research title about industrial technology

117 Manufacturing Research Topics, Essay Titles, & Project Ideas

Manufacturing is an interesting subject to discuss. You can write about production engineering, technology, safety, and many other aspects. If you’re looking for the best manufacturing research topics, you’ve come to the right place! StudyCorgi has prepared a list of titles and questions for you! Feel free to use them as inspiration for your presentation, project, essay, or research paper.

🏆 Best Research Topics in Manufacturing Industry

✍️ manufacturing essay topics for college, 👍 good manufacturing research topics & essay examples, 🌶️ hot manufacturing topics to write about, 🎓 most interesting manufacturing topics for project.

Dell Company’s Manufacturing and Just-in-Time Model
Advantages and Disadvantages of Parts Manufacturer Approval
Procurement Management in Car Manufacturers
Furniture Manufacturing in the UAE
Case Study: JAMS Manufacturing
Report on Toyota Car Manufacturer
Mechanichal Pencil’s Manufacturing
Shoelace Manufacturing Company’s Supply Chain Management This paper is a review of the supply chain management process in a shoelace manufacturing company. It will draw out a supply chain process map for the product.
Chip Manufacturer’s Production Specifications To identify the company’s ability to produce the chips of the designated size, the production manager should consider the data such as the p-value and the confidence coefficient.
ABC Manufacturing Company’s Project In this project, ABC Manufacturing Company is planning to put up a new warehouse that uses Automated Storage and Retrieval System (AS/RS).
Lenovo and DHL Express Companies: Manufacturing and Service This essay outlines the manufacturing and service processes for the smartphone division of Lenovo Group Ltd., and logistics services company DHL Express.
ABC Manufacturing: Analysis of the Budget Case Report This case report aims to discuss the budget process in ABC Manufacturing, its practices in terms of leadership and control, and ethical issues.
Supply Chain Management of the Sandwich Manufacturing Company The paper asses supply chain management of the sandwich manufacturing company, specifically, push and pull management philosophies.
T-Shirt Manufacturing: 4 Important Factors The paper explains the four major factors which help to understand the different operations of a T-shirt manufacturing company.
Strategies in Manufacturing and Service Operations In manufacturing companies, customer involvement is usually less intense, and communication with consumers is of auxiliary character.
Automobile Manufacturers’ Corporate Governance This paper conducts a performance analysis of three automobile manufacturers, Ford, BMW, and Toyota Motors, focusing on regulatory frameworks and corporate governance.
Medical Device Manufacturer Launching a New Metal Alloy Prosthesis Stainless steel is the most effective metal alloy across the globe by medics. Stainless steel products can be used for a long duration as reusable tools.
Tropical Juice Manufacturing Company Brand Tropical juice manufacturing company is an institution involved in producing and processing freshly blended fruit such as mango, passion, apple, among others.
Reverse Logistics in Pharmaceutical Industry: Handling Products Back to the Manufacturer Reverse logistics plays an enormous part in the pharmaceutical industry as poor-quality goods must be delivered safely back to the final disposition point.
The Resources Dependency Theory (RDT): Clothing Manufacturing Organizations This paper aims to analyze the resources dependency theory (RDT) within the context of clothing manufacturing organizations.
Quality Standards in Manufacturing and Service Industries Implementation of the ISO 9000 system in both manufacturing and services also has a number of similarities between these organizations.
Cigarettes Manufacturers Should Be Prohibited The manufacturing of the cigarettes should be banned with immediate effect. Cigarette smoking has brought about more than enough miseries within the societies.
Cellular Manufacturing Analysis This paper has discovered the factors which have a say in the successful and well-organized implementation of Lean manufacturing through the use of cellular manufacturing.
Poka-Yoke Proofing in Non-Manufacturing’ Systems Poka-Yoke is one of the approaches to quality which helps organizations to avoid errors and mistakes by putting certain limits on operations.
SolarEdge Technologies, Inc.: Challenges of the Manufacturing Industry By exploring options concerning research and investment, SolarEdge will overcome the challenges that can currently be observed across the entire manufacturing industry.
Cryptography System for B Manufacturing Company This assignment includes a critical assessment and analysis of cryptographic protocols that can be implemented to secure a system.
Robotics in Manufacturing: Social and Ethical Implications The field of robotics has been growing tremendously over the last three decades, as occasioned by the technological revolution of the late 20th century.
Management Issues in Manufacturing Company In order to lead a firm to success, much attention should be paid to the position and responsibilities of a manager.
Chinese Manufacturing Superpower and Industrial Growth China is currently the largest manufacturing economy in the world. However, its position as a manufacturing superpower will come to an end sooner than predicted.
Soft Drink Manufacturing: Marketing Strategies of Coke The soft drink manufacturing industry is one of the largest and fastest-growing sectors globally, with a strong customer base spread worldwide.
How Planning Plays a Role in Whirlpool’s Manufacturing Process Whirlpool corporation is one of the leading companies in the manufacturing of kitchenware and laundry products. Discussion of how planning plays a role in the manufacturing process.
Employee Turnover in Manufacturing Reducing personnel turnover in the industrial sector is one of the most significant management problems. Reducing unwanted turnover is the goal of every organization
Manufacturing Dimethyl Ether From Methanol This report analyzes the viability of manufacturing dimethyl ether from methanol by heating it and converting it to dimethyl ether and water.
The Theory of Constraints: Manufacturing Methodology This report will investigate the fundamentals of the Theory of Constraints, apply it to a manufacturing process, and examine the associated challenges involved in the process.
Quality Evolution in Auto Manufacturing Industry Since its first appearance at the end of the 19th century, the automobile has come a long way not only in its appearance and technical capabilities but also in quality standards.
The Clarinet History, Manufacturers and Composers The clarinet was invented in the beginning of the 18th century. In a century after its invention great composers created amazing classical pieces for the said instrument.
Industrial Age: Manufacturing Machinery Industrial Age can be defined as the time when people became actively engaged in the development of manufacturing machinery.
Electric Vehicles in the UK Automotive Manufacturing Industry The statistics show that the international manufacturers of engines have a higher tendency of locating their car manufacturing plants in the UK than other nations.
The Manufacturing Sector of Singapore Singapore is a country that has relied on the manufacturing industry to develop its economy. Singapore will rely on the manufacturing sector to balance trade with its business partners.
Materials and Processes in Manufacturing In grinding, it is highly important to know properties of different materials. For this purpose, various standard and non-standard methods are used.
RFID in Retailing and Manufacturing Companies The paper states that RFID systems do have a range of advantages in contrast to traditional bar code reading systems for large retail and manufacturing companies.
AutoEdge Relocating Manufacturing Operations to the US AutoEdge is a company specializing in the production and supply of engine parts, which is now considering relocating its manufacturing operations to the United States.
Enhancing Manufacturing Quality and Performance With Control Charts Numerous techniques for continuous improvement have their roots in the industrial sector which the main objective is to efficiently produce a lot of identical things.
ABC Manufacturing: Financial Management In this research paper, it is required to evaluate the effectiveness of the financial management of ABC Manufacturing.
Oil Extraction and Standard Vehicle Manufacturing Oil extraction and standard vehicle manufacturing are examples of businesses that consciously avoid spending on environmental causes.
Offline Retailers Expanding Online to Compete With Manufacturers The article focuses on analyzing the ongoing trend in retail companies to enter online markets to compete with manufacturers who sell the same products for a lower price.
Return to Domestic Manufacturing Global socio-economic, political, and even environmental happenings are things that may reveal the reason for a return to the market politics of the old times.
Cigarette Manufacturers’ Liability Manufacturers should be held liable as it would create a tangible incentive to disclose any potential risks as comprehensively as possible, thus benefiting the entire society.
Production and Growth During the Pandemic: A Case of U.S. Manufacturing By recognizing the factors that shape the production process, U.S. manufacturers have managed to continue delivering solid performance despite the effects of the coronavirus.
Production Decisions in UK Manufacturing Between 2010 to 2019 The paper seeks to examine two basic mechanisms that regulate the supply of goods and services in UK Manufacturing Between 2010 to 2019.
Multinational Agricultural Manufacturing Companies’ Standardization & Adaptation The most popular approaches that multinational companies use to serve their customers from various countries are standardization and adaptation.
Computer and Smartphone Manufacturers’ Short Product Lifespan Strategy The short product lifespan approach may be significantly beneficial for businesses yet harmful for ordinary people and the environment as, for example, it may increase e-waste.
Capital Budgeting for Byron Manufacturing The paper discusses how capital budgeting can be implemented in Byron Manufacturing and provides an example of a decision made using the internal rate of return method of analysis.
Cell Phone Manufacturers Legal Responsibility Regarding Cell Phone Radiation At the moment, cellphone manufactures are not required by FCC to reveal the levels of radiation of the cellphones that they manufacture.
Ethical Problem of Using Slave Labor in Manufacturing Modern globalization has ensured that people can get products from all over the world. The purpose of this essay is to outline this ethical dilemma and the ways it can be addressed.
Internet of Things in Manufacturing System The introduction and use of the Internet of Things can further increase the efficiency of the manufacturing system.
Manufacturing Systems Design The automation of the company’s manufacturing facility will be the right step in maximizing production, which will enhance the company’s profits.
Responding to Threats Posed by Offshore Manufacturing The main goal of the study is to identify the criteria that fashion corporations consider to manage supply chain risks, which are a part of offshore manufacturing.
Frito-Lay’s Manufacturing Facility and Innovations Frito-Lay’s approach to solving the problem of introducing new equipment is thorough training of personnel to ensure the preparedness to function in current conditions.
Good Manufacturing Practices for Pharmaceuticals Creating conditions for the safe production of pharmaceuticals is a practice that has evolved significantly due to the introduction of modern approaches to the manufacturing process.
Nike Inc.’s Sustainable Manufacturing Assessment Growing competition poses challenges for Nike in terms of supply chain management and sustainable development.
Nike Inc.’s Marketing and Manufacturing Principles This paper is an outline of the research of Nike and its impact on the global economy, social and political conditions, and marketing trends.
Motivation and Manufacturing Jobs Factories nowadays are indeed more mechanized and automated, but it should eventually lead to market expansion, which, in turn, will produce more jobs.
The Hydrostatic and Hydraulics System of Acme Manufacturing Co The following report presents detailed information addressing the prevailing circumstances of the fire suppressing and the Hydrostatic and hydraulics system of Acme Manufacturing Co.
Acme Manufacturing Company and Employees’ Safety AMC is concerned about its employees’ safety and needs to analyze its workplace. This report details the findings from evaluating the company’s ergonomics of the packing line.
Implementing New Business Models in the Manufacturing Industry This paper gives a detailed analysis of the implementation of additional business models in the manufacturing industry.
The Main Goal of Lean Thinking and Manufacturing The main goal of lean thinking and manufacturing is to lower the expenses as much as possible to make the productions more profitable.
The Forward Contract: The Eduction of Manufacturing Capabilities In India and Brazil the company can lose the revenue, and it can use futures as hedging in order to preserve the same amount of revenue.
Safety & Lean: One Manufacturer’s Lessons Learned and Best Practices A lot of organizations noticed the enhancement of business performance after the shift from traditional methods of production to lean methods of production.
Sony’s Projector Manufacturing Market in 1989 The competitive situation on the projector market considering Electrohome production in 1989 and the strategy applied by Sony will be discussed in the present essay.
A Manufacturing Plant in the Global Marketplace The discussion is generalized to all types of manufacturing plants. For any specific kind of plant, there might be some added aspects.
Riordan Manufacturing Company’s Process Design The Riordan manufacturing company is a plastic manufacturing company. The company has a focused research and development process.
Improvement to Supply Chain Process in Riordan Manufacturing The company wants to introduce effective supply chain management initiatives for increasing the key values of the company.
Values That the ISO9000 Can Bring to Riordan Manufacturing As for the issues of implementation of the ISO standards, Riordan Manufacturing company has a huge experience in providing means and methods for the management system.
Level 5 Manufacturing: Pros and Cons of the Mode Level 5 manufacturing entails the assembly of a desktop PC assembly, floppy disc, and fan. This mode has many disadvantages and disadvantages that are discussed in the paper.
Scheduling and Supply Chain in Manufacturing The major types of manufacturing processes are a job shop, batch shop, assembly, and continuous. The selection of an optimal manufacturing process is crucial for cost reduction.
The Ohio’s Manufacturing Environment: Lost Time Accident Rates This study seeks to consider the positive impact of correlation between lost time accidents and corporations’ annual profit share margin in the Ohio manufacturing industry.
Cell Manufacturing Setup: Project Management To ensure the project is effectively managed, various tools of analysis such as risk management tools and following previous project precedents will be used.
Recruitment for Customer Service and Manufacturing There are many options for human resource managers to find skilled employees. Some methods of recruitment prove more efficient than others.
China’s Economic Growth and Manufacturing The enhanced economic growth, which China is currently experiencing, coexists with a drop in the manufacturing entrepreneurships’ performance.
Ethical Manufacturing and Technology Trends The ethical manufacturing aiming at the elimination of human discrimination at the workplace seems to be an essential step in establishing ethics across societies.
ANOVA Company’s Failures in Manufacturing The adoption of ANOVA is one of the means to locate a hindrance in the manufacturing process and remove it to improve the performance of a company.
State Manufacturing’s Pricing and Decision-Making In this document, the sales manager offers assistance in the decision-making process, describing options for analyzing and determining the export price of CIF.
Melbourne Manufacturing Company’s Hedging Options As the CFO of Melbourne Manufacturing, Shiela Forbes needs to draw a conclusion on whether to hedge while realizing the sale of a turbine generator.
Can Hospitals Manufacture Drugs in the US? The purpose of the initiative is to force the drug market to drop prices and compete fairly by introducing a new force to destabilize the existing monopoly of a few large companies.
Sustainability in the Manufacturing Company Context The Six Sigma approach allows for the promotion of the lean manufacturing principles in entrepreneurship and, therefore, supporting the principle of sustainable resources usage.
Abasco Inc.’s Manufacturing Unit and Industrial Progress Despite the reasonable approach toward information management of Abasco, Inc, the lack of reasonable resource allocation may jeopardize the organization’s efficacy.
US Car Manufacturing: International Promotion Mix The car manufacturing industry in the United States of America is quite competitive as the business environment in the country has transformed significantly.
Good Mark Company: Manufacturing Industry Analysis This paper provides a strategic analysis of the manufacturing industry. To concretize the analysis, Good Mark, a manufacturing company in Hong Kong is used.
Riordan Manufacturing Virtual Organization Riordan is primarily a business to business manufacturing company. Some of the company’s clients include appliance manufacturers, aircraft manufacturers, as well as car companies.
Riordan Manufacturing’s HR Marketing Services The main objective of the plan was identified as motivating employees in order to improve their productivity.
Marketing and Manufacturing Strategies Role Though the gap between the marketing approach and the production process in the organization may seem rather large, the choice of a marketing strategy, in fact, defines the manufacturing one largely.
Business Continuity Plan for Riordan Manufacturing
Manufacturing Exports From Brazil: Determinants and Consequences
Financial Audit and Laramie Wire Manufacturing
Manufacturing Firms’ Decisions Regarding Retiree Health Insurance
Computer Integrated Manufacturing and Management
Manufacturing Industry and Economic Growth in Latin America
Love, Pickup Trucks, and Lost Manufacturing Jobs
Manufacturing Industry and Fair Trade in Australia
Industrial Robots and Manufacturing Automation
Long-Run Profit Maximization in the Turkish Manufacturing Sector
Manufacturing Jobs: Implications for Income Inequality
Blue Ridge Manufacturing Company Analysis
Machine and Labor Flexibility in Manufacturing Networks
Information Technology and Manufacturing Today
Manufacturing and Activity Based Costing
Globalization and the Impact Onus Manufacturing
Differences Between Manufacturing and Service Organisations
Manufacturing and Economic Growth in Developing Countries, 1950–2005
Financial Forecasting Riordan Manufacturing
Dell Built-To-Order Has Revolutionized Manufacturing
Working Towards Agile Manufacturing in the UK Industry
Manufacturing Investment and Taxation in the Nordic Countries
Computer Manufacturing Industry Analysis
Manufacturing and Supplier Roles in Product Development
Lean Manufacturing and Its Effect on Businesses

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StudyCorgi. (2021, December 21). 117 Manufacturing Research Topics, Essay Titles, & Project Ideas. https://studycorgi.com/ideas/manufacturing-essay-topics/

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StudyCorgi . "117 Manufacturing Research Topics, Essay Titles, & Project Ideas." December 21, 2021. https://studycorgi.com/ideas/manufacturing-essay-topics/.

