research topics for science teachers

Research Topics & Ideas: Education

170+ Research Ideas To Fast-Track Your Project

If you’re just starting out exploring education-related topics for your dissertation, thesis or research project, you’ve come to the right place. In this post, we’ll help kickstart your research topic ideation process by providing a hearty list of research topics and ideas , including examples from actual dissertations and theses..

PS – This is just the start…

We know it’s exciting to run through a list of research topics, but please keep in mind that this list is just a starting point . To develop a suitable education-related research topic, you’ll need to identify a clear and convincing research gap , and a viable plan of action to fill that gap.

If this sounds foreign to you, check out our free research topic webinar that explores how to find and refine a high-quality research topic, from scratch. Alternatively, if you’d like hands-on help, consider our 1-on-1 coaching service .

Overview: Education Research Topics

• How to find a research topic (video)
• List of 50+ education-related research topics/ideas
• List of 120+ level-specific research topics 
• Examples of actual dissertation topics in education
• Tips to fast-track your topic ideation (video)
• Free Webinar : Topic Ideation 101
• Where to get extra help

Education-Related Research Topics & Ideas

Below you’ll find a list of education-related research topics and idea kickstarters. These are fairly broad and flexible to various contexts, so keep in mind that you will need to refine them a little. Nevertheless, they should inspire some ideas for your project.

• The impact of school funding on student achievement
• The effects of social and emotional learning on student well-being
• The effects of parental involvement on student behaviour
• The impact of teacher training on student learning
• The impact of classroom design on student learning
• The impact of poverty on education
• The use of student data to inform instruction
• The role of parental involvement in education
• The effects of mindfulness practices in the classroom
• The use of technology in the classroom
• The role of critical thinking in education
• The use of formative and summative assessments in the classroom
• The use of differentiated instruction in the classroom
• The use of gamification in education
• The effects of teacher burnout on student learning
• The impact of school leadership on student achievement
• The effects of teacher diversity on student outcomes
• The role of teacher collaboration in improving student outcomes
• The implementation of blended and online learning
• The effects of teacher accountability on student achievement
• The effects of standardized testing on student learning
• The effects of classroom management on student behaviour
• The effects of school culture on student achievement
• The use of student-centred learning in the classroom
• The impact of teacher-student relationships on student outcomes
• The achievement gap in minority and low-income students
• The use of culturally responsive teaching in the classroom
• The impact of teacher professional development on student learning
• The use of project-based learning in the classroom
• The effects of teacher expectations on student achievement
• The use of adaptive learning technology in the classroom
• The impact of teacher turnover on student learning
• The effects of teacher recruitment and retention on student learning
• The impact of early childhood education on later academic success
• The impact of parental involvement on student engagement
• The use of positive reinforcement in education
• The impact of school climate on student engagement
• The role of STEM education in preparing students for the workforce
• The effects of school choice on student achievement
• The use of technology in the form of online tutoring

Level-Specific Research Topics

Looking for research topics for a specific level of education? We’ve got you covered. Below you can find research topic ideas for primary, secondary and tertiary-level education contexts. Click the relevant level to view the respective list.

Research Topics: Pick An Education Level

Primary education.

• Investigating the effects of peer tutoring on academic achievement in primary school
• Exploring the benefits of mindfulness practices in primary school classrooms
• Examining the effects of different teaching strategies on primary school students’ problem-solving skills
• The use of storytelling as a teaching strategy in primary school literacy instruction
• The role of cultural diversity in promoting tolerance and understanding in primary schools
• The impact of character education programs on moral development in primary school students
• Investigating the use of technology in enhancing primary school mathematics education
• The impact of inclusive curriculum on promoting equity and diversity in primary schools
• The impact of outdoor education programs on environmental awareness in primary school students
• The influence of school climate on student motivation and engagement in primary schools
• Investigating the effects of early literacy interventions on reading comprehension in primary school students
• The impact of parental involvement in school decision-making processes on student achievement in primary schools
• Exploring the benefits of inclusive education for students with special needs in primary schools
• Investigating the effects of teacher-student feedback on academic motivation in primary schools
• The role of technology in developing digital literacy skills in primary school students
• Effective strategies for fostering a growth mindset in primary school students
• Investigating the role of parental support in reducing academic stress in primary school children
• The role of arts education in fostering creativity and self-expression in primary school students
• Examining the effects of early childhood education programs on primary school readiness
• Examining the effects of homework on primary school students’ academic performance
• The role of formative assessment in improving learning outcomes in primary school classrooms
• The impact of teacher-student relationships on academic outcomes in primary school
• Investigating the effects of classroom environment on student behavior and learning outcomes in primary schools
• Investigating the role of creativity and imagination in primary school curriculum
• The impact of nutrition and healthy eating programs on academic performance in primary schools
• The impact of social-emotional learning programs on primary school students’ well-being and academic performance
• The role of parental involvement in academic achievement of primary school children
• Examining the effects of classroom management strategies on student behavior in primary school
• The role of school leadership in creating a positive school climate Exploring the benefits of bilingual education in primary schools
• The effectiveness of project-based learning in developing critical thinking skills in primary school students
• The role of inquiry-based learning in fostering curiosity and critical thinking in primary school students
• The effects of class size on student engagement and achievement in primary schools
• Investigating the effects of recess and physical activity breaks on attention and learning in primary school
• Exploring the benefits of outdoor play in developing gross motor skills in primary school children
• The effects of educational field trips on knowledge retention in primary school students
• Examining the effects of inclusive classroom practices on students’ attitudes towards diversity in primary schools
• The impact of parental involvement in homework on primary school students’ academic achievement
• Investigating the effectiveness of different assessment methods in primary school classrooms
• The influence of physical activity and exercise on cognitive development in primary school children
• Exploring the benefits of cooperative learning in promoting social skills in primary school students

