science education research topics

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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• Open access
• Published: 10 March 2020

Research and trends in STEM education: a systematic review of journal publications

• Yeping Li 1 ,
• Ke Wang 2 ,
• Yu Xiao 1 &
• Jeffrey E. Froyd 3  

International Journal of STEM Education volume  7 , Article number:  11 ( 2020 ) Cite this article

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With the rapid increase in the number of scholarly publications on STEM education in recent years, reviews of the status and trends in STEM education research internationally support the development of the field. For this review, we conducted a systematic analysis of 798 articles in STEM education published between 2000 and the end of 2018 in 36 journals to get an overview about developments in STEM education scholarship. We examined those selected journal publications both quantitatively and qualitatively, including the number of articles published, journals in which the articles were published, authorship nationality, and research topic and methods over the years. The results show that research in STEM education is increasing in importance internationally and that the identity of STEM education journals is becoming clearer over time.

Introduction

A recent review of 144 publications in the International Journal of STEM Education ( IJ - STEM ) showed how scholarship in science, technology, engineering, and mathematics (STEM) education developed between August 2014 and the end of 2018 through the lens of one journal (Li, Froyd, & Wang, 2019 ). The review of articles published in only one journal over a short period of time prompted the need to review the status and trends in STEM education research internationally by analyzing articles published in a wider range of journals over a longer period of time.

With global recognition of the growing importance of STEM education, we have witnessed the urgent need to support research and scholarship in STEM education (Li, 2014 , 2018a ). Researchers and educators have responded to this on-going call and published their scholarly work through many different publication outlets including journals, books, and conference proceedings. A simple Google search with the term “STEM,” “STEM education,” or “STEM education research” all returned more than 450,000,000 items. Such voluminous information shows the rapidly evolving and vibrant field of STEM education and sheds light on the volume of STEM education research. In any field, it is important to know and understand the status and trends in scholarship for the field to develop and be appropriately supported. This applies to STEM education.

Conducting systematic reviews to explore the status and trends in specific disciplines is common in educational research. For example, researchers surveyed the historical development of research in mathematics education (Kilpatrick, 1992 ) and studied patterns in technology usage in mathematics education (Bray & Tangney, 2017 ; Sokolowski, Li, & Willson, 2015 ). In science education, Tsai and his colleagues have conducted a sequence of reviews of journal articles to synthesize research trends in every 5 years since 1998 (i.e., 1998–2002, 2003–2007, 2008–2012, and 2013–2017), based on publications in three main science education journals including, Science Education , the International Journal of Science Education , and the Journal of Research in Science Teaching (e.g., Lin, Lin, Potvin, & Tsai, 2019 ; Tsai & Wen, 2005 ). Erduran, Ozdem, and Park ( 2015 ) reviewed argumentation in science education research from 1998 to 2014 and Minner, Levy, and Century ( 2010 ) reviewed inquiry-based science instruction between 1984 and 2002. There are also many literature reviews and syntheses in engineering and technology education (e.g., Borrego, Foster, & Froyd, 2015 ; Xu, Williams, Gu, & Zhang, 2019 ). All of these reviews have been well received in different fields of traditional disciplinary education as they critically appraise and summarize the state-of-art of relevant research in a field in general or with a specific focus. Both types of reviews have been conducted with different methods for identifying, collecting, and analyzing relevant publications, and they differ in terms of review aim and topic scope, time period, and ways of literature selection. In this review, we systematically analyze journal publications in STEM education research to overview STEM education scholarship development broadly and globally.

The complexity and ambiguity of examining the status and trends in STEM education research

A review of research development in a field is relatively straight forward, when the field is mature and its scope can be well defined. Unlike discipline-based education research (DBER, National Research Council, 2012 ), STEM education is not a well-defined field. Conducting a comprehensive literature review of STEM education research require careful thought and clearly specified scope to tackle the complexity naturally associated with STEM education. In the following sub-sections, we provide some further discussion.