StudyCorgi . 2021. "117 Manufacturing Research Topics, Essay Titles, & Project Ideas." December 21, 2021. https://studycorgi.com/ideas/manufacturing-essay-topics/.

These essay examples and topics on Manufacturing were carefully selected by the StudyCorgi editorial team. They meet our highest standards in terms of grammar, punctuation, style, and fact accuracy. Please ensure you properly reference the materials if you’re using them to write your assignment.

This essay topic collection was updated on January 8, 2024 .

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The Top 10 Most Interesting Technology Research Topics

With technological innovation streamlining processes in businesses at all levels and customers opting for digital interaction, adopting modern technologies have become critical for success in all industries. Technology continues to positively impact organizations , according to Statista, which is why technology research topics have become common among college-level students.

In this article, we have hand-picked the best examples of technology research topics and technology research questions to help you choose a direction to focus your research efforts. These technology research paper topics will inspire you to consider new ways to analyze technology and its evolving role in today’s world.

Find your bootcamp match

What makes a strong technology research topic.

A strong research topic is clear, relevant, and original. It should intrigue readers to learn more about the role of technology through your research paper. A successful research topic meets the requirements of the assignment and isn’t too broad or narrow.

Technology research topics must identify a broad area of research on technologies, so an extremely technical topic can be overwhelming to write. Your technology research paper topic should be suitable for the academic level of your audience.

Tips for Choosing a Technology Research Topic

Make sure it’s clear. Select a research topic with a clear main idea that you can explain in simple language. It should be able to capture the attention of the audience and keep them engaged in your research paper.
Make sure it’s relevant. The technology research paper topic should be relevant to the understanding and academic level of the readers. It should enhance their knowledge of a specific technological topic, instead of simply providing vague, directionless ideas about different types of technologies.
Employ approachable language. Even though you might be choosing a topic from complex technology research topics, the language should be simple. It can be field-specific, but the technical terms used must be basic and easy to understand for the readers.
Discuss innovations. New technologies get introduced frequently, which adds to the variety of technology research paper topics. Your research topic shouldn’t be limited to old or common technologies. Along with the famous technologies, it should include evolving technologies and introduce them to the audience.
Be creative . With the rapid growth of technological development, some technology research topics have become increasingly common. It can be challenging to be creative with a topic that has been exhausted through numerous research papers. Your research topic should provide unique information to the audience, which can attract them to your work.

What’s the Difference Between a Research Topic and a Research Question?

A research topic is a subject or a problem being studied by a researcher. It is the foundation of any research paper that sets the tone of the research. It should be broad with a wide range of information available for conducting research.

On the other hand, a research question is closely related to the research topic and is addressed in the study. The answer is formed through data analysis and interpretation. It is more field-specific and directs the research paper toward a specific aspect of a broad subject.

How to Create Strong Technology Research Questions

Technology research questions should be concise, specific, and original while showing a connection to the technology research paper topic. It should be researchable and answerable through analysis of a problem or issue. Make sure it is easy to understand and write within the given word limit and timeframe of the research paper.

Technology is an emerging field with several areas of study, so a strong research question is based on a specific part of a large technical field. For example, many technologies are used in branches of healthcare such as genetics and DNA. Therefore, a research paper about genetics technology should feature a research question that is exclusive to genetics technology only.

2. Children’s Use of Social Media

Nowadays, parents allow their children to use the Internet from a very young age. A recent poll by C.S. Mott Children’s Hospital reported that 32 percent of parents allow their children aged seven to nine to use social media sites. This can expose them to cyber bullying and age-inappropriate content, as well as increase their dependence on technology.

Kids need to engage in physical activities and explore the world around them. Using social media sites in childhood can be negative for their personalities and brain health. Analyzing the advantages and disadvantages of the use of technology among young children can create an interesting research paper.

3. The Risks of Digital Voting

Digital voting is an easy way of casting and counting votes. It can save the cost and time associated with traveling to the polling station and getting a postal vote. However, it has a different set of security challenges. A research paper can list the major election security risks caused by digital voting.

Voting in an online format can expose your personal information and decisions to a hacker. As no computer device or software is completely unhackable, the voting system can be taken down, or the hacking may even go undetected.

4. Technology’s Impact on Society in 20 Years

Technological development has accelerated in the last decade. Current technology trends in innovation are focusing on artificial intelligence development, machine learning, and the development and implementation of robots.

Climate change has affected both human life and animal life. Climate technology can be used to deal with global warming in the coming years, and digital learning can make education available for everyone. This technology research paper can discuss the positive and negative effects of technology in 20 years.

5. The Reliability of Self-Driving Cars

Self-driving cars are one of the most exciting trends in technology today. It is a major technology of the future and one of the controversial technology topics. It is considered safer than human driving, but there are some risks involved. For example, edge cases are still common to experience while driving.

Edge cases are occasional and unpredictable situations that may lead to accidents and injuries. It includes difficult weather conditions, objects or animals on the road, and blocked roads. Self-driving cars may struggle to respond to edge cases appropriately, requiring the driver to employ common sense to handle the situation.

6. The Impact of Technology on Infertility

Assisted reproductive technology (ART) helps infertile couples get pregnant. It employs infertility techniques such as In-Vitro Fertilization (IVF) and Gamete Intrafallopian Transfer (GIFT).

Infertility technologies are included in the controversial technology topics because embryonic stem cell research requires extracted human embryos. So, the research can be considered unethical. It is an excellent research topic from the reproductive technology field.

7. Evolution of War Technology

Military technologies have improved throughout history. Modern technologies, such as airplanes, missiles, nuclear reactors, and drones, are essential for war management. Countries experience major innovation in technologies during wars to fulfill their military-specific needs.

Military technologies have controversial ideas and debates linked to them, as some people believe that it plays a role in wars. A research paper on war technology can help evaluate the role of technology in warfare.

8. Using Technology to Create Eco-Friendly Food Packaging

Food technologies and agricultural technologies are trying to manage climate change through eco-friendly food packaging. The materials used are biodegradable, sustainable, and have inbuilt technology that kills microbes harmful to human life.

Research on eco-friendly food packaging can discuss the ineffectiveness of current packaging strategies. The new food technologies used for packaging can be costly, but they are better for preserving foods and the environment.

9. Disease Diagnostics and Therapeutics Through DNA Cloning

Genetic engineering deals with genes and uses them as diagnostics and therapeutics. DNA cloning creates copies of genes or parts of DNA to study different characteristics. The findings are used for diagnosing different types of cancers and even hematological diseases.

Genetic engineering is also used for therapeutic cloning, which clones an embryo for studying diseases and treatments. DNA technology, gene editing, gene therapy, and similar topics are hot topics in technology research papers.

10. Artificial Intelligence in Mental Health Care

Mental health is a widely discussed topic around the world, making it perfect for technology research topics. The mental health care industry has more recently been using artificial intelligence tools and mental health technology like chatbots and virtual assistants to connect with patients.

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Artificial intelligence has the potential to improve the diagnosis and treatment of mental illness. It can help a health care provider with monitoring patient progress and assigning the right therapist based on provided data and information.

Technology Research Questions

Is using technology in college classrooms a good or bad idea?
What are the advantages of cloud technologies for pharmaceutical companies?
Can new technologies help in treating morbid obesity?
How to identify true and false information on social media
Why is machine learning the future?

Choosing the Right Technology Research Topic

Since technology is a diverse field, it can be challenging to choose an interesting technology research topic. It is crucial to select a good research topic for a successful research paper. Any research is centered around the research topic, so it’s important to pick one carefully.

From cell phones to self-driving cars, technological development has completely transformed the world. It offers a wide range of topics to research, resulting in numerous options to choose from. We have compiled technology research topics from a variety of fields. You should select a topic that interests you, as you will be spending weeks researching and writing about it.

Technology Research Topics FAQ

Technology is important in education because it allows people to access educational opportunities globally through mobile technologies and the Internet. Students can enroll in online college degrees , courses, and attend online coding bootcamps . Technology has also made writing research papers easier with the tremendous amount of material available online.

Yes, technology can take over jobs as robotics and automation continue to evolve. However, the management of these technologies will still require human employees with technical backgrounds, such as artificial intelligence specialists, data scientists , and cloud engineers.

Solar panels and wind turbines are two forms of technology that help with climate change, as they convert energy efficiently without emitting greenhouse gases. Electric bikes run on lithium batteries and only take a few hours to charge, which makes them environmentally friendly. Carbon dioxide captures are a way of removing CO 2 from the atmosphere and storing it deep underground.

Technology helps companies manage client and employee data, store and protect important information, and develop strategies to stay ahead of competitors. Marketing technologies, such as Search Engine Optimization (SEO), are great for attracting customers online.

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A comprehensive study of technological change

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Bar graph. On the y-axis: density, from 0.00 to 0.08. On the X-axis: estimated yearly improvement rates, from 0 to 200. There is a large spike of data going past .08 on the y-axis, in between approximately the 0 and 25 marks on the x-axis. A red vertical dotted line exists at the 36.5 mark.

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The societal impacts of technological change can be seen in many domains, from messenger RNA vaccines and automation to drones and climate change. The pace of that technological change can affect its impact, and how quickly a technology improves in performance can be an indicator of its future importance. For decision-makers like investors, entrepreneurs, and policymakers, predicting which technologies are fast improving (and which are overhyped) can mean the difference between success and failure.

New research from MIT aims to assist in the prediction of technology performance improvement using U.S. patents as a dataset. The study describes 97 percent of the U.S. patent system as a set of 1,757 discrete technology domains, and quantitatively assesses each domain for its improvement potential.

“The rate of improvement can only be empirically estimated when substantial performance measurements are made over long time periods,” says Anuraag Singh SM ’20, lead author of the paper. “In some large technological fields, including software and clinical medicine, such measures have rarely, if ever, been made.”

A previous MIT study provided empirical measures for 30 technological domains, but the patent sets identified for those technologies cover less than 15 percent of the patents in the U.S. patent system. The major purpose of this new study is to provide predictions of the performance improvement rates for the thousands of domains not accessed by empirical measurement. To accomplish this, the researchers developed a method using a new probability-based algorithm, machine learning, natural language processing, and patent network analytics.

Overlap and centrality

A technology domain, as the researchers define it, consists of sets of artifacts fulfilling a specific function using a specific branch of scientific knowledge. To find the patents that best represent a domain, the team built on previous research conducted by co-author Chris Magee, a professor of the practice of engineering systems within the Institute for Data, Systems, and Society (IDSS). Magee and his colleagues found that by looking for patent overlap between the U.S. and international patent-classification systems, they could quickly identify patents that best represent a technology. The researchers ultimately created a correspondence of all patents within the U.S. patent system to a set of 1,757 technology domains.

To estimate performance improvement, Singh employed a method refined by co-authors Magee and Giorgio Triulzi, a researcher with the Sociotechnical Systems Research Center (SSRC) within IDSS and an assistant professor at Universidad de los Andes in Colombia. Their method is based on the average “centrality” of patents in the patent citation network. Centrality refers to multiple criteria for determining the ranking or importance of nodes within a network.

“Our method provides predictions of performance improvement rates for nearly all definable technologies for the first time,” says Singh.

Those rates vary — from a low of 2 percent per year for the “Mechanical skin treatment — Hair removal and wrinkles” domain to a high of 216 percent per year for the “Dynamic information exchange and support systems integrating multiple channels” domain. The researchers found that most technologies improve slowly; more than 80 percent of technologies improve at less than 25 percent per year. Notably, the number of patents in a technological area was not a strong indicator of a higher improvement rate.

“Fast-improving domains are concentrated in a few technological areas,” says Magee. “The domains that show improvement rates greater than the predicted rate for integrated chips — 42 percent, from Moore’s law — are predominantly based upon software and algorithms.”

TechNext Inc.

The researchers built an online interactive system where domains corresponding to technology-related keywords can be found along with their improvement rates. Users can input a keyword describing a technology and the system returns a prediction of improvement for the technological domain, an automated measure of the quality of the match between the keyword and the domain, and patent sets so that the reader can judge the semantic quality of the match.

Moving forward, the researchers have founded a new MIT spinoff called TechNext Inc. to further refine this technology and use it to help leaders make better decisions, from budgets to investment priorities to technology policy. Like any inventors, Magee and his colleagues want to protect their intellectual property rights. To that end, they have applied for a patent for their novel system and its unique methodology.

“Technologies that improve faster win the market,” says Singh. “Our search system enables technology managers, investors, policymakers, and entrepreneurs to quickly look up predictions of improvement rates for specific technologies.”

Adds Magee: “Our goal is to bring greater accuracy, precision, and repeatability to the as-yet fuzzy art of technology forecasting.”

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Shaping technology’s future

Ali Jadbabaie is the JR East Professor of Engineering in the Department of Civil and Environmental Engineering, the associate director of the Institute for Data, Systems, and Society (IDSS), and the director of one of its parts, the Sociotechnical Systems Research Center. “Our focus is on addressing large societal problems, whether they be power systems and energy systems, or social networks, or...

Tackling society’s big problems with systems theory

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TECHNOLOGY AND INDUSTRIAL RESEARCH

TECHNOLOGY AND INDUSTRIAL RESEARCH. Early Cleveland's household, agricultural, and industrial processes and devices were simply transfers or adaptations from elsewhere. The earliest settlers borrowed the 18th-century technologies of Europe and North America, including water-powered saw- and gristmilling, blacksmithing, brewing and distilling, textile manufacture, and intensive farming with plows and other iron implements. CUYAHOGA STEAM FURNACE , established in 1834 in the FLATS , reproduced the iron-smelting technology used in the U.S. for over a century, though it added the recent innovation of blowing the blast with a steam engine. Similarly, the Cleveland Paper Co. began operations in 1860 with well-known technology, and the Kuhlman Furniture Co. relied upon traditional craftsmen when it was established in 1867. Cleveland's entry into the steel industry began in 1868 when the Cleveland Rolling Mills Co. opened a Bessemer works, which was based on British patents of a decade earlier, as well as important American modifications developed in New York and Michigan.

By the mid-19th century, however, local improvements in existing technology were appearing. Cuyahoga County farmers had become innovators in beekeeping, the use of haymowers, and silo construction. And in the last third of the century, Clevelanders invented a number of significant devices and processes that laid the foundation for further industrial growth. For example, both John McMyler and A. N. Simmerly invented and patented derricks for loading and unloading ships, and in the 1880s founded Cleveland companies to manufacture them. Other inventors were professionals who obtained technical training or formal education, and then devoted their careers to creating new devices or attacking critical problems in developing industries. An early inventor of this type was Elisha Gray. Educated at Oberlin (Ohio) Preparatory School and Oberlin College, Gray experimented regularly with electricity at the college's laboratory in the early 1860s. His first patent (1867) was for a telegraph apparatus, which he successfully demonstrated at Western Union headquarters in Cleveland. In 1869 he sold Western Union an interest in a telegraph printer he had designed, and with the cash he purchased a half-interest in a telegraph-instrument shop in Cleveland. By the time Gray moved his business to Chicago in 1871, he had a close and regular relationship with Western Union.

Another professional inventor, CHARLES F. BRUSH , was born in EUCLID , completed engineering training at the Univ. of Michigan in 1869, and subsequently set up a consuliting chemical laboratory in Cleveland. Privately he carried on experiments in electricity, and in 1875-79 he developed and patented crucial elements of the first central-station arc-lighting system in the world. Brush established the Brush Electric Co. in 1880 with the help of local capitalists, and marketed his system for street lighting worldwide. At his factory at 45th St. and what is now Commerce Ave., he established a laboratory in which he did fundamental work on storage batteries, securing the basic American patents on what eventually became a vital part of the automobile. Brush's pioneering innovations in the electrical industry attracted a number of Clevelanders who later founded important companies. ALEXANDER E. BROWN , a Scottish immigrant, worked for Brush, then designed a hoist for unloading iron ore from Great Lakes vessels, first used in 1881. By 1893 an estimated 75% of Great Lakes ore was handled by hoists made by Brown's Cleveland company. WASHINGTON H. LAWRENCE also worked with Brush in developing workable carbon points (from petroleum refinery residue) for arc lights, and in 1886 was a founder of the NATIONAL CARBON CO ., of which he became president. Lawrence participated in and promoted further research, which developed the use of carbons for batteries, dynamo and motor brushes, and telephone transmitters. LINCOLN ELECTRIC was founded in 1896 by another former Brush employee, John C. Lincoln. He pioneered in the development and manufacture of arc-welding equipment, and by the 1930s his company was known worldwide for its products.