Secondary Education

• Investigating the effects of school discipline policies on student behavior and academic success in secondary education
• The role of social media in enhancing communication and collaboration among secondary school students
• The impact of school leadership on teacher effectiveness and student outcomes in secondary schools
• Investigating the effects of technology integration on teaching and learning in secondary education
• Exploring the benefits of interdisciplinary instruction in promoting critical thinking skills in secondary schools
• The impact of arts education on creativity and self-expression in secondary school students
• The effectiveness of flipped classrooms in promoting student learning in secondary education
• The role of career guidance programs in preparing secondary school students for future employment
• Investigating the effects of student-centered learning approaches on student autonomy and academic success in secondary schools
• The impact of socio-economic factors on educational attainment in secondary education
• Investigating the impact of project-based learning on student engagement and academic achievement in secondary schools
• Investigating the effects of multicultural education on cultural understanding and tolerance in secondary schools
• The influence of standardized testing on teaching practices and student learning in secondary education
• Investigating the effects of classroom management strategies on student behavior and academic engagement in secondary education
• The influence of teacher professional development on instructional practices and student outcomes in secondary schools
• The role of extracurricular activities in promoting holistic development and well-roundedness in secondary school students
• Investigating the effects of blended learning models on student engagement and achievement in secondary education
• The role of physical education in promoting physical health and well-being among secondary school students
• Investigating the effects of gender on academic achievement and career aspirations in secondary education
• Exploring the benefits of multicultural literature in promoting cultural awareness and empathy among secondary school students
• The impact of school counseling services on student mental health and well-being in secondary schools
• Exploring the benefits of vocational education and training in preparing secondary school students for the workforce
• The role of digital literacy in preparing secondary school students for the digital age
• The influence of parental involvement on academic success and well-being of secondary school students
• The impact of social-emotional learning programs on secondary school students’ well-being and academic success
• The role of character education in fostering ethical and responsible behavior in secondary school students
• Examining the effects of digital citizenship education on responsible and ethical technology use among secondary school students
• The impact of parental involvement in school decision-making processes on student outcomes in secondary schools
• The role of educational technology in promoting personalized learning experiences in secondary schools
• The impact of inclusive education on the social and academic outcomes of students with disabilities in secondary schools
• The influence of parental support on academic motivation and achievement in secondary education
• The role of school climate in promoting positive behavior and well-being among secondary school students
• Examining the effects of peer mentoring programs on academic achievement and social-emotional development in secondary schools
• Examining the effects of teacher-student relationships on student motivation and achievement in secondary schools
• Exploring the benefits of service-learning programs in promoting civic engagement among secondary school students
• The impact of educational policies on educational equity and access in secondary education
• Examining the effects of homework on academic achievement and student well-being in secondary education
• Investigating the effects of different assessment methods on student performance in secondary schools
• Examining the effects of single-sex education on academic performance and gender stereotypes in secondary schools
• The role of mentoring programs in supporting the transition from secondary to post-secondary education