Diverse perspectives about STEM and STEM education

STEM education as explicated by the term does not have a long history. The interest in helping students learn across STEM fields can be traced back to the 1990s when the US National Science Foundation (NSF) formally included engineering and technology with science and mathematics in undergraduate and K-12 school education (e.g., National Science Foundation, 1998 ). It coined the acronym SMET (science, mathematics, engineering, and technology) that was subsequently used by other agencies including the US Congress (e.g., United States Congress House Committee on Science, 1998 ). NSF also coined the acronym STEM to replace SMET (e.g., Christenson, 2011 ; Chute, 2009 ) and it has become the acronym of choice. However, a consensus has not been reached on the disciplines included within STEM.

To clarify its intent, NSF published a list of approved fields it considered under the umbrella of STEM (see http://bit.ly/2Bk1Yp5 ). The list not only includes disciplines widely considered under the STEM tent (called “core” disciplines, such as physics, chemistry, and materials research), but also includes disciplines in psychology and social sciences (e.g., political science, economics). However, NSF’s list of STEM fields is inconsistent with other federal agencies. Gonzalez and Kuenzi ( 2012 ) noted that at least two US agencies, the Department of Homeland Security and Immigration and Customs Enforcement, use a narrower definition that excludes social sciences. Researchers also view integration across different disciplines of STEM differently using various terms such as, multidisciplinary, interdisciplinary, and transdisciplinary (Vasquez, Sneider, & Comer, 2013 ). These are only two examples of the ambiguity and complexity in describing and specifying what constitutes STEM.

Multiple perspectives about the meaning of STEM education adds further complexity to determining the extent to which scholarly activity can be categorized as STEM education. For example, STEM education can be viewed with a broad and inclusive perspective to include education in the individual disciplines of STEM, i.e., science education, technology education, engineering education, and mathematics education, as well as interdisciplinary or cross-disciplinary combinations of the individual STEM disciplines (English, 2016 ; Li, 2014 ). On the other hand, STEM education can be viewed by others as referring only to interdisciplinary or cross-disciplinary combinations of the individual STEM disciplines (Honey, Pearson, & Schweingruber, 2014 ; Johnson, Peters-Burton, & Moore, 2015 ; Kelley & Knowles, 2016 ; Li, 2018a ). These multiple perspectives allow scholars to publish articles in a vast array and diverse journals, as long as journals are willing to take the position as connected with STEM education. At the same time, however, the situation presents considerable challenges for researchers intending to locate, identify, and classify publications as STEM education research. To tackle such challenges, we tried to find out what we can learn from prior reviews related to STEM education.

Guidance from prior reviews related to STEM education

A search for reviews of STEM education research found multiple reviews that could suggest approaches for identifying publications (e.g., Brown, 2012 ; Henderson, Beach, & Finkelstein, 2011 ; Kim, Sinatra, & Seyranian, 2018 ; Margot & Kettler, 2019 ; Minichiello, Hood, & Harkness, 2018 ; Mizell & Brown, 2016 ; Thibaut et al., 2018 ; Wu & Rau, 2019 ). The review conducted by Brown ( 2012 ) examined the research base of STEM education. He addressed the complexity and ambiguity by confining the review with publications in eight journals, two in each individual discipline, one academic research journal (e.g., the Journal of Research in Science Teaching ) and one practitioner journal (e.g., Science Teacher ). Journals were selected based on suggestions from some faculty members and K-12 teachers. Out of 1100 articles published in these eight journals from January 1, 2007, to October 1, 2010, Brown located 60 articles that authors self-identified as connected to STEM education. He found that the vast majority of these 60 articles focused on issues beyond an individual discipline and there was a research base forming for STEM education. In a follow-up study, Mizell and Brown ( 2016 ) reviewed articles published from January 2013 to October 2015 in the same eight journals plus two additional journals. Mizell and Brown used the same criteria to identify and include articles that authors self-identified as connected to STEM education, i.e., if the authors included STEM in the title or author-supplied keywords. In comparison to Brown’s findings, they found that many more STEM articles were published in a shorter time period and by scholars from many more different academic institutions. Taking together, both Brown ( 2012 ) and Mizell and Brown ( 2016 ) tended to suggest that STEM education mainly consists of interdisciplinary or cross-disciplinary combinations of the individual STEM disciplines, but their approach consisted of selecting a limited number of individual discipline-based journals and then selecting articles that authors self-identified as connected to STEM education.