Other innovators used the Brush laboratory and shops for their projects. Walter Knight and Edward Bentley experimented on electric trolleys there, and although their work was not commercially successful, they are credited with making the first working installation of an electric streetcar line in the U.S. Eugene and Alfred Cowles first operated their electric furnace at the Brush site in 1883. Elmer Sperry, one of America's outstanding consulting engineers, focused on electric vehicles and batteries, working at the Brush shops from the time of his arrival in Cleveland in 1893 until 1905. In addition to his work in conjunction with GENERAL ELECTRIC , Sperry pursued his own investigations, notably in electrochemical processes, during his Cleveland years.

Certainly Brush and the cluster of inventions and innovations that spun off of his work are the most dramatic examples of the surge in technical change associated with the industrialization of Cleveland in the late 19th century, but there were many others. AMBROSE SWASEY and WORCESTER WARNER , for example, applied their machine-tool skills to telescope and instrument manufacture with great success, completing the great Lick Telescope in 1889. That telescope's worldwide publicity brought them numerous telescope contracts thereafter. The automobile industry in Cleveland also had innovative leaders. ALEXANDER WINTON introduced the 2-cylinder automobile engine in 1901, and later turned his attention to developing the diesel engine. WALTER BAKER was a leading manufacturer of electric vehicles, and ROLLIN WHITE patented a semiflash boiler for steam automobiles. The steel industry benefited enormously from Samuel Wellman's work at the Otis Steel Co., where he introduced the open-hearth process in 1874, and first produced basic open-hearth steel in 1886.

Through this late-19th-century age of rapid innovation and invention, the companies that remained in the forefront of their fields relied upon the energy and initiative of talented individuals for new or adapted technology. These individuals seldom had more than a personal laboratory and 1 or 2 assistants, and their approach to patenting their invention was often haphazard, leading to costly litigation when opportunities to patent were missed. By 1900 however, research and development of new industrial technology had begun to be institutionalized and systematized, in order to anticipate and control the course of invention and innovation. Modern industrial research began as companies hired professional researchers as permanent employees and created well-supplied laboratories for them. Early steps in that direction were taken by the STANDARD OIL CO ., which began its program of research in 1877 by employing HERMAN FRASCH , a pharmaceutical chemist, to work on refining problems in Cleveland. In 1889 Standard Oil established a permanent research department, which is usually regarded as the first such department in the petroleum industry. The SHERWIN-WILLIAMS CO . hired its first full-time chemist, Percy Neyman, in 1884, and its second in 1892. The outstanding pioneering research laboratory in Cleveland was NELA PARK . The National Electric Lamp Assn. (NELA) was founded in 1901 by a group of lightbulb manufacturers competing with General Electric. Soon NELA established a research and development laboratory in Cleveland in order to standardize and upgrade its product, an effort that was so successful that NELA more than doubled its share of the market in the next decade. That success, and the laboratory director's desire to remove research from the gaseous pollution, vibrations, and electrical disturbances of a city location, led NELA's leaders to build a larger research center in suburban EAST CLEVELAND. The new site, Nela Park, was begun in 1911 and eventually comprised 20 buildings on 90 acres. In 1912 GE absorbed NELA, and the site became GE's Lamp Development Laboratory. GE created an outstanding team of engineers and scientists who carried out a series of major inventions and innovations in lighting technology. In 1917 Dr. Aladar Pacz completed work on a workable tungsten wire filament, and in the 1930s the Nela Park staff did fundamental investigations of sodium-vapor and fluorescent lamps. Throughout the 20th century, the NELA team was expected to solve GE's lightbulb-manufacturing problems, however, in the process, they often conducted basic scientific research on light emission and transmission. During the first decade of the 20th century, other corporate giants, such as AT&T, Eastman-Kodak, and Du Pont, established massive research divisions, and GE had an even larger laboratory in Schenectady, NY. But, as symbolized by Nela Park, Cleveland was one of the leaders in industrial research, and it remained a major center in succeeding years. A survey by the National Research Council in 1930 revealed that the city had 41 laboratories, concentrated in the chemical, metallurgical, paint, and machinery industries. Cleveland then had the 5th-largest concentration of industrial research laboratories in the U.S. Fifty years later, the Cleveland metropolitan area had over 200 industrial laboratories, including major research centers for such diverse corporations as Sohio, Durkee Foods, and Union Carbide.

From about the time of World War II, the federal government and higher education became the rising stars of industrial research. In Cleveland that was symbolized by the establishment of the NATIONAL AERONAUTICS & SPACE ADMINISTRATION, LABORATORY, and the growth of Case Institute of Technology. The National Advisory Committee for Aeronautics founded Lewis in 1941 on a site adjacent to Cleveland's airport, and commissioned it to test aircraft engines. As one of NACA's test facilities, Lewis conducted important wartime research on piston engines and their fuels, lubricants, and coolants. After the war, its attention turned to developing the jet engines invented by British and German engineers, and in the 1950s and the 1960s (when NACA became NASA), Lewis pioneered in rocketry. Both of these research and development programs remained strong through the 1980s, although energy conservation and fuel efficiency also entered Lewis's agenda.

Case Institute of Technology regarded scientific research and industrial development as tasks compatible with education from the beginning of classes in 1882. Over its first 50 years, Case professors contributed to the understanding of petroleum chemistry and electrochemistry, and helped to develop the technologies on which the Dow Chemical and LUBRIZOL corporations were founded. By 1930 Case was one of about 20 institutions of higher learning that could be identified as regularly conducting industrial research. Yet the research depended on individual efforts. With the presidencies of WILLIAM WICKENDEN (1924-47) and T. KEITH GLENNAN (1948-67), Case established closer relationships with industry and government. By accepting long-term contracts, and committing its faculty, graduate students, and laboratories to industrial research, Case dealt regularly with the iron and steel, metal fabrication, and chemical industries. During World War II, federal contracts became increasingly important, and by the 1950s 70% of Case's research income came from government research, mostly for the Defense Department. Notable research during the institute's second 50 years occurred in polymers, strength of materials, complex systems design, computers, and biomedical engineering. Classified military projects, such as the multimillion-dollar "Doan Brook" enterprise of the 1950s, which planned technologies for the aerial "seeding" of land mines, cannot yet be assessed by historians.

By the 1980s, industrial research laboratories in Cleveland fostered invention and promoted technical innovation on behalf of industrial corporations, government agencies, and higher education. Many Clevelanders looked to such laboratories as the source of the new ideas that would stem or reverse the decline of Cleveland's industrial base. Others viewed with concern the increasingly military orientation of research, and the integration of military, academic, and industrial institutions, which was most visible in research laboratories. Although they are a relatively small part of Cleveland's economy and workforce, the laboratories will continue to play an important role in the future.

Darwin H. Stapleton

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This guide will provide some recommendations on resources for research in Industrial Technology including finding articles in databases, books, standards and web resource

Recommended Databases

ACM Digital Library This link opens in a new window The Association for Computing Machinery (ACM) Digital Library is a research, discovery and networking platform containing full-text access to all ACM publications (including journals, conference proceedings, technical magazines, newsletters and book) as well as the ACM Guide to Computing Literature, a comprehensive bibliographic database focused exclusively on the field of computing.
ASCE Online Journals This link opens in a new window Includes access to all online ASCE (American Society of Civil Engineers) journals (32 journals - 1983 to 2010) and all online proceedings (190+ title archive plus all new titles in 2010).
Business Source Complete This link opens in a new window Journal articles, magazine articles, newspaper articles, company profiles, country reports, industry profiles, market research reports, SWOT analyses, and trade publications.
IEEE Xplore This link opens in a new window Research papers from IEEE conferences. Full Text: All

Database Search Tips

Peer-Reviewed

Many databases allow you to limit your results to Scholalry or Peer-Reviewed Articles. This option is usually found on either side of your results list and/or in the advanced search screen. Use this to limit your results to college level research written by and approved by experts in the field.

Subject Headings

To help narrow your search, search for subjects related to your topic instead of the default keyword search. You can usually see the subjects an article covers by clicking on the title of that article from the results list. Use those subject terms to find more articles on that topic.

Use the databases limits options to narrow your search. Date, type of document, and language are just some of the options you can usually limit your search by. Limits options can usually be found on the advanced search screen and/or to either side of your results list.

Use truncation to search for multiple forms of a word. Truncation symbols may vary but it is usually the * or ? symbol. Example : comput* will search for "computer," "computers," "computing," "computation," etc.

A wildcard is a character you can insert in the place of another character. It will search for different spellings and word variations. The wildcard symbol may vary but it is usually the ? or ! symbol. Example : "wom?n" will search for both "woman" and "women."

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Last Updated: Mar 27, 2023 10:46 AM
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100+ Top Technology Research Topics for Students

When pursuing their studies, learners are required to write papers and essays on technology research topics. This is a major academic task that influences the final grade that learners graduate with. But, the grades that students score are largely dependent on the technology topics that they opt to write about. Technology is generally a broad study field. As such, choosing research topics on technology is not always easy. If struggling to choose a good technology research topic for your academic paper or essay, here are some of the best ideas to consider.

Trendy Technology Research Topics

Perhaps, you need a prominent research topic about technology. In that case, you should consider prominent technology research paper topics. Here are some of the most trendy topics about technology to consider.

Technology use in education (here is our list of 110 topics in education research )
Space and technology studies (check out our top 30 space research topics )
Current and stunning developments in technology
Shocking inventions in modern technology that most people don’t know yet
What technologies can be considered harmful and destructive?
How does technology affect people’s values and health?
Can humans be replaced by robots completely in the workplace?
How have different countries contributed to modern technology developments
Transport safety and technology
Discuss the scope of the use of nanotechnologies
Discuss the use of technology in medicine
Which technologies can influence human mental health?
Discuss how technology is changing human life
What are the positive effects of technologies on personal safety?
How does technology affect personal safety negatively?
Discuss how modern technology facilitates the improvement of educational processes
How do modern technologies influence users’ mental health?
Why are robots likely to replace humans in the workplace?
How has technology influenced space travel?
Is food preservation technology safe?

This category also includes some of the most controversial technology topics. Nevertheless, each topic should be researched extensively before writing a paper or an essay.

Interesting Information Technology Topics

If pursuing a college or university program in information technology, this category has some of the best options for you. Here are some of the best information technology research topics to consider.

How useful is unlimited data storage?
How can humans manage large amounts of information?
How blurred is the line between the human brain and a computer?
Is entertainment technology something good or bad?
Discuss the differences between digital reading and print reading
How does Google impact the attention span of young people?
How important are traditional research skills in the current era of advanced information technologies?
How credible is the information provided by different platforms on the internet?
Do blogs and books compare?
Should schools and guardians encourage or discourage the use of media by children?
Does Google provide the best information when it prefers its specific brands?
Are humans losing the intelligence developed via conventional reading and research in the current digital age?
How important is learning to how use social media, iPads, and Smart Boards?
Should modern technologies be incorporated into teaching?
How has Google search changed humans?
How is intelligence gauged by humans?
Is online information format making the readers skim rather than digest information?
Is the ease of finding information on the internet something bad or good?
Is technology changing how people read?
Can using information technology make you smarter?

Students have many information technology research paper topics to choose from. However, select a topic that you find interesting to research and write about.

Interesting Science and Technology Topics

Are you looking for a science and technology-related topics? If yes, consider topics in this category. Here are some of the most interesting topic ideas in science and technology.

Discuss the greatest technological and scientific breakthroughs of the 21st century
How significant is number 0 in science and technology?
How important is the first black hole image?
Discuss the unlimited fractals’ perimeter despite their limited area
How can a person perform mental calculations rapidly?
Discuss the fourth dimension
Discuss the math behind the Draft lottery by the NBA
Differentiate non-parametric and parametric statistics
Discuss the concept of something being random or impossible to prove mathematically
Discuss some of the greatest modern age mathematicians
How are the latest automobile technology improvements protecting the environment?
Why are Smartphones resistant to viruses and bugs in comparison to computers?
Discuss the Internet of Things story
What made vector graphics mainstream and not pixels?
Discuss the latest technology advances that relate to medicine
Describe Molten Salt Nuclear Reactors
Is it possible to power everything with solar energy?
Explain why smart electronics get slower with time
Differentiate closed and open systems in technology
Discuss the process of converting old recordings into new formats

This category has amazing topics on technology and science. Select an idea that you find interesting to research and write a paper or essay about.

The Best Computer Technology Topics

If you’re pursuing a program on computer technologies, you will find educational technology topics in this category very interesting. Here are some of the best topics for technology and computers to consider.

How can you describe the Machine Learning future?
Discuss computer science that will be the most important in the future
Discuss how big data and bioinformatics change biology
What is the borderline for hardware and software in cloud computing?
How moving everything to the cloud affects human life?
Can robots become more intelligent and like people with reinforced learning?
How can computer programmers enhance device protection with open-source getting trendier?
Is Google becoming the first machine learning firm?
Explain machine learning in detail
Discuss the importance of machine learning
Which sectors does machine learning affect the most?
How will virtualization change the entertainment industry?
Describe virtualization
Can virtual reality be something bad or good?
How will virtual reality change education?
What can humans expect from the internet?
What improvements can be made on the internet?
How are robots changing the health sector?
Are humans yet to invent any computer language?
What will happen if most tasks that are currently done by humans are taken over by computers?

These are great technology essay topics to consider if pursuing a computer technology program in college or university. They can also be great technology debate topics. Nevertheless, extensive research is required when writing about any of these technology essay topics.

Controversial Topics in Technology for Research Papers and Essays

Are you looking for interesting technology topics that your audience will love to read about? If yes, consider one of these technology controversy topics to research and write about.

Do law enforcement cameras invade privacy?
Does the technology age turn humans into zombies?
Has technology advancement led to a throw-away society?
How has cloud technology changed data storage?
How have Smartphones reduced live communication?
Our modern technologies changing teaching?
How does the use of IT by construction companies lead to under-spending and recession?
Discuss the technologies used by NASA to explore Mars
How dangerous are cell phones?
How does media technology affect child development?
Is the use of technology in planning lessons good or bad?
How does technology influence the educational system?
Discuss the application of green technologies in engineering, architecture, and construction
Can modern technologies like cryptocurrencies help in identity theft prevention?
How can technology be used to enhance energy efficiency?
How are self-driving cars likely to change human life?
How did Steve Jobs and Bill Gates change the world with technology
What is the impact of drone warfare on humans?
Can the actual reality be substituted by virtual reality?
Discuss the use of technologies and smart materials in road building

If looking for hot topics in technology, consider some of the ideas in this category. Nevertheless, you can also find technology persuasive speech topics here. That’s because this category has some of the most debatable topics. If you still don’t find a great idea from this list, consider technology security topics or contact our thesis writers . Remember that extensive research is required to write a great paper or essay regardless of the topic that you opt to write about.

500+ Quantitative Research Titles and Topics

Table of Contents

Quantitative research involves collecting and analyzing numerical data to identify patterns, trends, and relationships among variables. This method is widely used in social sciences, psychology , economics , and other fields where researchers aim to understand human behavior and phenomena through statistical analysis. If you are looking for a quantitative research topic, there are numerous areas to explore, from analyzing data on a specific population to studying the effects of a particular intervention or treatment. In this post, we will provide some ideas for quantitative research topics that may inspire you and help you narrow down your interests.