Tertiary Education

• The role of student support services in promoting academic success and well-being in higher education
• The impact of internationalization initiatives on students’ intercultural competence and global perspectives in tertiary education
• Investigating the effects of active learning classrooms and learning spaces on student engagement and learning outcomes in tertiary education
• Exploring the benefits of service-learning experiences in fostering civic engagement and social responsibility in higher education
• The influence of learning communities and collaborative learning environments on student academic and social integration in higher education
• Exploring the benefits of undergraduate research experiences in fostering critical thinking and scientific inquiry skills
• Investigating the effects of academic advising and mentoring on student retention and degree completion in higher education
• The role of student engagement and involvement in co-curricular activities on holistic student development in higher education
• The impact of multicultural education on fostering cultural competence and diversity appreciation in higher education
• The role of internships and work-integrated learning experiences in enhancing students’ employability and career outcomes
• Examining the effects of assessment and feedback practices on student learning and academic achievement in tertiary education
• The influence of faculty professional development on instructional practices and student outcomes in tertiary education
• The influence of faculty-student relationships on student success and well-being in tertiary education
• The impact of college transition programs on students’ academic and social adjustment to higher education
• The impact of online learning platforms on student learning outcomes in higher education
• The impact of financial aid and scholarships on access and persistence in higher education
• The influence of student leadership and involvement in extracurricular activities on personal development and campus engagement
• Exploring the benefits of competency-based education in developing job-specific skills in tertiary students
• Examining the effects of flipped classroom models on student learning and retention in higher education
• Exploring the benefits of online collaboration and virtual team projects in developing teamwork skills in tertiary students
• Investigating the effects of diversity and inclusion initiatives on campus climate and student experiences in tertiary education
• The influence of study abroad programs on intercultural competence and global perspectives of college students
• Investigating the effects of peer mentoring and tutoring programs on student retention and academic performance in tertiary education
• Investigating the effectiveness of active learning strategies in promoting student engagement and achievement in tertiary education
• Investigating the effects of blended learning models and hybrid courses on student learning and satisfaction in higher education
• The role of digital literacy and information literacy skills in supporting student success in the digital age
• Investigating the effects of experiential learning opportunities on career readiness and employability of college students
• The impact of e-portfolios on student reflection, self-assessment, and showcasing of learning in higher education
• The role of technology in enhancing collaborative learning experiences in tertiary classrooms
• The impact of research opportunities on undergraduate student engagement and pursuit of advanced degrees
• Examining the effects of competency-based assessment on measuring student learning and achievement in tertiary education
• Examining the effects of interdisciplinary programs and courses on critical thinking and problem-solving skills in college students
• The role of inclusive education and accessibility in promoting equitable learning experiences for diverse student populations
• The role of career counseling and guidance in supporting students’ career decision-making in tertiary education
• The influence of faculty diversity and representation on student success and inclusive learning environments in higher education

Education-Related Dissertations & Theses

While the ideas we’ve presented above are a decent starting point for finding a research topic in education, they are fairly generic and non-specific. So, it helps to look at actual dissertations and theses in the education space to see how this all comes together in practice.

Below, we’ve included a selection of education-related research projects to help refine your thinking. These are actual dissertations and theses, written as part of Master’s and PhD-level programs, so they can provide some useful insight as to what a research topic looks like in practice.

• From Rural to Urban: Education Conditions of Migrant Children in China (Wang, 2019)
• Energy Renovation While Learning English: A Guidebook for Elementary ESL Teachers (Yang, 2019)
• A Reanalyses of Intercorrelational Matrices of Visual and Verbal Learners’ Abilities, Cognitive Styles, and Learning Preferences (Fox, 2020)
• A study of the elementary math program utilized by a mid-Missouri school district (Barabas, 2020)
• Instructor formative assessment practices in virtual learning environments : a posthumanist sociomaterial perspective (Burcks, 2019)
• Higher education students services: a qualitative study of two mid-size universities’ direct exchange programs (Kinde, 2020)
• Exploring editorial leadership : a qualitative study of scholastic journalism advisers teaching leadership in Missouri secondary schools (Lewis, 2020)
• Selling the virtual university: a multimodal discourse analysis of marketing for online learning (Ludwig, 2020)
• Advocacy and accountability in school counselling: assessing the use of data as related to professional self-efficacy (Matthews, 2020)
• The use of an application screening assessment as a predictor of teaching retention at a midwestern, K-12, public school district (Scarbrough, 2020)
• Core values driving sustained elite performance cultures (Beiner, 2020)
• Educative features of upper elementary Eureka math curriculum (Dwiggins, 2020)
• How female principals nurture adult learning opportunities in successful high schools with challenging student demographics (Woodward, 2020)
• The disproportionality of Black Males in Special Education: A Case Study Analysis of Educator Perceptions in a Southeastern Urban High School (McCrae, 2021)

As you can see, these research topics are a lot more focused than the generic topic ideas we presented earlier. So, in order for you to develop a high-quality research topic, you’ll need to get specific and laser-focused on a specific context with specific variables of interest.  In the video below, we explore some other important things you’ll need to consider when crafting your research topic.