In contrast to reviews on STEM education, in general, other reviews focused on specific issues in STEM education (e.g., Henderson et al., 2011 ; Kim et al., 2018 ; Margot & Kettler, 2019 ; Minichiello et al., 2018 ; Schreffler, Vasquez III, Chini, & James, 2019 ; Thibaut et al., 2018 ; Wu & Rau, 2019 ). For example, the review by Henderson et al. ( 2011 ) focused on instructional change in undergraduate STEM courses based on 191 conceptual and empirical journal articles published between 1995 and 2008. Margot and Kettler ( 2019 ) focused on what is known about teachers’ values, beliefs, perceived barriers, and needed support related to STEM education based on 25 empirical journal articles published between 2000 and 2016. The focus of these reviews allowed the researchers to limit the number of articles considered, and they typically used keyword searches of selected databases to identify articles on STEM education. Some researchers used this approach to identify publications from journals only (e.g., Henderson et al., 2011 ; Margot & Kettler, 2019 ; Schreffler et al., 2019 ), and others selected and reviewed publications beyond journals (e.g., Minichiello et al., 2018 ; Thibaut et al., 2018 ; Wu & Rau, 2019 ).

The discussion in this section suggests possible reasons contributing to the absence of a general literature review of STEM education research and development: (1) diverse perspectives in existence about STEM and STEM education that contribute to the difficulty of specifying a scope of literature review, (2) its short but rapid development history in comparison to other discipline-based education (e.g., science education), and (3) difficulties in deciding how to establish the scope of the literature review. With respect to the third reason, prior reviews have used one of two approaches to identify and select articles: (a) identifying specific journals first and then searching and selecting specific articles from these journals (e.g., Brown, 2012 ; Erduran et al., 2015 ; Mizell & Brown, 2016 ) and (b) conducting selected database searches with keywords based on a specific focus (e.g., Margot & Kettler, 2019 ; Thibaut et al., 2018 ). However, neither the first approach of selecting a limited number of individual discipline-based journals nor the second approach of selecting a specific focus for the review leads to an approach that provides a general overview of STEM education scholarship development based on existing journal publications.

Current review

Two issues were identified in setting the scope for this review.

What time period should be considered?

What publications will be selected for review?

Time period

We start with the easy one first. As discussed above, the acronym STEM did exist until the early 2000s. Although the existence of the acronym does not generate scholarship on student learning in STEM disciplines, it is symbolic and helps focus attention to efforts in STEM education. Since we want to examine the status and trends in STEM education, it is reasonable to start with the year 2000. Then, we can use the acronym of STEM as an identifier in locating specific research articles in a way as done by others (e.g., Brown, 2012 ; Mizell & Brown, 2016 ). We chose the end of 2018 as the end of the time period for our review that began during 2019.

Focusing on publications beyond individual discipline-based journals

As mentioned before, scholars responded to the call for scholarship development in STEM education with publications that appeared in various outlets and diverse languages, including journals, books, and conference proceedings. However, journal publications are typically credited and valued as one of the most important outlets for research exchange (e.g., Erduran et al., 2015 ; Henderson et al., 2011 ; Lin et al., 2019 ; Xu et al., 2019 ). Thus, in this review, we will also focus on articles published in journals in English.

The discourse above on the complexity and ambiguity regarding STEM education suggests that scholars may publish their research in a wide range of journals beyond individual discipline-based journals. To search and select articles from a wide range of journals, we thought about the approach of searching selected databases with keywords as other scholars used in reviewing STEM education with a specific focus. However, existing journals in STEM education do not have a long history. In fact, IJ-STEM is the first journal in STEM education that has just been accepted into the Social Sciences Citation Index (SSCI) (Li, 2019a ). Publications in many STEM education journals are practically not available in several important and popular databases, such as the Web of Science and Scopus. Moreover, some journals in STEM education were not normalized due to a journal’s name change or irregular publication schedule. For example, the Journal of STEM Education was named as Journal of SMET Education when it started in 2000 in a print format, and the journal’s name was not changed until 2003, Vol 4 (3 and 4), and also went fully on-line starting 2004 (Raju & Sankar, 2003 ). A simple Google Scholar search with keywords will not be able to provide accurate information, unless you visit the journal’s website to check all publications over the years. Those added complexities prevented us from taking the database search as a viable approach. Thus, we decided to identify journals first and then search and select articles from these journals. Further details about the approach are provided in the “ Method ” section.