Quantitative Research Titles

Quantitative Research Titles are as follows:

Business and Economics

“Statistical Analysis of Supply Chain Disruptions on Retail Sales”
“Quantitative Examination of Consumer Loyalty Programs in the Fast Food Industry”
“Predicting Stock Market Trends Using Machine Learning Algorithms”
“Influence of Workplace Environment on Employee Productivity: A Quantitative Study”
“Impact of Economic Policies on Small Businesses: A Regression Analysis”
“Customer Satisfaction and Profit Margins: A Quantitative Correlation Study”
“Analyzing the Role of Marketing in Brand Recognition: A Statistical Overview”
“Quantitative Effects of Corporate Social Responsibility on Consumer Trust”
“Price Elasticity of Demand for Luxury Goods: A Case Study”
“The Relationship Between Fiscal Policy and Inflation Rates: A Time-Series Analysis”
“Factors Influencing E-commerce Conversion Rates: A Quantitative Exploration”
“Examining the Correlation Between Interest Rates and Consumer Spending”
“Standardized Testing and Academic Performance: A Quantitative Evaluation”
“Teaching Strategies and Student Learning Outcomes in Secondary Schools: A Quantitative Study”
“The Relationship Between Extracurricular Activities and Academic Success”
“Influence of Parental Involvement on Children’s Educational Achievements”
“Digital Literacy in Primary Schools: A Quantitative Assessment”
“Learning Outcomes in Blended vs. Traditional Classrooms: A Comparative Analysis”
“Correlation Between Teacher Experience and Student Success Rates”
“Analyzing the Impact of Classroom Technology on Reading Comprehension”
“Gender Differences in STEM Fields: A Quantitative Analysis of Enrollment Data”
“The Relationship Between Homework Load and Academic Burnout”
“Assessment of Special Education Programs in Public Schools”
“Role of Peer Tutoring in Improving Academic Performance: A Quantitative Study”

Medicine and Health Sciences

“The Impact of Sleep Duration on Cardiovascular Health: A Cross-sectional Study”
“Analyzing the Efficacy of Various Antidepressants: A Meta-Analysis”
“Patient Satisfaction in Telehealth Services: A Quantitative Assessment”
“Dietary Habits and Incidence of Heart Disease: A Quantitative Review”
“Correlations Between Stress Levels and Immune System Functioning”
“Smoking and Lung Function: A Quantitative Analysis”
“Influence of Physical Activity on Mental Health in Older Adults”
“Antibiotic Resistance Patterns in Community Hospitals: A Quantitative Study”
“The Efficacy of Vaccination Programs in Controlling Disease Spread: A Time-Series Analysis”
“Role of Social Determinants in Health Outcomes: A Quantitative Exploration”
“Impact of Hospital Design on Patient Recovery Rates”
“Quantitative Analysis of Dietary Choices and Obesity Rates in Children”

Social Sciences

“Examining Social Inequality through Wage Distribution: A Quantitative Study”
“Impact of Parental Divorce on Child Development: A Longitudinal Study”
“Social Media and its Effect on Political Polarization: A Quantitative Analysis”
“The Relationship Between Religion and Social Attitudes: A Statistical Overview”
“Influence of Socioeconomic Status on Educational Achievement”
“Quantifying the Effects of Community Programs on Crime Reduction”
“Public Opinion and Immigration Policies: A Quantitative Exploration”
“Analyzing the Gender Representation in Political Offices: A Quantitative Study”
“Impact of Mass Media on Public Opinion: A Regression Analysis”
“Influence of Urban Design on Social Interactions in Communities”
“The Role of Social Support in Mental Health Outcomes: A Quantitative Analysis”
“Examining the Relationship Between Substance Abuse and Employment Status”

Engineering and Technology

“Performance Evaluation of Different Machine Learning Algorithms in Autonomous Vehicles”
“Material Science: A Quantitative Analysis of Stress-Strain Properties in Various Alloys”
“Impacts of Data Center Cooling Solutions on Energy Consumption”
“Analyzing the Reliability of Renewable Energy Sources in Grid Management”
“Optimization of 5G Network Performance: A Quantitative Assessment”
“Quantifying the Effects of Aerodynamics on Fuel Efficiency in Commercial Airplanes”
“The Relationship Between Software Complexity and Bug Frequency”
“Machine Learning in Predictive Maintenance: A Quantitative Analysis”
“Wearable Technologies and their Impact on Healthcare Monitoring”
“Quantitative Assessment of Cybersecurity Measures in Financial Institutions”
“Analysis of Noise Pollution from Urban Transportation Systems”
“The Influence of Architectural Design on Energy Efficiency in Buildings”

Quantitative Research Topics

Quantitative Research Topics are as follows:

The effects of social media on self-esteem among teenagers.
A comparative study of academic achievement among students of single-sex and co-educational schools.
The impact of gender on leadership styles in the workplace.
The correlation between parental involvement and academic performance of students.
The effect of mindfulness meditation on stress levels in college students.
The relationship between employee motivation and job satisfaction.
The effectiveness of online learning compared to traditional classroom learning.
The correlation between sleep duration and academic performance among college students.
The impact of exercise on mental health among adults.
The relationship between social support and psychological well-being among cancer patients.
The effect of caffeine consumption on sleep quality.
A comparative study of the effectiveness of cognitive-behavioral therapy and pharmacotherapy in treating depression.
The relationship between physical attractiveness and job opportunities.
The correlation between smartphone addiction and academic performance among high school students.
The impact of music on memory recall among adults.
The effectiveness of parental control software in limiting children’s online activity.
The relationship between social media use and body image dissatisfaction among young adults.
The correlation between academic achievement and parental involvement among minority students.
The impact of early childhood education on academic performance in later years.
The effectiveness of employee training and development programs in improving organizational performance.
The relationship between socioeconomic status and access to healthcare services.
The correlation between social support and academic achievement among college students.
The impact of technology on communication skills among children.
The effectiveness of mindfulness-based stress reduction programs in reducing symptoms of anxiety and depression.
The relationship between employee turnover and organizational culture.
The correlation between job satisfaction and employee engagement.
The impact of video game violence on aggressive behavior among children.
The effectiveness of nutritional education in promoting healthy eating habits among adolescents.
The relationship between bullying and academic performance among middle school students.
The correlation between teacher expectations and student achievement.
The impact of gender stereotypes on career choices among high school students.
The effectiveness of anger management programs in reducing violent behavior.
The relationship between social support and recovery from substance abuse.
The correlation between parent-child communication and adolescent drug use.
The impact of technology on family relationships.
The effectiveness of smoking cessation programs in promoting long-term abstinence.
The relationship between personality traits and academic achievement.
The correlation between stress and job performance among healthcare professionals.
The impact of online privacy concerns on social media use.
The effectiveness of cognitive-behavioral therapy in treating anxiety disorders.
The relationship between teacher feedback and student motivation.
The correlation between physical activity and academic performance among elementary school students.
The impact of parental divorce on academic achievement among children.
The effectiveness of diversity training in improving workplace relationships.
The relationship between childhood trauma and adult mental health.
The correlation between parental involvement and substance abuse among adolescents.
The impact of social media use on romantic relationships among young adults.
The effectiveness of assertiveness training in improving communication skills.
The relationship between parental expectations and academic achievement among high school students.
The correlation between sleep quality and mood among adults.
The impact of video game addiction on academic performance among college students.
The effectiveness of group therapy in treating eating disorders.
The relationship between job stress and job performance among teachers.
The correlation between mindfulness and emotional regulation.
The impact of social media use on self-esteem among college students.
The effectiveness of parent-teacher communication in promoting academic achievement among elementary school students.
The impact of renewable energy policies on carbon emissions
The relationship between employee motivation and job performance
The effectiveness of psychotherapy in treating eating disorders
The correlation between physical activity and cognitive function in older adults
The effect of childhood poverty on adult health outcomes
The impact of urbanization on biodiversity conservation
The relationship between work-life balance and employee job satisfaction
The effectiveness of eye movement desensitization and reprocessing (EMDR) in treating trauma
The correlation between parenting styles and child behavior
The effect of social media on political polarization
The impact of foreign aid on economic development
The relationship between workplace diversity and organizational performance
The effectiveness of dialectical behavior therapy in treating borderline personality disorder
The correlation between childhood abuse and adult mental health outcomes
The effect of sleep deprivation on cognitive function
The impact of trade policies on international trade and economic growth
The relationship between employee engagement and organizational commitment
The effectiveness of cognitive therapy in treating postpartum depression
The correlation between family meals and child obesity rates
The effect of parental involvement in sports on child athletic performance
The impact of social entrepreneurship on sustainable development
The relationship between emotional labor and job burnout
The effectiveness of art therapy in treating dementia
The correlation between social media use and academic procrastination
The effect of poverty on childhood educational attainment
The impact of urban green spaces on mental health
The relationship between job insecurity and employee well-being
The effectiveness of virtual reality exposure therapy in treating anxiety disorders
The correlation between childhood trauma and substance abuse
The effect of screen time on children’s social skills
The impact of trade unions on employee job satisfaction
The relationship between cultural intelligence and cross-cultural communication
The effectiveness of acceptance and commitment therapy in treating chronic pain
The correlation between childhood obesity and adult health outcomes
The effect of gender diversity on corporate performance
The impact of environmental regulations on industry competitiveness.
The impact of renewable energy policies on greenhouse gas emissions
The relationship between workplace diversity and team performance
The effectiveness of group therapy in treating substance abuse
The correlation between parental involvement and social skills in early childhood
The effect of technology use on sleep patterns
The impact of government regulations on small business growth
The relationship between job satisfaction and employee turnover
The effectiveness of virtual reality therapy in treating anxiety disorders
The correlation between parental involvement and academic motivation in adolescents
The effect of social media on political engagement
The impact of urbanization on mental health
The relationship between corporate social responsibility and consumer trust
The correlation between early childhood education and social-emotional development
The effect of screen time on cognitive development in young children
The impact of trade policies on global economic growth
The relationship between workplace diversity and innovation
The effectiveness of family therapy in treating eating disorders
The correlation between parental involvement and college persistence
The effect of social media on body image and self-esteem
The impact of environmental regulations on business competitiveness
The relationship between job autonomy and job satisfaction
The effectiveness of virtual reality therapy in treating phobias
The correlation between parental involvement and academic achievement in college
The effect of social media on sleep quality
The impact of immigration policies on social integration
The relationship between workplace diversity and employee well-being
The effectiveness of psychodynamic therapy in treating personality disorders
The correlation between early childhood education and executive function skills
The effect of parental involvement on STEM education outcomes
The impact of trade policies on domestic employment rates
The relationship between job insecurity and mental health
The effectiveness of exposure therapy in treating PTSD
The correlation between parental involvement and social mobility
The effect of social media on intergroup relations
The impact of urbanization on air pollution and respiratory health.
The relationship between emotional intelligence and leadership effectiveness
The effectiveness of cognitive-behavioral therapy in treating depression
The correlation between early childhood education and language development
The effect of parental involvement on academic achievement in STEM fields
The impact of trade policies on income inequality
The relationship between workplace diversity and customer satisfaction
The effectiveness of mindfulness-based therapy in treating anxiety disorders
The correlation between parental involvement and civic engagement in adolescents
The effect of social media on mental health among teenagers
The impact of public transportation policies on traffic congestion
The relationship between job stress and job performance
The effectiveness of group therapy in treating depression
The correlation between early childhood education and cognitive development
The effect of parental involvement on academic motivation in college
The impact of environmental regulations on energy consumption
The relationship between workplace diversity and employee engagement
The effectiveness of art therapy in treating PTSD
The correlation between parental involvement and academic success in vocational education
The effect of social media on academic achievement in college
The impact of tax policies on economic growth
The relationship between job flexibility and work-life balance
The effectiveness of acceptance and commitment therapy in treating anxiety disorders
The correlation between early childhood education and social competence
The effect of parental involvement on career readiness in high school
The impact of immigration policies on crime rates
The relationship between workplace diversity and employee retention
The effectiveness of play therapy in treating trauma
The correlation between parental involvement and academic success in online learning
The effect of social media on body dissatisfaction among women
The impact of urbanization on public health infrastructure
The relationship between job satisfaction and job performance
The effectiveness of eye movement desensitization and reprocessing therapy in treating PTSD
The correlation between early childhood education and social skills in adolescence
The effect of parental involvement on academic achievement in the arts
The impact of trade policies on foreign investment
The relationship between workplace diversity and decision-making
The effectiveness of exposure and response prevention therapy in treating OCD
The correlation between parental involvement and academic success in special education
The impact of zoning laws on affordable housing
The relationship between job design and employee motivation
The effectiveness of cognitive rehabilitation therapy in treating traumatic brain injury
The correlation between early childhood education and social-emotional learning
The effect of parental involvement on academic achievement in foreign language learning
The impact of trade policies on the environment
The relationship between workplace diversity and creativity
The effectiveness of emotion-focused therapy in treating relationship problems
The correlation between parental involvement and academic success in music education
The effect of social media on interpersonal communication skills
The impact of public health campaigns on health behaviors
The relationship between job resources and job stress
The effectiveness of equine therapy in treating substance abuse
The correlation between early childhood education and self-regulation
The effect of parental involvement on academic achievement in physical education
The impact of immigration policies on cultural assimilation
The relationship between workplace diversity and conflict resolution
The effectiveness of schema therapy in treating personality disorders
The correlation between parental involvement and academic success in career and technical education
The effect of social media on trust in government institutions
The impact of urbanization on public transportation systems
The relationship between job demands and job stress
The correlation between early childhood education and executive functioning
The effect of parental involvement on academic achievement in computer science
The effectiveness of cognitive processing therapy in treating PTSD
The correlation between parental involvement and academic success in homeschooling
The effect of social media on cyberbullying behavior
The impact of urbanization on air quality
The effectiveness of dance therapy in treating anxiety disorders
The correlation between early childhood education and math achievement
The effect of parental involvement on academic achievement in health education
The impact of global warming on agriculture
The effectiveness of narrative therapy in treating depression
The correlation between parental involvement and academic success in character education
The effect of social media on political participation
The impact of technology on job displacement
The relationship between job resources and job satisfaction
The effectiveness of art therapy in treating addiction
The correlation between early childhood education and reading comprehension
The effect of parental involvement on academic achievement in environmental education
The impact of income inequality on social mobility
The relationship between workplace diversity and organizational culture
The effectiveness of solution-focused brief therapy in treating anxiety disorders
The correlation between parental involvement and academic success in physical therapy education
The effect of social media on misinformation
The impact of green energy policies on economic growth
The relationship between job demands and employee well-being
The correlation between early childhood education and science achievement
The effect of parental involvement on academic achievement in religious education
The impact of gender diversity on corporate governance
The relationship between workplace diversity and ethical decision-making
The correlation between parental involvement and academic success in dental hygiene education
The effect of social media on self-esteem among adolescents
The impact of renewable energy policies on energy security
The effect of parental involvement on academic achievement in social studies
The impact of trade policies on job growth
The relationship between workplace diversity and leadership styles
The correlation between parental involvement and academic success in online vocational training
The effect of social media on self-esteem among men
The impact of urbanization on air pollution levels
The effectiveness of music therapy in treating depression
The correlation between early childhood education and math skills
The effect of parental involvement on academic achievement in language arts
The impact of immigration policies on labor market outcomes
The effectiveness of hypnotherapy in treating phobias
The effect of social media on political engagement among young adults
The impact of urbanization on access to green spaces
The relationship between job crafting and job satisfaction
The effectiveness of exposure therapy in treating specific phobias
The correlation between early childhood education and spatial reasoning
The effect of parental involvement on academic achievement in business education
The impact of trade policies on economic inequality
The effectiveness of narrative therapy in treating PTSD
The correlation between parental involvement and academic success in nursing education
The effect of social media on sleep quality among adolescents
The impact of urbanization on crime rates
The relationship between job insecurity and turnover intentions
The effectiveness of pet therapy in treating anxiety disorders
The correlation between early childhood education and STEM skills
The effect of parental involvement on academic achievement in culinary education
The impact of immigration policies on housing affordability
The relationship between workplace diversity and employee satisfaction
The effectiveness of mindfulness-based stress reduction in treating chronic pain
The correlation between parental involvement and academic success in art education
The effect of social media on academic procrastination among college students
The impact of urbanization on public safety services.

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Nanotechnology: A Revolution in Modern Industry

Shiza malik.

1 Bridging Health Foundation, Rawalpindi 46000, Pakistan

Khalid Muhammad

2 Department of Biology, College of Science, UAE University, Al Ain 15551, United Arab Emirates

Yasir Waheed

3 Office of Research, Innovation, and Commercialization (ORIC), Shaheed Zulfiqar Ali Bhutto Medical University (SZABMU), Islamabad 44000, Pakistan

4 Gilbert and Rose-Marie Chagoury School of Medicine, Lebanese American University, Byblos 1401, Lebanon

Associated Data

Not applicable.

Nanotechnology, contrary to its name, has massively revolutionized industries around the world. This paper predominantly deals with data regarding the applications of nanotechnology in the modernization of several industries. A comprehensive research strategy is adopted to incorporate the latest data driven from major science platforms. Resultantly, a broad-spectrum overview is presented which comprises the diverse applications of nanotechnology in modern industries. This study reveals that nanotechnology is not limited to research labs or small-scale manufacturing units of nanomedicine, but instead has taken a major share in different industries. Companies around the world are now trying to make their innovations more efficient in terms of structuring, working, and designing outlook and productivity by taking advantage of nanotechnology. From small-scale manufacturing and processing units such as those in agriculture, food, and medicine industries to larger-scale production units such as those operating in industries of automobiles, civil engineering, and environmental management, nanotechnology has manifested the modernization of almost every industrial domain on a global scale. With pronounced cooperation among researchers, industrialists, scientists, technologists, environmentalists, and educationists, the more sustainable development of nano-based industries can be predicted in the future.