Get 1-On-1 Help

If you’re still unsure about how to find a quality research topic within education, check out our Research Topic Kickstarter service, which is the perfect starting point for developing a unique, well-justified research topic.

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Recent Research in Science Teaching and Learning

• Sarah L. Eddy

*Address correspondence to: Sarah L. Eddy ( E-mail Address: [email protected] ).

Department of Biological Sciences, STEM Transformation Institute, Florida International University, Miami, FL 33199

Search for more papers by this author

The Current Insights feature is designed to introduce life science educators and researchers to current articles of interest in other social science and education journals. In this installment, I highlight three diverse research studies: one addresses the relationships between active learning and teaching evaluations; one presents an observation tool for documenting metacognition in the classroom; and the last explores things teachers can say to encourage students to employ scientific reasoning during class discussions.

STUDENT EVALUATIONS AND ACTIVE LEARNING

Henderson, C., Khan, R., & Dancy, M. (2018). Will my student evaluations decrease if I adopt an active learning instructional strategy? American Journal of Physics , 86 (12), 934–942. https://doi.org/10.1119/1.5065907

Student evaluations are widely used and are often the sole source for the evaluation of faculty teaching. As described in the Introduction, fear that one’s student evaluations may decrease is one of the oft-cited reasons for faculty not adopting active-learning techniques. Yet this phenomenon has not been studied on a large scale. Henderson and colleagues test the hypothesis that active learning lowers student evaluations in a population of physics and astronomy instructors who participated in a long-running faculty development workshop. Forty percent (40%) of new physics and astronomy faculty attended this workshop. Of the more than 1300 workshop participants, 431 responded to a follow-up survey. Participants were asked about their use of active-learning methods in their most recent quantitative physics class; whether their student evaluations were impacted by the use of active learning; and whether students complained about the inclusion of active learning. If a faculty member reported a change in student evaluations, he or she was given an opportunity to provide an explanation for that change.

The majority of respondents saw either an increase (48%) or no change in their student evaluations (32%). The subset of instructors who reported receiving lower teaching evaluations also reported substantially less time lecturing than instructors who reported better evaluations. This pattern seemed driven by people using interactive methods for more than 80% of a class period, as this population was more likely to report reduced evaluations. Student complaints followed a similar pattern, with an increase in complaints becoming the most common outcome for instructors using active methods more than 80% of class time.

The reasons shared by instructors for why their evaluations changed were varied. For those who reported their evaluations improving, more than 20% of the instructors thought this increase was due to each of the following: students believing they were learning more, students enjoying class more, students enjoying interacting with one another, or students enjoying using technology. For those who reported lower evaluations, 40% reported that the students felt that the instructor was not teaching. Interestingly, many of these instructors also confessed as part of this comment that they were not good at “selling” the active learning. They next most common explanation given for lower evaluations was that students did not like working during class time; they would rather be listeners.

The results of this study suggest that, for the majority of faculty, adopting active learning will not negatively impact student evaluations. The study also suggests that those instructors concerned about student evaluations could incorporate active-learning activities for as much as 80% of class time and still not be likely to see a negative impact on their evaluations. This could be useful information to share with departmental colleagues and anyone mentoring new faculty who are deciding how to teach. As always, though, some caution should be taken in applying these results in a new context. Specifically, the authors acknowledge that they did not account for what types of active learning instructors implemented. It may be that some methods are more accepted by students than others.

TEACHERS TALKING METACOGNITION

Zepeda, C. D., Hlutkowsky, C. O., Partika, A. C., & Nokes-­Malach, T. J. (2018, October 29). Identifying teachers’ supports of metacognition through classroom talk and its relation to growth in conceptual learning. Journal of Educational Psychology (advance online publication). https://doi.org/10.1037/edu0000300

Metacognition refers to one’s knowledge and awareness of one’s own thought processes. As reviewed in the Introduction, metacognition is considered highly desirable for students, because it has been linked to many positive outcomes in experimental and classroom studies, including achievement, transfer of knowledge from one context to another, and motivation. Although many studies have focused on the use of planned interventions for metacognition, few have looked at what teachers are saying and doing spontaneously in the classroom that might influence student metacognition.

Zepeda and colleagues developed an observation protocol to detect classroom talk directed toward metacognitive growth in middle school students in math classrooms. They identified both the metacognitive content of the talk and the delivery method by documenting four dimensions, each with three possible states: the type of metacognitive knowledge being promoted; the metacognitive skill being worked on; the manner in which the teacher delivered this content; and how specific the metacognitive skill is frame d (from specific to the question being worked on to a more global approach to problem solving). For example, a teacher might say, “Alright, so explain to us what you are doing right now.” This would be coded as personal knowledge, because the student is asked about his or her own process. The skill being worked on would be monitoring, (i.e., being aware of why they are doing what they are doing). The manner in which the teacher delivers the content would be directive, because the teacher is telling the student to do something. The framing could be domain general, because the prompt could be used with any type of problem. I am not going to go further into the individual states for each dimension due to space, but there are lengthy descriptions of them within the original paper.

The authors use this observation tool with one class session from 39 middle school math instructors. The classes were selected from a larger national data set of middle school classrooms. Every class included in this larger data set had math knowledge assessments. The current authors created a smaller data set that included instructors who had the most student growth on the math assessment over a year and a set of instructors who had the least growth after accounting for various student- and instructor-level factors. Each video was transcribed and each teacher statement was examined for metacognitive talk. Any instance of metacognitive talk was coded for the four dimensions in the observation tool.

Overall, there were very few metacognitive statements made by teachers (∼7% of teacher statements), but even with this low overall percentage, there were some interesting patterns. The odds of teachers engaging in metacognitive talk were 4.75 times greater during whole-class activities than during activities done individually by students. In addition, in high math growth classes, the odds of instructors engaging in metacognitive talk were 1.5 times higher than in low math growth classes.

The content of the metacognitive talk differed between these two class types as well. In terms of the knowledge dimension, teachers in the high math growth classes elicited more personal knowledge statements in which students shared their own understanding of what they were doing in class than teachers in the low math growth classes. The high math growth class also had more statements focused on the skills of monitoring and evaluating their own work. In terms of how the metacognitive content was delivered (manner), the high math growth class had more directive statements. Finally, the high math growth classes had more domain-general framing of the metacognitive statements.

This study demonstrates that classroom observations can be used to explore metacognition and that the same methods that work most effectively in interventions designed to promote metacognition may also work more informally during teach talk in class. Although the authors cannot rule out that teachers who are more effective in other ways are also more likely to engage in metacognitive talk, the results do suggest that certain ways and certain content of metacognitive talk is more effective than others.

BUILDING STUDENT’S SCIENTIFIC REASONING IN CONVERSATIONS

Grinath, A. S., & Southerland, S. A. (2018). Applying the ambitious science teaching framework in undergraduate biology: Responsive talk moves that support explanatory rigor. Science Education ,  103 (1), 92–122. https://doi.org/10.1002/sce.21484

Active learning is centered around the idea that it encourages students to engage in their own learning, often through conversations about course content. Yet the quality of these conversations can vary. In this paper, Grinath and Southerland explore how instructors can influence in-class student discussions.

To explore the question of facilitation effects without confounding variables of differences between lessons, content, and students, the authors chose to work with 26 teaching assistants (TAs) instructing sections of the same introductory biology lab for nonmajors at the same university. This controlled both the content being presented to students across instructors and the structure of the lessons, as each TA was provided the same slides and the same training in how to conduct the lab. The laboratory lessons were designed around the Ambitious Science Teaching framework described in the Introduction, which is meant to help students engage in the meaningful practices of their discipline, including scientific dialogue. One aspect of this framework is helping students connect their everyday explanations of their experiences to the scientific principles underlying them, that is, bridging their everyday way of talking and science talk. This initial conversation is thought to help them meaningfully engage in the subsequent lesson. This study focuses on these initial conversations.

Grinath and Southerland recorded the 8- to 22-minute–long class discussions that opened a lab class exploring how organisms respond to stimuli. At the start of class, students were asked to describe how they experience stress and explain what is driving this response. The authors transcribed the recordings and characterized each TA discourse “move,” a statement made by a TA that served a specific communication function. These moves were coded as conservative or ambitious . Conservative patterns follow the traditional classroom pattern, in which the expertise lies with the instructor only. These moves include the instructor asking questions that only have one correct answer, usually about recalling facts or procedures; evaluating a student response as right or wrong; and explaining the connection between the student response and the scientific concept rather than having students make the connection. Ambitious patterns of discourse allow students to be experts, and the instructor is the facilitator. These instructor moves include asking questions with many possible reasonable answers, probing student responses, and pressing students to supply explanations for their answers. Finally, observers also coded TA moves as inclusive or not inclusive . Inclusive moves could include providing opportunities for multiple students to respond to a question, acknowledging a contribution without indicating correctness, and repeating student responses out loud.