1. Introduction

Nanotechnology has slowly yet deeply taken over different industries worldwide. This rapid pace of technological revolution can especially be seen in the developed world, where nano-scale markets have taken over rapidly in the past decade. Nanotechnology is not a new concept since it has now become a general-purpose technology. Four generations of nanomaterials have emerged on the surface and are used in interdisciplinary scientific fields; these are active and passive nanoassemblies, general nanosystems, and small-scale molecular nanosystems [ 1 ].

This rapid development of nanoscience is proof that, soon, nano-scale manufacturing will be incorporated into almost every domain of science and technology. This review article will cover the recent advanced applications of nanotechnology in different industries, mainly agriculture, food, cosmetics, medicine, healthcare, automotive, oil and gas industries, chemical, and mechanical industries [ 2 , 3 ]. Moreover, a brief glimpse of the drawbacks of nanotechnology will be highlighted for each industry to help the scientific community become aware of the ills and benefits of nanotechnology side by side. Nanotechnology is a process that combines the basic attributes of biological, physical, and chemical sciences. These processes occur at the minute scale of nanometers. Physically, the size is reduced; chemically, new bonds and chemical properties are governed; and biological actions are produced at the nano scale, such as drug bonding and delivery at particular sites [ 4 , 5 ].

Nanotechnology provides a link between classical and quantum mechanics in a gray area called a mesoscopic system. This mesoscopic system is being used to manufacture nanoassemblies of nature such as agricultural products, nanomedicine, and nanotools for treatment and diagnostic purposes in the medical industry [ 6 ]. Diseases that were previously untreatable are now being curtailed via nano-based medications and diagnostic kits. This technology has greatly affected bulk industrial manufacturing and production as well. Instead of manufacturing materials by cutting down on massive amounts of material, nanotechnology uses the reverse engineering principle, which operates in nature. It allows the manufacturing of products at the nano scale, such as atoms, and then develops products to work at a deeper scale [ 7 ].

Worldwide, millions and billions of dollars and euros are being spent in nanotechnology to utilize the great potential of this new science, especially in the developed world in Europe, China, and America [ 8 ]. However, developing nations are still lagging behind as they are not even able to meet the industrial progression of the previous decade [ 9 ]. This lag is mainly because these countries are still fighting economically, and they need some time to walk down the road of nanotechnology. However, it is pertinent to say that both the developed and developing world’s scientific communities agree that nanotechnology will be the next step in technological generation [ 10 ]. This will make further industrial upgrading and investment in the field of nanotechnology indispensable in the coming years.

With advances in science and technology, the scientific community adopts technologies and products that are relatively cheap, safe, and cleaner than previous technologies. Moreover, they are concerned about the financial standing of technologies, as natural resources in the world are shrinking excessively [ 11 ]. Nanotechnology thus provides a gateway to this problem. This technology is clear, cleaner, and more affordable compared to previous mass bulking and heavy machinery. Moreover, nanotechnology holds the potential to be implemented in every aspect of life. This will mainly include nanomaterial sciences, nanoelectronics, and nanomedicine, being inculcated in all dimensions of chemistry and the physical and biological world [ 12 ]. Thus, it is not wrong to predict that nanotechnology will become a compulsory field of study for future generations [ 13 ]. This review inculcates the basic applications of nanotechnology in vital industries worldwide and their implications for future industrial progress [ 14 ].

2. Nanotechnology Applications

2.1. applications of nanotechnology in different industries.

After thorough and careful analyses, a wide range of industries—in which nanotechnology is producing remarkable applications—have been studied, reviewed, and selected to be made part of this review. It should be notified that multiple subcategories of industrial links may be discussed under one heading to elaborate upon the wide-scale applications of nanotechnology in different industries. A graphical abstract at the beginning of this article indicates the different industries in which nanotechnology is imparting remarkable implications, details of which are briefly discussed under different headings in the next session.

2.2. Nanotechnology and Computer Industry

Nanotechnology has taken its origins from microengineering concepts in physics and material sciences [ 15 ]. Nanoscaling is not a new concept in the computer industry, as technologists and technicians have been working for a long time to design such modified forms of computer-based technologies that require minimum space for the most efficient work. Resultantly, the usage of nanotubes instead of silicon chips is being increasingly experimented upon in computer devices. Feynman and Drexler’s work has greatly inspired computer scientists to design revolutionary nanocomputers from which wide-scale advantages could be attained [ 13 ]. A few years ago, it was an unimaginable to consider laptops, mobiles, and other handy gadgets as thin as we have today, and it is impossible for even the common man to think that with the passage of time, more advanced, sophisticated, and lighter computer devices will be commonly used. Nanotechnology holds the potential to make this possible [ 16 ].

Energy-efficient, sustainable, and urbanized technologies have been emerging since the beginning of the 21st century. The improvement via nanotechnology in information and communication technology (ICT) is noteworthy in terms of the improvements achieved in interconnected communities, economic competitiveness, environmental stability during demographic shifts, and global development [ 17 ]. The major implications of renewable technology incorporate the roles of ICT and nanotechnology as enablers of environmental sustainability. The traditional methods of product resizing, re-functioning, and enhanced computational capabilities, due to their expensiveness and complicated manufacturing traits, have slowly been replaced by nanotechnological renovations. Novel technologies such as smart sensors logic elements, nanochips, memory storage nanodevices, optoelectronics, quantum computing, and lab-on-a-chip technologies are important in this regard [ 18 ].

Both private and public spending are increasing in the field of nanocomputing. The growth of marketing and industrialization in the biotechnology and computer industries are running in parallel, and their expected growth rates for the coming years are far higher. Researchers and technologists believe that by linking the advanced field of nanotechnology and informatics and computational industries, various problems in human society such as basic need fulfillment can be easily accomplished in line with the establishment of sustainable goals by the end of this decade [ 19 ]. The fourth industrial revolution is based upon the supporting pillars derived from hyperphysical systems including artificial intelligence, machine learning, the internet of things, robots, drones, cloud computing, fast internet technologies (5G and 6G), 3D printing, and block chain technologies [ 20 ].

Most of these technologies have a set basis in computing, nanotechnology, biotechnology, material science renovations, and satellite technologies. Nanotechnology offers useful alterations in the physiochemical, mechanical, magnetic, electrical, and optical properties of computing materials which enable innovative and newer products [ 21 ]. Thus, nanotechnology is providing a pathway for another broad-spectrum revolution in the field of automotive, aerospace, renewable energy, information technology, bioinformatics, and environmental management, all of which have root origins from nanotechnological improvements in computers. Sensors involved in software and data algorithms employ nanomaterials to induce greater sensitivity and processabilities with minimal margin-to-machine errors [ 22 ]. Nanomaterials provide better characteristics and robustness to sensor technologies which mean they are chemically inert, corrosion-resistant, and have greater tolerance profiles toward temperature and alkalinity [ 22 ].

Moreover, the use of semiconductor nanomaterials in the field of quantum computing has increased overall processing speeds with better accuracy and transmissibility. These technologies offer the creation of different components and communication protocols at the nano level, which is often called the internet of nano things [ 23 ]. This area is still in a continuous development and improvement phase with the potential for telecommunication, industrial, and medical applications. This field has taken its origin from the internet of things, which is a hyperphysical world of sensors, software, and other related technologies which allow broad-scale communication via internet operating devices [ 17 ]. The applications of these technologies range from being on the simple home scale to being on the complex industrial scale. The internet of things is mainly capable of gathering and distributing large-scale data via internet-based equipment and modern gadgets. In short, the internet of nano things is applicable to software, hardware, and network connection which could be used for data manipulation, collection, and sharing across the globe [ 24 ].

Another application of nanotechnology in the computer and information industry comes in the form of artificial intelligence, machine learning, and big data platforms which have set the basis for the fourth industrial revolution. Vast amounts of raw data are collected through interconnected robotic devices, sensors, and machines which have properties of nanomaterials [ 18 ]. After wide-scale data gathering, the next step is the amalgamation of the internet of things and the internet of people to prepare a greater analysis, understanding, and utilization of the gathered information for human benefit [ 4 ]. Such data complications can be easily understood through the use of big data in the medical industry, in which epidemiological data provide benefits for disease management [ 2 ]. Yet another example is the applications in business, where sales and retail-related data help to elucidate the target markets, sales industry, and consumer behavioral inferences for greater market consumption patterns [ 19 ].

Similarly, an important dimension of nanotechnology and computer combination comes in the form of drone and robotics technology. These technologies have a rising number of applications in maintenance, inspections, transportation, deliverability, and data inspection [ 25 ]. Drones, robots, and the internet of things are being perfectly amalgamated with the industrial sector to achieve greater goals. Drones tend to be more mobile but rely more on human control as compared to robots, which are less mobile but have larger potential for self-operation [ 26 ]. However, now, more mobile drones with better autonomous profiles are being developed to help out in the domain of manufacturing industries. These devices intensify and increase the pace of automation and precision in industries along with providing the benefits of lower costs and fewer errors [ 24 ]. The integrated fields of robotics, the internet of things, and nanotechnology are often called the internet of robotics and nano things. This field of nanorobotics is increasing the flexibility and dexterity in manufacturing processes compared to traditional robotics [ 25 ].

Drones, on the contrary, help to manage tasks that are otherwise difficult or dangerous to be managed by humans, such as working from a far distance or in dangerous regions. Nanosensors help to equip drones with the qualities of improved detection and sensation more precisely than previous sensor technologies [ 21 , 27 ]. Moreover, the over-potential of working hours, battery, and maintenance have also been improved with the operationalization of nano-based sensors in drone technology. These drones are inclusively used for various purposes such as maintaining operations, employing safety profiling, security surveys, and mapping areas [ 18 ]. However, limitations such as high speed, legal and ethical limitations, safety concerns, and greater automobility are some of the drawbacks of aerial and robotic drone technologies [ 26 ].

Three-dimensional printing is yet another important application of the nanocomputer industry, in which an integrated modus operandi works to help in production management [ 28 ]. Nanotechnology-based 3D printing offers the benefits of an autonomous, integrated, intelligent exchange network of information which enables wide-scale production benefits. These technologies have enabled a lesser need for industrial infrastructure, minimized post-processing operations, reduced waste material generation, and reduced need for human presence for overall industrial management [ 28 , 29 ]. Moreover, the benefits of 3D printing and similar technologies have potentially increased flexibility in terms of customized items, minimal environmental impacts, and sustainable practices with lower resource and energy consumption. The use of nano-scale and processed resins, metallic raw material, and thermoplastics along with other raw materials allow for customized properties of 3D printing technology [ 29 ].

The application of nanotechnology in computers cannot be distinguished from other industrial applications, because everything in modern industries is controlled by a systemic network in association with a network of computers and similar technologies. Thus, the fields of electronics, manufacturing, processing, and packaging, among several others, are interlinked with nanocomputer science [ 11 , 15 ]. Silicon tubes have had immense applications that revolutionized the industrial revolution in the 20th century; now, the industrial revolution is in yet another revolutionary phase based on nanostructures [ 16 ]. Silicon tubes have been slowly replaced with nanotubes, which are allowing a great deal of improvement and efficiency in computing technology. Similarly, lab-on-a-chip technology and memory chips are being formulated at nano scales to lessen the storage space but increase the storage volume within a small, flexible, and easily workable chip in computers for their subsequent applications in multiple other industries.

Hundreds of nanotechnology computer-related products have been marketed in the last 20 years of the nanotechnological revolution [ 30 ]. Modern industries such as textiles, automotive, civil engineering, construction, solar technologies, environmental applications, medicine, transportation agriculture, and food processing, among others are largely reaping the benefits of nano-scale computer chips and other devices. In simple terms, everything out there in nanoindustrial applications has something to do with computer-based applications in the nanoindustry [ 31 , 32 , 33 ]. Thus, all the applications discussed in this review more or less originate from nanocomputers. These applications are enabling considerable improvement and positive reports within the industrial sector. Having said that, it is hoped that computer scientists will remain engaged and will keep on collaborating with scientists in other fields to further explore the opportunities associated with nanocomputer sciences.

2.3. Nanotechnology and Bioprocessing Industries

Scientific and engineering rigor is being carried out to the link fields of nanotechnology with contributions to the bioprocessing industry. Researchers are interested in how the basics of nanomaterials could be used for the high-quality manufacturing of food and other biomaterials [ 15 , 34 ]. Pathogenic identification, food monitoring, biosensor devices, and smart packaging materials, especially those that are reusable and biodegradable, and the nanoencapsulation of active food compounds are only a few nanotechnological applications which have been the prime focus of the research community in recent years. Eventually, societal acceptability and dealing with social, cultural, and ethical concerns will allow the successful delivery of nano-based bio-processed products into the common markets for public usage [ 20 , 35 ].

With the increasing population worldwide, food requirements are increasing in addition to the concerns regarding the production of safe, healthy, and recurring food options. Sensors and diagnostic devices will help improve the sensitivity in food quality monitoring [ 36 ]. Moreover, the fake industrial application of food products could be easily scanned out of a system with the application of nanotechnology which could control brand protection throughout bio-processing [ 6 ]. The power usage in food production might also be controlled after a total nanotechnological application in the food industry. The decrease in power consumption would ultimately be positive for the environment. This could directly bring in the interplay of environment, food, and nanotechnology and would help to reduce environmental concerns in future [ 37 ].

One of the important implications of nanotechnology in bioprocessing industries can be accustomed to fermentation processes; these technologies are under usage for greater industrial demand and improved biomolecule production at a very low cost, unlike traditional fermentation processes [ 35 ]. The successful implementation and integration of fermentation and nanotechnology have allowed the development of biocompatible, safe, and nontoxic substances and nanostructures with wide-scale application in the field of food, bioprocessing, and winemaking industries [ 38 ]. Another important application is in the food monitoring and food supply chain management, present in various subsectors such as production, storage, distribution, and toxicity management. Nanodevices and nanomaterials are incorporated into chemical and biological sensor technologies to improve overall analytical performance with regard to parameters such as response time, sensitivity, selectivity, accuracy, and reliability [ 39 ]. The conventional methods of food monitoring are slowly being replaced with modern nano-based materials such as nanowires, nanocomposites, nanotubes, nanorods, nanosheets, and other materials that function to immobilize and label components [ 40 ]. These methods are either electrochemically or optically managed. For food monitoring, several assays are proposed and implemented with their roots in nano-based technologies; they may include molecular and diagnostic assays, immunological assays, and electrochemical and optical assays such as surface-enhanced Raman scattering and colorimetry technologies [ 34 ]. Materials ranging from heavy materials to microorganisms, pesticides, allergens, and antibiotics are easily monitored during commercial processing and bioprocessing in industries.

Additionally, nanotechnology has presented marvelous transformations in bio-composting materials. With the rising demand for biodegradable composites worldwide to reduce the environmental impact and increase the efficiency of industrial output, there is an increasing need for sustainable technologies [ 41 ]. Nanocomposites are thus being formulated with valuable mechanical properties better than conventional polymers, thus establishing their applicability in industries. The improved properties include optical, mechanical, catalytic, electrochemical, and electrical ones [ 42 ]. These biodegradable polymers are not only used in bioprocessing industries to create food products with relevant benefits but are also being deployed in the biomedical field, therapeutic industries, biotechnology base tissue engineering field, packing, sensor industries, drug delivery technology, water remediation, food industries, and cosmetics industries as well [ 2 , 24 , 34 , 43 ]. These nanocomposites have outstanding characteristics of biocompatibility, lower toxicities, antimicrobial activity, thermal resistance, and overall improved biodegradation properties which make them worthy of applications in products [ 44 ]. However, it is still imperative to conduct wide-scale toxicity and safety profiling for these and other nanomaterials to ensure the safety requirements, customer satisfaction, and public benefit are met [ 44 ].

Moreover, the advancement of nanotechnology has also been conferred to the development of functional food items. The exposure and integration of nanotechnology and the food industry have resulted in larger quantities of sustainable, safer, and healthier food products for human consumption, which is a growing need for the rising population worldwide [ 45 ]. The overall positive impact of nanotechnology in food processing, manufacturing, packing, pathogenic detection, monitoring, and production profiles necessitates the wide-scale application of this technology in the food industry worldwide [ 4 , 41 ]. Recent research has shown how the delivery of bioactive compounds and essential ingredients is and can be improved by the application of nanomaterials (nanoencapsulation) in food products [ 46 ]. These technologies improve the protection performance and sensitivity of bioactive ingredients while preventing unnecessary interaction with other constituents of foods, thus establishing clear-cut improved bioactivity and solubility profiles of nanofoods, thereby improving human health benefits. However, it should be kept in mind that the safety regards of these food should be carefully regulated with safety profiling, as they directly interact with human bodies [ 47 ].