The discourse moves were correlated with student talk. Grinath and Southerland used a framework for explanatory rigor of scientific talk to code student responses in the initial class discussion. There were three codes for student answers: fact , observation , and explanation . A turn of student talk was coded as fact if it was short and a vocabulary word or scientific definition not grounded in personal experience. Observations were what a student thought was happening based on personal experience. Finally, explanations were students’ ideas of why something was happening. The goal of ambitious science teaching is to help students start making their own explanations of phenomena grounded in science and their own experiences. Thus, TA discourse moves that promoted student explanations were considered the most important in this study.

Using linear regressions with a Bonferroni correction for multiple comparisons, Grinath and Southerland found that conservative discourse moves by TAs were related to an increase in student responses being simply fact statements. Ambitious questions (with multiple possible answers) did not predict student responses, but ambitious responses in which TAs deliberately probed student response and pressed students to expand on their answers did relate to increased explanations. Finally, inclusive moves together related to increased observations given by students.

This work highlights several interesting principles that could be expanded beyond labs. First, it seems that, without deliberately pressing for it (and removing the instructor’s explanations), students are not making explanations themselves. They offer facts or observations and wait for the instructor to put them together. Yet explaining phenomena is a key scientific practice and one students should develop. Second, how instructors respond to student answers is critical for creating meaningful conversations in the classroom, maybe even more critical than the qualities of the initial question itself.

• A Critical Feminist Approach for Equity and Inclusion in Undergraduate Biology Education 22 April 2021

© 2019 S. L. Eddy. CBE—Life Sciences Education © 2019 The American Society for Cell Biology. This article is distributed by The American Society for Cell Biology under license from the author(s). It is available to the public under an Attribution–Noncommercial–Share Alike 3.0 Unported Creative Commons License (http://creativecommons.org/licenses/by-nc-sa/3.0).

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Action Research for Science Teachers

The Science Teacher—February 2020 (Volume 87, Issue 6)

By Scott B. Watson and Michelle J. Barthlow

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The purpose of educational research in general is to develop information which can be used to improve education. Alexakos (2015) stated that teachers conduct research to answer these questions about their own practice: How am I doing? How can I improve? What works? To answer these questions, teachers may conduct action research.

Action research

Action research is a special form of educational research. Gall, Gall, and Borg (2007) , authors of some of the most respected educational research texts, define action research as: “A type of applied research the purpose of which is the improvement of education professional’s own practice.” Lesha (2014) describes action research as being a cyclical or spiral process that begins with a teacher-researcher identifying a problem, investigating the problem, taking action, evaluating the results of the action, and then repeating the process. In doing so, teachers can develop the most appropriate strategies for their own classroom or school.

How is action research different?

Action research is not necessarily very different from other forms of educational research. The main difference is that it is conducted by practitioners in the schools instead of someone from outside the school, such as a university professor or another researcher. With schools focused on learning outcomes for students and the call for decisions based on student data, teachers need the skills and confidence to scientifically evaluate their own practice in order to make curriculum and instructional decisions. Action research provides teachers with the data needed to make informed decisions to benefit their students and improve their own classroom practice.

Action research is a great way for teachers to experience the 3D (three dimensional) approach of the Next Generation Science Standards ( NGSS ). NGSS incorporates the three dimensions of learning science: crosscutting concepts, science and engineering practices, and core ideas. As teachers embrace the NGSS , they will consider the crosscutting concepts of effective teaching and focus on the core ideas to be taught as they plan for instruction. Through action research, teachers can investigate their natural world—classroom instruction—to determine what is and is not resulting in learning gains for their students.

Educational trends without research

So why should science teachers be interested in research? Although most educational research is conducted by college professors and other professional researchers, teachers can enhance their own knowledge and may contribute to the research base through research in their own classrooms ( Abell 2007 ). Science teachers, because of the nature of their discipline, have a natural interest in research, and often have a good understanding of research methods.

Teachers seem to know many things intuitively (and through experience). A good example is using a hands-on approach to teaching science. The idea is that simply doing many activities is conducive to learning, which is not necessarily the case. Research findings indicate that if students do not fully understand what the activity is all about, very little learning really occurs ( Gough 1990 ; Nadelson 2009 ). In order to maximize learning (and achievement), a minds-on approach should be added to the hands-on approach. This should include using higher-order thinking and problem-solving skills in addition to simply participating in an activity ( Lumpe and Oliver 1991 ).

As another example of the practicality of conducting and understanding research for science teachers, consider the case of Mr. Nolan, a young chemistry teacher. Almost all of Mr. Nolan’s classes in college included midterm and final exams, mostly using a multiple-choice format. When he started teaching, he followed the same model with his own students. His whole evaluation system was based on teacher-made tests.

In an effort to increase his own knowledge in science and in education, Mr. Nolan enrolled in a graduate degree program at his local university. One of the early courses he completed was in educational research. During that time, he learned about reliability (internal consistency) of tests. Reliability is normally determined on a scale of 0 to 1, with 1 being perfect. It is an indicator of the precision, consistency, and stability of an instrument ( Gall, Gall, and Borg 2007 , p. 149).

One of his projects was to determine the reliability of one of his own tests. He picked one that he considered his best, and he ran a reliability figure using one of many available computer programs. Much to his dismay, he found that the reliability of his prized, multiple-choice measure was a .58, which is substantially lower than what is minimally acceptable for research purposes. He realized that relying on imperfect tests alone for grading purposes was a mistake. This discovery changed his teaching almost immediately, and he started including more projects, presentations, and practical labs as part of his assessment system. This also produced greater interest and participation among his students.

Basics of research methods: qualitative vs. quantitative

Two types of research methods are qualitative and quantitative studies. Denzin and Lincoln (1994) describe qualitative research as “interpretive, naturalistic….Qualitative researchers study things in their natural setting, attempting to make sense of, or interpret, phenomena in terms of the meanings people bring to them.” Quantitative research “…describes and explains…reality by collecting numerical data on observable behaviors…and by subjecting these data to statistical analysis” ( Gall, Gall, and Borg 2007 ).

Qualitative research differs from quantitative research in that it depends on numerical data; no statistics are needed. Qualitative research methods include interviews, surveys, and observations. Teachers could prepare a questionnaire to determine what methods and activities students feel are most beneficial to their learning. For more in-depth information, a teacher could conduct interviews with students.

A focus group of students can provide valuable insight into their experience in the classroom. Ary, Jacobs, and Sorenson (2010) point out that an advantage of a focus group is that participants respond not only to the interviewer but also to each other. These student-to-student interactions can result in more information than is typically collected in a one-on-one interview or survey.

Quantitative research is the systematic study of the relationships among variables. A variable is anything that can change during a study. An independent variable is sometimes referred to as the manipulated variable as it is deliberately changed (manipulated) during an experiment. A dependent, or responding, variable is one that may change as a result of the experiment. A controlled variable is a variable that you try to keep constant during the experiment. An extraneous variable is an outside or unknown variable that you have no control over.

Further explorations

For an action research project, Ms. Jones is curious about using the flipped classroom model, in which students first watch instructional videos outside of class and do homework and practice problems in class ( Brunsell and Horejsi 2013 ). For one unit of study, she decides to teach half of her class periods using the flipped model and the other half using the traditional model, where students engage in learning activities in class and do homework at home. She will give the same unit assessment to each group and compare the results.

Her independent variable is classroom pedagogy (flipped classroom vs. traditional). Her dependent variables are unit test results. The controlled variables include the length of time for the unit, the state standards, and the homework practice problems utilized. The examples given in class and on the teaching videos are all the same. Ms. Jones will compare the two group’s performance on the unit test using a t- test, which will allow her to determine if one group performs significantly better than the other on the assessment based on her pedagogy. Knowing what works best for students in her classroom will allow Ms. Jones to improve her teaching skills and will likely increase learning for her students.

Correlation studies

Simple forms of correlation research can be used to determine if there is a relationship between two continuous variables. A continuous variable is one that has a maximum value and a minimum value and can be any value in between ( Gall, Gall, and Borg 2007 ). A correlation will not show causation but will show if a relationship exists between two variables. An example action research project would be to determine if using a web-based practice quiz site prepares students for tests. A correlation could be performed to determine if the number of practice problems a student answers correctly correlates with their summative test score.

Quasi-experimental and causal-comparative designs

Statistical analysis, free statistical calculators.

Many statistical tests are available at no cost online or using Microsoft Excel. Some can even be performed with scientific or advanced calculators. Statistical analysis sources may be found by doing simple internet searches. One example of a free online resource for performing statistical calculations is GraphPad .

Getting started

Science teachers, due to their content training, have a real head start on most teachers in other fields when it comes to conducting research. Science teachers also have an advantage in their understanding of research because they already know that research can be fun, so get started!