2.4. Nanotechnology and Agri-Industries

Agriculture is the backbone of the economies of various nations around the globe. It is a major contributing factor to the world economy in general and plays a critical role in population maintenance by providing nutritional needs to them. As global weather patterns are changing owing to the dramatic changes caused by global warming, it is accepted that agriculture will be greatly affected [ 48 ]. Under this scenario, it is always better to take proactive measures to make agricultural practices more secure and sustainable than before. Modern technology is thus being employed worldwide. Nanotechnology has also come to play an effective role in this interplay of sustainable technologies. It plays an important role during the production, processing, storing, packaging, and transport of agricultural industrial products [ 49 ].

Nanotechnology has introduced certain precision farming techniques to enhance plant nutrients’ absorbance, alongside better pathogenic detection against agricultural diseases. Fertilizers are being improved by the application of nanoclays and zeolites which play effective roles in soil nutrient broths and in the restoration soil fertility [ 49 ]. Modern concepts of smart seeds and seed banks are also programmed to germinate under favorable conditions for their survival; nanopolymeric mixtures are used for coating in these scenarios [ 50 ]. Herbicides, pesticides, fungicides, and insecticides are also being revolutionized through nanotechnology applications. It has also been considered to upgrade linked fields of poultry and animal husbandry via the application of nanotechnology in treatment and disinfection practices.

2.5. Nanotechnology and Food Industry

The applications of nanotechnology in the food industry are immense and include food manufacturing, packaging, safety measures, drug delivery to specific sites [ 51 ], smart diets, and other modern preservatives, as summarized in Figure 1 . Nanomaterials such as polymer/clay nanocomposites are used in packing materials due to their high barrier properties against environmental impacts [ 52 ]. Similarly, nanoparticle mixtures are used as antimicrobial agents to protect stored food products against rapid microbial decay, especially in canned products. Similarly, several nanosensor and nano-assembly-based assays are used for microbial detection processes in food storage and manufacturing industries [ 53 ].

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Nanotechnology applications in food and interconnected industries.

Nanoassemblies hold the potential to detect small gasses and organic and inorganic residues alongside microscopic pathogenic entities [ 54 ]. It should, however, be kept in mind that most of these nanoparticles are not directly added to food species because of the risk of toxicity that may be attached to such metallic nanoparticles. Work is being carried out to predict the toxicity attached, so that in the future, these products’ market acceptability could be increased [ 55 ]. With this, it is pertinent to say that nanotechnology is rapidly taking steps into the food industry for packing, sensing, storage, and antimicrobial applications [ 56 ].

Nanotechnology is also revolutionizing the dairy industry worldwide [ 57 ]. An outline of potential applications of nanotechnology in the dairy industry may include: improved processing methods, improved food contact and mixing, better yields, the increased shelf life and safety of dairy-based products, improved packaging, and antimicrobial resistance [ 58 ]. Additionally, nanocarriers are increasingly applied to transfer biologically active substances, drugs, enhanced flavors, colors, odors, and other food characteristics to dairy products [ 59 ].

These compounds exhibit higher delivery, solubility, and absorption properties to their targeted system. However, the problem of public acceptability due to the fear of unknown or potential side effects associated with nano-based dairy and food products needs to be addressed for the wider-scale commercialization of these products [ 60 ].

2.5.1. Nanotechnology, Poultry and Meat Industry

The poultry industry is a big chunk of the food industry and contributes millions of dollars every year to food industries around the world. Various commercial food chains are running throughout the world, the bases of which start from healthy poultry industries. The incidence of widespread foodborne diseases that originate from poultry, milk, and meat farms is a great concern for the food industry. Nanobiotechnology is certainly playing a productive role in tackling food pathogens such as those which procreate from Salmonella and Campylobacter infections by allowing increased poultry consumption while maintaining the affordability and safety of manufactured chicken products [ 61 ]. Several nano-based tools and materials such as nano-enabled disinfectants, surface biocides, protective clothing, air and water filters, packaging materials, biosensors, and detective devices are being used to confirm the authenticity and traceability of poultry products [ 62 ]. Moreover, nano-based materials are used to reduce foodborne pathogens and spoilage organisms before the food becomes part of the supply chain [ 63 ].

2.5.2. Nanotechnology—Fruit and Vegetable Industry

As already described, nanotechnology has made its way far ahead in the food industry. The agricultural, medicinal, and fruit and vegetable industries cannot remain unaffected under this scenario. Scientists are trying to increase the shelf life of fresh organic products to fulfill the nutritional needs of a growing population. From horticulture to food processing, packaging, and pathogenic detection technology, nanotechnology plays a vital role in the safety and production of vegetables and fruits [ 64 ].

Conventional technologies are now being replaced with nanotechnology due to their benefits of cost-effectiveness, satisfactory results, and overall shelf life improvement compared to past practices. Although some risks may be attached, nanotechnology has not yet reported high-grade toxicity to organic fresh green products. These technologies serve the purpose of providing safe and sufficient food sources to customers while reducing postharvest wastage, which is a major concern in developing nations [ 55 ]. Nanopackaging provides the benefits of lower humidity, oxygen passage, and optimal water vapor transmission rates. Hence, in the longer run, the shelf life of such products is increased to the desired level using nanotechnology [ 65 ].

2.5.3. Nanotechnology and Winemaking Industry

The winemaking industry is a big commercial application of the food industry worldwide. The usage of nanotechnology is also expanding in this industry. Nanotechnology serves the purpose of sensing technology through employment as nanoelectronics, nanoelectrochemical, and biological, amperometric, or fluorimetric sensors. These nanomaterials help to analyze the wine components, including polyphenols, organic acids, biogenic amines, or sulfur dioxide, and ensure they are at appropriate levels during the production of wine and complete processing [ 66 ].

Efforts are being made to further improve sensing nanotechnology to increase the accuracy, selectivity, sensitivity, and rapid response rate for wine sampling, production, and treatment procedures [ 53 ]. Specific nanoassemblies that are used in winemaking industries include carbon nanorods, nanodots, nanotubes, and metallic nanoparticles such as gold, silver, zinc oxide, iron oxide, and other types of nanocomposites. Recent research studies have introduced the concept of electronic tongues, nanoliquid chromatography, mesoporous silica, and applications of magnetic nanoparticles in winemaking products [ 67 ]. An elaborative account of these nanomaterials is out of the scope of the present study; however, on a broader scale, it is not wrong to say that nanotechnology is successfully reaping in the field of enology.

2.6. Nanotechnology and Packaging Industries

The packaging industry is continuously under improvement since the issue of environmentalism has been raised around the globe. Several different concerns are linked to the packaging industry; primarily, packaging should provide food safety to deliver the best quality to the consumer end. In addition, packaging needs to be environmentally friendly to reduce the food-waste-related pollution concern and to make the industrial processes more sustainable. Trials are being carried out to reduce the burden by replacing non-biodegradable plastic packaging materials with eco-friendly organic biopolymer-based materials which are processed at the nano scale to incur the beneficial properties of nanotechnology [ 68 ].

The nanomanufacturing of packaging biomaterials has proven effective in food packaging industries, as nanomanufacturing not only contributes to increasing food safety and production but also tackles environmental issues [ 69 ]. Some examples of these packaging nanomaterials may include anticaking agents, nanoadditives, delivery systems for nutraceuticals, and many more. The nanocompositions of packing materials are formed by mixing nanofillers and biopolymers to enhance packaging’s functionality [ 70 ]. Nanomaterials with antimicrobial properties are preferred in these cases, and they are mixed with a polymer to prevent the contamination of the packaged material. It is important to mention here that this technology is not only limited to food packaging; instead, packaging nanotechnology is now also being introduced in certain other industries such as textile, leather, and cosmetic industries in which it is providing large benefits to those industries [ 64 ].

2.7. Nanotechnology and Construction Industry and Civil Engineering

Efficient construction is the new normal application for sustainable development. The incorporation of nanomaterials in the construction industry is increasing to further the sustainability concern [ 71 ]. Nanomaterials are added to act as binding agents in cement. These nanoparticles enhance the chemical and physical properties of strength, durability, and workability for the long-lasting potential of the construction industry. Materials such as silicon dioxide which were previously also in use are now manufactured at the nano scale [ 71 ]. These nanostructures along with polymeric additives increase the density and stability of construction suspension [ 72 ]. The aspect of sustainable development is being applied to the manufacture of modern technologies coupled with beneficial applications of nanotechnology. This concept has produced novel isolative and smart window technologies which have driven roots in nanoengineering, such as vacuum insulation panels (VIPs) and phase change materials (PCMs), which provide thermal insulation effects and thus save energy and improve indoor air quality in homes [ 73 ].

A few of the unique properties of nanomaterials in construction include light structure, strengthened structural composition, low maintenance requirements, resistant coatings, improved pipe and bridge joining materials, improved cementitious materials, extensive fire resistance, sound absorption, and insulation properties, as well as the enhanced reflectivity of glass surfaces [ 74 ]. As elaborated under the heading of civil engineering applications, concrete’s properties are the most commonly discussed and widely changing in the construction industry because of concrete’s minute structure, which can be easily converted to the nano scale [ 75 ]. More specifically, the combination of nano-SiO 2 in cement could improve its performance in terms of compressiveness, large volumes with increased compressiveness, improved pore size distribution, and texture strength [ 76 ].

Moreover, some studies are also being carried out to improve the cracking properties of concrete by the application of microencapsulated healing polymers, which reduce the cracking properties of cement [ 77 ]. Moreover, some other construction materials, such as steel, are undergoing research to change their structural composites through nano-scale manufacturing. This nanoscaling improves steel’s properties such as improved corrosion resistance, increased weldability, the ease of handling for designing building materials, and construction work [ 78 ]. Additionally, coating materials have been improved by being manufactured at the nano scale. This has led to different improved coating properties such as functional improvement; anticorrosive action; high-temperature, fire, scratch, and abrasion resistance; antibacterial and antifouling self-healing capabilities; and self-assembly, among other useful applications [ 79 ].

Nanotechnology improves the compressive flexural properties of cement and reduces its porosity, making it absorb less water compared to traditional cementation preparations. This is because of the high surface-to-volume ratio of nanosized particles. Such an approach helps in reducing the amount of cement in concrete, making it more cost-effective, more strengthening, and eco-friendly, known as ‘green concrete’. Besides concrete, the revolutionary characteristics of nanotechnology are now also being adopted in other construction materials such as steel, glass, paper, wood, and multiple other engineering materials to upgrade the construction industry [ 80 ].

Similarly, carbon nanotubes, nanorods, and nanofibers are rapidly replacing steel constructions. These nanostructures along with nanoclay formations increase the mechanical properties and thus have paved the way for a new branch of civil engineering in terms of nanoengineering [ 80 ]. Apart from cement formulations, nanoparticles are included in repair mortars and concrete with healing properties that help in crack recovery in buildings. Furthermore, nanostructures, titanium dioxide, zinc, and other metallic oxides are being employed for the production of photocatalytic products with antipathogenic, self-cleaning, and water- and germ-repellent built-in technologies [ 33 ]. Similarly, quantum dot technologies are progressively employed for solar energy generation (a concept discussed later). These photovoltaic cells contribute to saving the maximum amount of solar energy [ 81 ].

2.8. Nanotechnology and Textiles Industry

The textile industry achieved glory in the 21st century with enormous outgrowth through social media platforms. Large brands have taken over the market worldwide, and millions are earned every year through textile industries. With the passing of time, nanotechnology is being slowly incorporated into the textile fiber industry owing to its unique and valuable properties. Previously, fabrics manufactured via conventional methods often curtailed the temporary effects of durability and quality [ 82 ]. However, the age of nanotechnology has allowed these fabric industries to employ nanotechnology to provide high durability, flexibility, and quality to clothes which is not lost upon laundering and wearing. The high surface-to-volume ratio of nanomaterials keeps high surface energy and thus provides better affinity to their fabrics, leading to long-term durability [ 82 ]. Moreover, a thin layering and coating of nanoparticles on the fabric make them breathable and make them smooth to the touch. This layering is carried out by processes such as printing, washing, padding, rinsing, drying, and curing to attach nanoparticles on the fabric surface. These processes are carried out to impart the properties of water repellence, soil resistance, flame resistance, hydrophobicity, wrinkle resistance, antibacterial and antistatic properties, and increased dyeability to the clothes [ 83 ].

The unique properties of nanomaterials in textile industries have attracted large-scale businesses for the financial benefits attached to their application. For this reason, competitors are increasing in nanotextile industry speedily, which may make the conventional textile industry sidelined in the near future [ 84 ]. Some benefits associated with nanotextile engineering and industry may include: improved cleaning surfaces, soil, wrinkle, stain, and color damage resistance, higher wettability and strike-through characteristics, malodor- and soil-removal abilities, abrasion resistance, a modified version of surface friction, and color enhancement through nanomaterials [ 85 ].

These characteristics have hugely improved the functionality and performance characteristics of textile and fiber materials [ 86 ]. Based upon the numerous advantages, nanotextile technology is increasingly being used in various inter-related fields, including in medical clothes, geotextiles, shock-resistant textiles, and fire-resistant and water-resistant textiles [ 87 ]. These textiles and fibers help overcome severe environmental conditions in special industries where high temperatures, pressure, and other conditions are adjusted for manufacturing purposes. These textiles are now increasingly called smart clothes due to renewed nanotechnological application to traditional methods [ 88 ].

The increasing demand for durable, appealing, and functionally outstanding textile products with a couple of factors of sustainability has allowed science to incorporate nanotechnology in the textile sector. These nano-based materials offer textile properties such as stain-repellent, wrinkle-free textures and fibers’ electrical conductivity alongside guaranteeing comfort and flexibility in clothing [ 82 ]. The characteristics of nanomaterials are also exhibited in the form of connected garments creation that undergo sensations to respond to external stimuli through electrical, colorant, or physiological signals. Thus, a kind of interconnection develops between the fields of photonic, electrical, textile and nanotechnologies [ 89 ]. Their interconnected applications confer the properties of high-scale performance, lasting durability, and connectivity in textile fibers. However, the concerns of nanotoxicity, the chances of the release of nanomaterials during washing, and the overall environmental impact of nanotextiles are important challenges that need to be ascertained and dealt with successfully in the coming years to ensure wide-scale acceptance and the global broad-spectrum application of nanotextiles [ 90 ].

The global market for the textile industry is constantly on the rise; with so many new brands, the competition is rising in regard to pricing, material, product outlook, and market exposure. Under this scenario, nanotechnology has contributed in terms of value addition to textiles by contributing the properties of water repellence, self-cleaning, and protection from radiation and UV light, along with safety against flames and microorganisms [ 82 ]. A whole new market of smart clothes is slowly taking our international markets along with improvements in textile machinery and economic standing. These advances have effectively established the sustainable character of the textile industry and have created grounds to meet the customer’s demand [ 91 ]. Some important examples of smart clothing originating from the nanotextile industry can be seen in products such as bulletproof jackets, fabric coatings, and advanced nanofibers. Fabric coatings and pressure pads can exhibit characteristics of invisibility and entail a silver, nickel, or gold nanoparticle-based material with inherent antimicrobial properties [ 92 ]. Such materials are effectively being utilized and introduced into the medical industry for bandages, dressings, etc. [ 92 ].

Similarly, woven optical fibers are already making progress in the textile and IT industry. With the incorporation of nanomaterials, optical fibers are being utilized for a range of purposes such as light transmission, sensing technologies, deformation, improved formational characteristic detection, and long-range data transmission. These optical fibers with phase-changing material properties can also be utilized for thermostability maintenance in the fiber industry. Thus, these fibers have combined applications in the computer, IT, and textile sectors [ 93 ]. In addition, the nano cellulosic material that is naturally obtained from plants confers properties of stiffness, strength, durability, and large surface area to volume ratios, which is acquired through the large number of surface hydroxyl groups embedded in nanocellulose particles [ 94 ]. Moreover, the characteristics of high resistance, lower weight, cost-effectiveness, and electrical conductivity are some additional benefits which are also linked to these nanocellulosic fibers [ 93 ]. The aforementioned technologies will allow industrialists to manufacture fabrics based on nanomaterials through a variety of chemical, physical, and biological processes. The scope of improvement in the textile properties, cost, and production methods is making the nanotextile industry a strong field of interest for future industrial investments.

2.9. Nanotechnology and Transport and Automobile Industry

The automotive industry is always improving its production. Nanotechnology is one such tool that could impart the automotive industry with a totally new approach to manufacturing. Automobile shaping could be improved greatly without any changes to the raw materials used. The replacement of conventional fabrication procedures with advanced nanomanufacturing is required to achieve the required outcome. Nanotechnology intends to partly renovate the automobile industry by enhancing the technical performance and reducing production costs excessively. However, there is a gap in fully harnessing the potential of nanomaterials in the automotive industry. Industrialists who were previously strict about automotive industrial principles are ready to employ novelties attached to nanotechnology to create successful applications to automobiles in the future [ 95 ]. Nanotechnology could provide assistance in manufacturing methods with an impartment of extended life properties. Cars that have been manufactured with nanotechnology applications have shown lower failure rates and enhanced self-repairing properties. Although the initial investment in the nanoautomated industry is high, the outcomes are enormous.

The concept of sustainable transport could also be applied to the manufacturing of such nano-based technology which is CO 2 free and imparts safe driving and quiet, clean, and wider-screen cars, which, in the future, may be called nanocars. The major interplay of nanotechnology and the automotive industry comes in the manufacturing of car parts, engines, paints, coating materials, suspensions, breaks, lubrication, and exhaust systems [ 32 ]. These properties are largely imparted via carbon nanotubes and carbon black, which renders new functionalities to automobiles. These products were previously in use, but nanoscaling and nanocoating allow for enhanced environmental, thermal, and mechanical stability to be imparted to the new generation of automobiles. In simple terms, automobiles manufactured with principal nanonovelties could result in cars with less wearing risk, better gliding potential, thinner coating lubrication requirements, and long service bodies with weight reductions [ 31 ]. These properties will ultimately reduce costs and will impart more space for improved automobile manufacturing in the future. Similarly, the development of electric cars and cars built on super capacitor technology is increasingly based on nanotechnology. The implications of nanotechnology in the form of rubber fillers, body frames made of light alloys, nanoelectronic components, nanocoatings of the interior and exterior of cars, self-repairing materials against external pressure, nanotextiles for interiors, and nanosensors are some of the nanotechnological-based implications of the automotive industry [ 96 ]. Owing to these properties, nanotechnology ventures are rapidly progressing in the automobile industry. It is expected that, soon, the automobile industry will commercialize nanotechnological perspectives on their branding strategies.

2.10. Nanotechnology, Healthcare, and Medical Industry

The genesis of nanomedicine simply cannot be ignored when we talk about the large fields of biological sciences, biotechnology, and medicine. Nanotechnology is already making its way beyond the imagination in the broader vision of nanobiotechnology. The quality of human life is continuously improved by the successful applications of nanotechnology in medicine, and resultantly, the entire new field of nanomedicine has come to the surface, which has allowed scientists to create upgraded versions of diagnostics, treatment, screening, sequencing, disease prevention, and proactive actions for healthcare [ 97 ]. These practices may also involve drug manufacturing, designing, conjugation, and efficient delivery options with advances in nano-based genomics, tissue engineering, and gene therapy. With this, it could be predicted that soon, nanomedicine will be the foremost research interest for the coming generation of biologists to study the useful impacts and risks that might be associated with them [ 98 ]. As illustrated in Figure 2 , we summarized the applications of nanotechnology in different subfields of the medical industry.

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Nanotechnology applications in medical industry. Nanotechnology has a broad range of applications in various diagnostics and treatments using nanorobotics and drug delivery systems.

In various medical procedures, scientists are exploring the potential benefits of nanotechnology. In the field of medical tools, various robotic characters have been applied which have their origins in nano-scale computers, such as diagnostic surfaces, sensor technologies, and sample purification kits [ 99 ]. Similarly, some modifications are being accepted in diagnostics with the development of devices that are capable of working, responding, and modifying within the human body with the sole purpose of early diagnosis and treatment. Regenerative medicine has led to nanomanufacturing applications in addition to cell therapy and tissue engineering [ 100 ]. Similarly, some latest technologies in the form of ‘lab-on-a-chip’, as elaborated upon earlier, are being introduced with large implications in different fields such as nanomedicine, diagnostics, dentistry, and cosmetics industries [ 101 ]. Some updated nanotechnology applications in genomics and proteomics fields have developed molecular insights into antimicrobial diseases. Moreover, medicine, programming, nanoengineering, and biotechnology are being merged to create applications such as surgical nanorobotics, nanobioelectrics, and drug delivery methods [ 102 ]. All of these together help scientists and clinicians to better understand the pathophysiology of diseases and to bring about better treatment solutions in the future.

Specifically, the field of nanocomputers and linked devices help to control activation responses and their rates in mechanical procedures [ 2 ]. Through these mechanical devices, specific actions of medical and dental procedures are executed accurately. Moreover, programmed nanomachines and nanorobots allow medical practitioners to carry out medical procedures precisely at even sub-cellular levels [ 4 ]. In diagnostics fields, the use of such nanodevices is expanding rapidly, which allows predictions to be made about disease etiology and helps to regulate treatment options [ 103 ]. The use of in vitro diagnosis allows increased efficiency in disease apprehension. Meanwhile, in in vivo diagnoses, such devices have been made which carry out the screening of diseased states and respond to any kind of toxicities or carcinogenic or pathological irregularities that the body faces [ 104 ].

Similarly, the field of regenerative medicine is employing nanomaterials in various medical procedures such as cell therapy, tissue engineering, and gene sequencing for the greater outlook of treatment and reparation of cells, tissues, and organs. Nanoassemblies have been recorded in research for applications in powerful tissue regeneration technologies with properties of cell adhesion, migration, and cellular differentiation [ 102 ]. Additionally, nanotechnology is being applied in antimicrobial (antibacterial and antiviral) fields. The microscopic abilities of these pathogens are determined through nano-scale technologies [ 100 ]. Greek medicinal practices have long been using metals to cure pathogenic diseases, but the field of nanotechnology has presented a new method to improve such traditional medical practices; for example, nanosized silver nanomaterials are being used to cure burn wounds owing to the easy penetration of nanomaterials at the cellular level [ 102 , 105 ].

In the field of bioinformatics and computational biology, genomic and proteomic technologies are elucidating molecular insights into disease management [ 106 ]. The scope of targeted and personalized therapies related to pathogenic and pathophysiological diseases have greatly provided spaces for nanotechnological innovative technologies [ 107 , 108 ]. They also incorporate the benefits of cost-effectiveness and time saving [ 109 ]. Similarly, nanosensors and nanomicrobivores are utilized for military purposes such as the detection of airborne chemical agents which could cause serious toxic outcomes otherwise [ 102 ]. Some nanosensors also serve a purpose similar to phagocytes to clear toxic pathogens from the bloodstream without causing septic shock conditions, especially due to the inhalation of prohibited drugs and banned substances [ 100 , 105 , 110 ]. These technologies are also used for dose specifications and to neutralize overdosing incidences [ 110 ] Nano-scale molecules work as anticancer and antiviral nucleoside analogs with or without other adjuvants [ 21 ].

Another application of nanotechnology in the medical industry is in bone regeneration technology. Scientists are working on bone graft technology for bone reformation and muscular re-structuring [ 111 , 112 ]. Principle investigations of biomineralization, collagen mimic coatings, collagen fibers, and artificial muscles and joints are being conducted to revolutionize the field of osteology and bone tissue engineering [ 113 , 114 ]. Similarly, drug delivery technologies are excessively considering nanoscaling options to improve drug delivery stability and pharmacodynamic and pharmacokinetic profiles at a large scale [ 110 ]. The use of nanorobots is an important step that allows drugs to travel across the circulatory system and deliver drug entities to specifically targeted sites [ 99 , 115 ]. Scientists are even working on nanorobots-based wireless intracellular and intra-nucleolar nano-scale surgeries for multiple malignancies, which otherwise remain incurable [ 102 ]. These nanorobotics can work at such a minute level that they can even cut a single neuronic dendrite without causing harm to complex neuronal networks [ 116 ].

Another important application of nanotechnology in the medical field is oncology. Nanotechnology is providing a good opportunity for researchers to develop such nanoagents, fluorescent materials, molecular diagnostics kits, and specific targeted drugs that may help to diagnose and cure carcinogenesis [ 104 ]. Scientists are trying various protocols of adjoining already-available drugs with nanoparticulate conjugation to enhance drug specificity and targeting in organs [ 104 , 107 , 117 ]. Nanomedicine acts as the carrier of hundreds of specific anticancerous molecules that could be projected at tumor sites; moreover, the tumor imaging and immunotherapy approaches linked with nanomedicine are also a potential field of interest when it comes to cancer treatment management [ 112 , 117 ]. A focus is also being drawn toward lessening the impact of chemotherapeutic drugs by increasing their tumor-targeting efficiency and improving their pharmacokinetic and pharmacodynamic properties [ 112 ]. Similarly, heat-induced ablation treatment against cancer cells alongside gene therapy protocols is also being coupled with nanorobotics [ 99 , 118 ]. Anticancerous drugs may utilize the Enhanced Permeation and Retention Effect (EPR effect) by applications of nano assemblies such as liposomes, albumin nanospheres, micelles, and gold nanoparticles, which confirms effective treatment strategies against cancer [ 119 ]. Such advances in nanomedicine will bring about a more calculated, outlined, and technically programmed field of nanomedicine through association and cooperation between physicians, clinicians, researchers, and technologies.

2.10.1. Nanoindustry and Dentistry

Nanodentistry is yet another subfield of nanomedicine that involves broad-scale applications of nanotechnology ranging from diagnosis, prevention, cure, prognosis, and treatment options for dental care [ 120 ]. Some important applications in oral nanotechnology include dentition denaturalization, hypersensitivity cure, orthodontic realignment problems, and modernized enameling options for the maintenance of oral health [ 2 , 121 ]. Similarly, mechanical dentifrobots work to sensitize nerve impulse traffic at the core of a tooth in real-time calculation and hence could regulate tooth tissue penetration and maintenance for normal functioning [ 122 ]. The functioning is coupled with programmed nanocomputers to execute an action from external stimuli via connection with localized internal nerve stimuli. Similarly, there are other broad-range applications of nanotechnology in tooth repair, hypersensitivity treatment, tooth repositioning, and denaturalization technologies [ 4 , 118 , 120 , 121 ]. Some of the applications of nanotechnology in the field of dentistry are elaborated upon in Figure 3 .

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Nanotechnology applications in field of dentistry. Nanotechnology can be largely used in dentistry to repair and treat dental issues.

2.10.2. Nanotechnology and Cosmetics Industry

The cosmetics industry, as part of the greater healthcare industry, is continuously evolving. Nanotechnology-based renovations are progressively incorporated into cosmetics industries as well. Products are designed with novel formulations, therapeutic benefits, and aesthetic output [ 123 ]. The nanocosmetics industry employs the usage of lipid nanocarrier systems, polymeric or metallic nanoparticles, nanocapsules, nanosponges, nanoemulsions, nanogels, liposomes, aquasomes, niosomes, dendrimers, and fullerenes, etc., among other such nanoparticles [ 101 ]. These nanomaterials bring about specific characteristics such as drug delivery, enhanced absorption, improved esthetic value, and enhanced shelf life. The benefits of nanotechnology are greatly captured in the improvement of skin, hair, nail, lip, and dental care products, and those associated with hygienic concerns. Changes to the skin barrier have been largely curtailed owing to the function of the nano scale of materials. The nanosize of active ingredients allows them to easily permeate skin barriers and generate the required dermal effect [ 124 ].

More profoundly, nanomaterials’ application is encouraged in the production of sun-protective cosmetics products such as sunblock lotions and creams. The main ingredient used is the rational combination of cinnamates (derived from carnauba wax) and titanium dioxide nanosuspensions which provide sun-protective effects in cosmetics products [ 125 ]. Similarly, nanoparticle suspensions are being applied in nanostructured lipid carriers (NLCs) for dermal and pharmaceutical applications [ 126 ]. They exhibit the properties of controlled drug-carrying and realizing properties, along with direct drug targeting, occlusion, and increased penetration and absorption to the skin surface. Moreover, these carrier nanoemulsions exhibit excellent tolerability to intense environmental and body conditions [ 127 ]. Moreover, these lipid nanocarriers have been researched and declared safe for potential cosmetic and pharmaceutical applications. However, more research is still required to assess the risk/benefit ratio of their excessive application [ 128 ].

2.11. Nanotechnology Industries and Environment

The environment, society, and technology are becoming excessively linked under a common slogan of sustainable development. Nanotechnology plays a key role in the 21st century to modify the technical and experimental outlook of various industries. Environmental applications cannot stand still against revolutionary applications of nanotechnology. Since the environment has much to do with the physical and chemical world around a living being, the nano scale of products greatly changes and affects environmental sustainability [ 129 ]. The subsequent introduction of nanomaterials in chemistry, physics, biotechnology, computer science, and space, food, and chemical industries, in general, directly impacts environmental sciences.

With regard to environmental applications, the remarkable research and applications of nanotechnology are increasing in the processing of raw materials, product manufacturing, contaminate treatment, soil and wastewater treatment, energy storage, and hazardous waste management [ 130 ]. In developed nations, it is now widely suggested that nanotechnology could play an effective role in tackling environmental issues. In fact, the application of nanotechnology could be implemented for water and cell cleaning technologies, drinking safety measures, and the detoxification of contaminants and pollutants from the environment such as heavy metals, organochlorine pesticides, and solvents, etc., which may involve reprocessing although nanofiltration. Moreover, the efficiency and durability of materials can be increased with mechanical stress and weathering phenomena. Similarly, the use of nanocage-based emulsions is being used for optical imaging techniques [ 131 ].

In short, the literature provides immense relevance to how nanotechnology is proving itself through groundbreaking innovative technologies in environmental sciences. The focus, for now, is kept on remediation technologies with prime attention on water treatment, since water scarcity is being faced worldwide and is becoming critical with time. There is a need for the scientific community to actively conduct research on comprehending the properties of nanomaterials for their high surface area, related chemical properties, high mobility, and unique mechanical and magnetic properties which could be used for to achieve a sustainable environment [ 132 ].

2.12. Nanotechnology—Oil and Gas Industry

The oil and gas industry makes up a big part of the fossil industry, which is slowly depleting with the rising consumption. Although nanotechnology has been successfully applied to the fields of construction, medicine, and computer science, its application in the oil and gas industry is still limited, especially in exploration and production technologies [ 133 ]. The major issue in this industry is to improve oil recovery and the further exploitation of alternative energy sources. This is because the cost of oil production and further purification is immense compared to crude oil prices. Nanotechnologists believe that they could overcome the technological barriers to developing such nanomaterials that would help in curtailing these problems.

Governments are putting millions of dollars into the exploration, drilling, production, refining, wastewater treatment, and transport of crude oil and gas. Nanotechnology can provide assistance in the precise measurement of reservoir conditions. Similarly, nanofluids have been proven to exhibit better performance in oil production industries. Nanocatalyses enhance the separation processing of oil, water, and gases, thus bringing an efficient impurity removal process to the oil and gas industry. Nanofabrication and nanomembrane technologies are excessively being utilized for the separation and purification of fossil materials [ 134 ]. Finally, functional and modified nanomaterials can produce smart, cost-effective, and durable equipment for the processing and manufacturing of oil and gas. In short, there is immense ground for the improvement of the fossil fuel industry if nanotechnology could be correctly directed in this industry [ 135 ].

2.13. Nanotechnology and Renewable Energy (Solar) Industry

Renewable energy sources are the solutions to many environmental problems in today’s world. This makes the renewable energy industry a major part of the environmental industry. Subsequently, nanotechnology needs to be considered in the energy affairs of the world. Nanotechnologies are increasingly applied in solar, hydrogen, biomass, geothermal, and tidal wave energy production. Although, scientists are convinced that much more needs to be discovered before enhancing the benefits of coupled nanotechnology and renewable energy [ 136 ].

Nanotechnology has procured its application way down the road of renewable energy sources. Solar collectors have been specifically given much importance since their usage is encouraged throughout the world, and with events of intense solar radiation, the production and dependence of solar energy will be helpful for fulfilling future energy needs. Research data are available regarding the theoretical, numerical, and experimental approaches adopted for upgrading solar collectors with the employment of nanotechnologies [ 137 ].