Ary D., Jacobs L.C., and Sorenson C.. 2010. Introduction to research in education (8th Ed.). Belmont, CA: Wadsworth.

Brodie K. 2013. The power of professional learning communities. Education As Change 17 (1): 5–18. doi:10.1080/16823206.2013.773929

Brunsell E., and Horejsi M.. 2013. Science 2.0: A flipped classroom in action. The Science Teacher 80 (2): 8.

Denzin N.K., and Lincoln Y.S.. 2014. Handbook of qualitative research. Los Angeles: SAGE Publications.

Gall M., Gall J., and Borg W.. 2007. Educational research: An introduction . Boston: Pearson.

Gough P. B., Ed. 1990. Hands-on/minds-on: Making science accessible. Kappan 71 (9).

Lesha J. 2014. Action research in education . European Scientific Journal 10, 379.

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Research in Science Education is an international journal publishing and promoting scholarly science education research of interest to a wide group of people. The journal examines early childhood, primary, secondary, tertiary, workplace, and informal learning as they relate to science education.

In publishing scholarly articles, RISE is looking for articulation of the principles and practices used by scholars to make valid claims about the world and their critique of such claims. Publishing such work is important as it makes these principles and practices known to the scholarly community so that they can be considered, debated, judged, and accepted, rejected or reframed. Importantly, these principles and practices must be constantly advancing in ways that allow our knowledge to advance within the field. In looking for works to publish, RISE will seek articles that advance our knowledge in science education research rather than reproducing what we already know.

Research can take many forms, quantitative, qualitative and mixed methods to name a few. RISE is interested in producing valid and trustworthy research that takes on a variety of forms and embraces new capabilities at hand, particularly around new technologies. Innovative practices and how these relate to science education will be at the forefront of our thinking in RISE.

Scholarly works of interest need to encompass the wide diversity of readership. RISE is the journal associated with the Australasian Science Education Research Association (ASERA), one of the oldest such association in the world. With ASERA’s history from a colonial western tradition, combined with its location within the highly productive and exciting Asian region, the membership of ASERA and the readership of RISE spans the globe and cultural perspectives. Hence, the scholarly works of interest published within RISE need to reflect this diversity. Additionally, they must also include a diversity of form. So, RISE will continue to review articles, editorials, book reviews, and other material deemed appropriate by the Editors.

This is a transformative journal , you may have access to funding.

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Topical Collections in RISE

Research in Science Education (RISE) is pleased to announce the introduction of topical collections to complement the ongoing publication of papers through regular and special issues. A topical collection curates papers on a given topic, theme or problem. The articles in a topical collection are published continuously over several issues, making them different from special issues that are time-bounded and assigned to one issue. Articles selected for a topical collection will appear in that collection. At the same time, they will still be published in a regular issue.

Topical collections represent a chance for editors to gather related papers on a topic of contemporary interest to the RISE readership and the wider science education research community. As such, we are interested to develop collections that both consolidate a series of thematically-related papers previously published in RISE and encourage future developments in the field. This approach allows us to connect the rich  historical conversation in RISE with contemporary issues that matter to the science education community.

With this objective, RISE has launched two inaugural topical collections on “Artificial Intelligence in Science Education” and “STEM and teaching engineering design”. Interested authors are encouraged to explore these collections and contribute new articles that build upon the ongoing work within the collection. To read more of these collections, please click here .

Authors wishing to submit their manuscripts to a topical collection can indicate their intention via the Editorial Manager submission system. All submissions to a topical collection will undergo the same peer review process and standards. The Editors-in-Chief have the final discretions to choose and include articles in any collection.

Furthermore, RISE welcomes proposals for new topical collections that meet the following criteria:

1.      Relevance to RISE: The topic should have a solid foundation within RISE, as evidenced by a substantial number of previously published articles in RISE. These articles will be curated to form the initial core of the collection.

2.      Timeliness: The topic should focus on current and urgent issues in science education, demonstrating a strong potential to draw future contributions to the collection

Researchers interested in editing a topical collection are encouraged to contact the Editors-in-Chief.

Call for Papers: Science Education: Fit for the Future

Guest Editors: 

Peta White and Russell Tytler

Please email abstracts to [email protected] before you submit the full manuscripts online .  To read more, please click here

Abstracts should be 300 – 400 words making clear the nature of the contribution to new knowledge

Call for Papers: Special Issue: Enterpreneurial STEM Education

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Lyn English (Queensland University of Technology)

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