These applications include the nanoengineering of flat solar plates, direct absorption plates, parabolic troughs, and wavy plates and heat pipes. In most of these instruments and solar collection devices, the use of nanofluids is becoming common and plays a crucial role in increasing the working efficiency of these devices. A gap, however, exists concerning the usage of nanomaterials in the useful manufacturing design of solar panels and their associated possible efficiencies which could be brought to the solar panel industry. Moreover, work needs to be done regarding the cost-effectiveness and efficiency analyses of traditional and nanotechnology-based solar devices so that appropriate measures could be adopted for the future generation of nanosolar collectors [ 138 ].

2.14. Nanotechnology and Wood Industry

The wood industry is one of the main economic drivers in various countries where forest growth is immense and heavy industrial setups rely on manufacturing and selling wood-based products [ 139 ]. However, the rising environmental concerns against deforestation are a major cause for researchers to think about a method for the sustainable usage of wood products. Hence, nanotechnology has set its foot in the wood industry in various applications such as the production of biodegradable materials in the paper and pulp industry, timber and furniture industry, wood preservatives, wood composites, and applications in lignocellulosic-based materials [ 140 ]. Resultantly, new products are introduced into the market with enhanced performance (stronger yet lighter products), increased economic potential, and reduced environmental impact.

One method of nano-based application in the wood industry is the derivation of nanomaterials directly from the forest, which is now called nanocellulose material, known broadly for its sustainable characteristics [ 141 ]. This factor has pushed the wood industry to convert cellulosic material to nanocellulose with increased strength, low weight, and increased electromagnetic response along with a larger surface area [ 142 ]. These characteristics are then further used as reinforcing agents in different subcategories of wood-based industries, including substrate, stabilizer, electronics, batteries, sensor technologies, food, medicine, and cosmetics industries [ 143 ]. Moreover, functional characteristics such as the durability, UV absorption, fire resistance, and decreased water absorption of wood-based biodegradable products are also being improved with the application of nanomaterials such as nanozinc oxide or nanotitanium oxide [ 144 ]. Similarly, wood biodegradable properties are reduced through the application of nanoencapsulated preservatives to improve the impregnation of wood with the increasing penetration of applied chemicals and a reduced leaching effect.

Cellulosic nanomaterials exhibit nanofibrillar structures which can be made multifunctional for application in construction, furniture, food, pharmaceuticals, and other wood-based industries [ 145 ]. Research is emerging in which promising results are predicted in different industries in which nanofibers, nanofillers, nanoemulsions, nanocomposites, and nano-scaled chemical materials are used to increase the potential advantages of manufactured wood products [ 146 ]. The outstanding properties of nanocellulusice materials have largely curtailed the environmental concerns in the wood industry in the form of their potential renewable characteristics, self-assembling properties, and well-defined architecture. However, there are a few challenges related to such industries, such as cost/benefit analyses, a lack of compatibility and acceptability from the public owing to a lack of proper commercialization, and a persistent knowledge gap in some places [ 145 ]. Therefore, more effort is required to increase the applications and acceptability of nano-based wood products in the market worldwide.

2.15. Nanotechnology and Chemical Industries

Nanotechnology can be easily applied to various chemical compositions such as polymeric substances; this application can bring about structural and functional changes in those chemical materials and can address various industrial applications including medicine, physics, electronics, chemical, and material industries, among others [ 76 , 132 , 138 ]. One such industrial application is in electricity production, in which different nanomaterials driven from silver, golden, and organic sources could be utilized to make the overall production process cheaper and effective [ 147 ]. Another effective application is in the coatings and textile industry, which has already been discussed briefly. In these industries, enzymatic catalysis in combination with nanotechnology accelerates reaction times, saving money and bringing about high-quality final products. Similarly, the water cleaning industry can utilize the benefits of nanomaterials in the form of silver and magnetic nanoparticles to create strong forces of attraction that easily separate heavy material from untreated water [ 148 ]. Similarly, there is a wide range of chemicals that can be potentially upgraded, although the nano scale for application in biomedical industries is discussed under the heading of nanotechnology and medicine.

Another major application of nanotechnology in the chemical industry includes the surfactant industry, which is used for cleaning paper, inks, agrochemicals, drugs, pharmaceuticals, and some food products [ 149 ]. The traditional surfactant application was of great environmental and health concern, but with the newer and improved manufacturing and nanoscaling of surfactants, environmentally friendly applications have been made possible. These newer types may include biosurfactants obtained via the process of fermentation and bio-based surfactants produced through organic manufacturing. More research is required to establish the risks and side effects of these nanochemical agents [ 3 ].

3. Closing Remarks

Nanotechnology, within a short period, has taken over all disciplinary fields of science, whether it is physics, biology, or chemistry. Now, it is predicted to enormously impact manufacturing technology owing to the evidential and proven benefits of micro scaling. Every field of industry, such as computing, information technology, engineering, medicine, agriculture, and food, among others, is now originating an entire new field in association with nanotechnology. These industries are widely known as nanocomputer, nanoengineering, nanoinformatics, nanobiotechnology, nanomedicine, nanoagriculture, and nanofood industries. The most brilliant discoveries are being made in nanomedicine, while the most cost-effective and vibrant technologies are being introduced in materials and mechanical sciences.

The very purpose of nanotechnology, in layman’s terms, is to ease out the manufacturing process and improve the quality of end products and processes. In this regard, it is easy and predictable that it is not difficult for nanotechnology to slowly take out most of the manufacturing process for industrial improvement. With every coming year, more high-tech and more effective-looking nanotechnologies are being introduced. This is smoothing out the basis of a whole new era of nanomindustries. However, the constructive need is to expand the research basis of nanoapplications to entail the rigorous possible pros of this technology and simultaneously figure out a method to deal with the cons of the said technology.

The miniaturization of computer devices has continued for many years and is now being processed at the nanometer scale. However, a gap remains to explore further options for the nanoscaling of computers and complex electronic devices, including computer processors. Moreover, there is an immense need to enable the controlled production and usage of such nanotechnologies in the real world, because if not, they could threaten the world of technology. Scientists should keep on working on producing nanoelectronic devices with more power and energy efficiency. This is important in order to extract the maximum benefits from the hands of nanotechnology and computer sciences [ 5 ].

Under the influence of nanotechnology, food bioprocessing is showing improvement, as proven by several scientific types of research and industrial applications in food chain and agricultural fields. Moreover, the aspect of sustainability is being introduced to convert the environment, food chains, processing industries, and production methods to save some resources for future generations. The usage of precision farming technologies based upon nanoengineering, modern nano-scale fertilizers, and pesticides are of great importance in this regard. Moreover, a combined nanotechnological aspect is also being successfully applied to the food industry, affecting every dimension of packing, sensing, storage, manufacturing, and antimicrobial applications. It is pertinent to say that although the applications of nanotechnology in the food, agriculture, winemaking, poultry, and associated packaging industries are immense, the need is to accurately conduct the risk assessment and potential toxicity of nanomaterials to avoid any damage to the commercial food chains and animal husbandry practices [ 63 ].

The exposure of the nano-based building industry is immense for civil and mechanical engineers; now, we need to use these technologies to actually bring about changes in those countries in which the population is immense, construction material is depleting, and environmental sustainability problems are hovering upon the state. By carefully assessing the sustainability potential of these nanomaterials, their environmental, hazardous, and health risks could be controlled, and they could likely be removed from the construction and automobile industry all over the world with sincere scientific and technical rigor [ 150 ]. It is expected that soon, the construction and automobile industry will commercialize the nanotechnological perspectives alongside sustainability features in their branding strategies. These nano-scale materials could allow the lifecycle management of automotive and construction industries with the provision of sustainable, safe, comfortable, cost-effective, and more eco-friendly automobiles [ 32 ]. The need is to explore the unacknowledged and untapped potential of nanotechnology applications in these industry industries.

Similarly, nanotechnology-based applications in consumer products such as textile and esthetics industries are immense and impressive. Professional development involves the application of nanotechnology-based UV-protective coatings in clothes which are of utmost need with climatic changes [ 73 ]. The application of nanotechnology overcomes the limitations of conventional production methods and makes the process more suitable and green-technology-based. These properties have allowed the textile companies to effectively apply nanotechnology for the manufacture of better products [ 90 ]. With greater consumer acceptability and market demand, millions are spent in the cosmetic industry to enable the further usage of nanotechnology. Researchers are hopeful that nanotechnology would be used to further upgrade the cosmetics industry in the near future [ 123 ].

Furthermore, the breakthrough applications of nanomedicine are not hidden from the scientific community. If nanomedicine is accepted worldwide in the coming years, then the hope is that the domain of diagnosis and treatment will become more customized, personalized, and genetically targeted for individual patients. Treatment options will ultimately become excessive in number and more successful in accomplishment. However, these assumptions will stay a dream if the research remains limited to scientific understanding.

The real outcome will be the application of this research into the experimental domain and clinical practices to make them more productive and beneficial for the medical industry. For this cause, a combined effort of technical ability, professional skills, research, experimentation, and the cooperation of clinicians, physicians, researchers, and technology is imperative. However, despite all functional beneficial characteristics, work needs to be done and more exploration is required to learn more about nanotechnology and its potential in different industries, especially nanomedicine, and to take into account and curtail the risks and harms attached to the said domain of science.

Additionally, climatic conditions, as mentioned before, along with fossil fuel depletion, have pushed scientists to realize a low-energy-consuming and more productive technological renovation in the form of nanoengineered materials [ 48 ]. Now, they are employing nanomaterials to save energy and harvest the maximum remaining natural resources. There is immense ground for the improvement of the fossil fuel industry if nanotechnology could be correctly directed in this industry [ 135 ]. The beneficial applications within the solar industry, gas and oil industry, and conversion fields require comparative cost-effectiveness and efficiency analyses of traditional and nano-based technologies so that appropriate measures could be adopted for the future generation of nano-based products in said industries [ 138 ].

As every new technology is used in industries, linked social, ethical, environmental, and human safety issues arise to halt the pace of progress. These issues need to be addressed and analyzed along with improving nanotechnology so that this technology easily incorporates into different industries without creating social, moral, and ethical concerns. Wide-scale collaboration is needed among technologists, engineers, biologists, and industrials for a prospective future associated with the wide-scale application of nanotechnology in diversified fields.

4. Conclusions

Highly cost-effective and vibrant nanotechnologies are being introduced in materials and mechanical sciences. A comprehensive overview of such technologies has been covered in this study. This review will help researchers and professionals from different fields to delve deeper into the applications of nanotechnology in their particular areas of interest. Indeed, the applications of nanotechnology are immense, yet the risks attached to unlimited applications remain unclear and unpronounced. Thus, more work needs to be linked and carefully ascertained so that further solutions can be determined in the realm of nanotoxicology. Moreover, it is recommended that researchers, technicians, and industrialists should cooperate at the field and educational level to explore options and usefully exploit nanotechnology in field experiments. Additionally, more developments should be made and carefully assessed at the nano scale for a future world, so that we are aware of this massive technology. The magnificent applications of nanotechnology in the industrial world makes one think that soon, the offerings of nanotechnology will be incorporated into every possible industry. However, there is a need to take precautionary measures to be aware of and educate ourselves about the environmental and pollution concerns alongside health-related harms to living things that may arise due to the deviant use of nanotechnology. This is important because the aspect of sustainability is being increasingly considered throughout the world. So, by coupling the aspect of sustainability with nanotechnology, a prosperous future of nanotechnology can be guaranteed.

Funding Statement

K.M.’s work is supported by United Arab Emirates University-UPAR-Grant#G3458, SURE plus Grant#3908 and SDG research programme grant#4065.

Author Contributions

Conceptualization, Y.W. methodology, S.M. validation, S.M., K.M. and Y.W. formal analysis, S.M., K.M. and Y.W. investigation, S.M., K.M. and Y.W. resources, K.M. and Y.W. data curation, S.M., K.M. and Y.W. writing—original draft preparation, S.M. writing—review and editing, S.M., K.M. and Y.W. supervision, Y.W. project administration, K.M. and Y.W. funding acquisition, Y.W. and K.M. All authors have read and agreed to the published version of the manuscript.

Institutional Review Board Statement

Informed consent statement, data availability statement, conflicts of interest.

The authors declare no conflict of interest.

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Genomics Sequencing Center ensemble supports top-performing research

Jenise L. Jacques

10 Apr 2024

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The Genomics Sequencing Center team members. Photo by Clark DeHart for Virginia Tech.

Imagine if there were Oscars given out in the world of academia, specifically for those unsung heroes behind the scenes that advance the progress of research.

In this scenario, the winning name in the envelope could be the Genomics Sequencing Center for best supporting role in research by a group.

As part of the Fralin Life Sciences Institute’s core research facilities, the Genomics Sequencing Center is a full-service sequencing center that provides rapid and cost effective genomic data collection. Located in Steger Hall, the center offers a range of quality control equipment to determine the integrity and concentration of user samples.

“We are here to support our faculty’s research goals,” said Megan Naff, a laboratory manager who has worked for the last 14 years in the center. During this time, Naff has witnessed sweeping changes in technology.

“We are producing exponentially more data in a shorter amount of time,” Naff said. “We are also seeing the applications of sequencing expanding into numerous other disciplines.”

Currently, the Genomics Sequencing Center’s application of different sequencing technologies span a variety of departments, disciplines, and applications, including human health, plant science, animal health, entomology, and engineering. And it maintains an eye for expanding into new disciplines.

As a small but mighty group, the team is made up of four highly skilled molecular biologists who work with the latest in next generation sequencing technology.

“We specialize in customizing projects to meet the needs of the investigators on campus,” Naff said.

As a director may do on a set, Naff starts each day with a morning meeting to discuss the current projects and how team members can best work together, while also sticking to their own scripts.

Your browser does not support iframes. Link to iframe content: https://www.youtube.com/embed/yVpgNC6OEkc?si=lTXqV1s4Gks0oQhk

Meet the cast

One of the three services offered by the center is next generation sequencing led by Jenny Jenrette and Riley Leathem. Together, they process DNA and RNA samples to generate whole genome DNA, transcriptome, and amplicon sequences, the latter being a highly targeted approach that enables researchers to analyze genetic variation in specific genomic regions.

Their sequencing handiwork was instrumental in advancing graduate student Blake Caldwell’s discovery of a DNA shift in the innate immune memory of cells, which may aid in the fight against one of humans’ most deadly foes — sepsis. Caldwell’s breakthrough was recently published in the Cell Reports journal .

As an undergraduate student, Leathem started working for the center part time and was hired full time after graduating in May 2023. She said she enjoys working with researchers to provide a custom experience and achieve the best results.

“Because we personalize projects, we are able to work very closely with each customer,” Leathem said. “This offers an opportunity for graduate students to ask questions and receive guidance.”

This interface also affords graduate students the opportunity to gain further insight into their specifical project and goals. Jenrette said this audience is where their work has the greatest impact with respect to training students on everything from DNA and RNA extraction methods to quality control analysis of input and output.

While their name may not be in lights or on the marquee, the center’s staff takes great pride in their contributions to advancing research. As one recent example, Jenrette has worked with Emmanuel Frimpong and Eric Hallerman in the Department of Fish and Wildlife Conservation to sequence the gut contents of three local minnow species.

Lights, camera, analysis

Two other services provided by the Genomics Sequencing Center are Sanger sequencing and quality control services, both of which are under the direction of Kris Lee. Lee has worked in the center for 20 years and at Virginia Tech for 36 years.

Sanger sequencing, in its basic form, is a method that yields information about the identity and order of the four nucleotide bases in a segment of DNA. It is typically used for smaller scale projects and for validation of NextGeneration Sequencing results.

As far as daily output, Lee receives, runs, and processes samples received by both Virginia Tech investigators and external entities. After the Sanger samples have been set up, she processes any requested RNA or DNA quality control assays, which is the process of analyzing a substance to determine its composition or quality.

During fiscal year 2023, close to 15,500 samples were run, supporting 110 Virginia Tech investigators and external customers.

Lee knows that as a cost-recovery lab, it is difficult for the Genomics Sequencing Center to compete with commercial providers who also offer Sanger sequencing services.

“I believe that offering better personal service is important in keeping our research happy,” Lee said.

More information can be found on the Genomics Sequencing Center website.

Lindsey Haugh

Blacksburg, Va.
College of Natural Resources and Environment
Fish and Wildlife Conservation
Fralin Life Sciences Institute
Graduate Research
One Health Frontier
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