Research questions

Given a broader range of journals and a longer period of time to be covered in this review, we can examine some of the same questions as the IJ-STEM review (Li, Froyd, & Wang, 2019 ), but we do not have access to data on readership, articles accessed, or articles cited for the other journals selected for this review. Specifically, we are interested in addressing the following six research questions:

What were the status and trends in STEM education research from 2000 to the end of 2018 based on journal publications?

What were the patterns of publications in STEM education research across different journals?

Which countries or regions, based on the countries or regions in which authors were located, contributed to journal publications in STEM education?

What were the patterns of single-author and multiple-author publications in STEM education?

What main topics had emerged in STEM education research based on the journal publications?

What research methods did authors tend to use in conducting STEM education research?

Based on the above discussion, we developed the methods for this literature review to follow careful sequential steps to identify journals first and then identify and select STEM education research articles published in these journals from January 2000 to the end of 2018. The methods should allow us to obtain a comprehensive overview about the status and trends of STEM education research based on a systematic analysis of related publications from a broad range of journals and over a longer period of time.

Identifying journals

We used the following three steps to search and identify journals for inclusion:

We assumed articles on research in STEM education have been published in journals that involve more than one traditional discipline. Thus, we used Google to search and identify all education journals with their titles containing either two, three, or all four disciplines of STEM. For example, we did Google search of all the different combinations of three areas of science, mathematics, technology Footnote 1 , and engineering as contained in a journal’s title. In addition, we also searched possible journals containing the word STEAM in the title.

Since STEM education may be viewed as encompassing discipline-based education research, articles on STEM education research may have been published in traditional discipline-based education journals, such as the Journal of Research in Science Teaching . However, there are too many such journals. Yale’s Poorvu Center for Teaching and Learning has listed 16 journals that publish articles spanning across undergraduate STEM education disciplines (see https://poorvucenter.yale.edu/FacultyResources/STEMjournals ). Thus, we selected from the list some individual discipline-based education research journals, and also added a few more common ones such as the Journal of Engineering Education .

Since articles on research in STEM education have appeared in some general education research journals, especially those well-established ones. Thus, we identified and selected a few of those journals that we noticed some publications in STEM education research.

Following the above three steps, we identified 45 journals (see Table  1 ).

Identifying articles

In this review, we will not discuss or define the meaning of STEM education. We used the acronym STEM (or STEAM, or written as the phrase of “science, technology, engineering, and mathematics”) as a term in our search of publication titles and/or abstracts. To identify and select articles for review, we searched all items published in those 45 journals and selected only those articles that author(s) self-identified with the acronym STEM (or STEAM, or written as the phrase of “science, technology, engineering, and mathematics”) in the title and/or abstract. We excluded publications in the sections of practices, letters to editors, corrections, and (guest) editorials. Our search found 798 publications that authors self-identified as in STEM education, identified from 36 journals. The remaining 9 journals either did not have publications that met our search terms or published in another language other than English (see the two separate lists in Table 1 ).

Data analysis

To address research question 3, we analyzed authorship to examine which countries/regions contributed to STEM education research over the years. Because each publication may have either one or multiple authors, we used two different methods to analyze authorship nationality that have been recognized as valuable from our review of IJ-STEM publications (Li, Froyd, & Wang, 2019 ). The first method considers only the corresponding author’s (or the first author, if no specific indication is given about the corresponding author) nationality and his/her first institution affiliation, if multiple institution affiliations are listed. Method 2 considers every author of a publication, using the following formula (Howard, Cole, & Maxwell, 1987 ) to quantitatively assign and estimate each author’s contribution to a publication (and thus associated institution’s productivity), when multiple authors are included in a publication. As an example, each publication is given one credit point. For the publication co-authored by two, the first author would be given 0.6 and the second author 0.4 credit point. For an article contributed jointly by three authors, the three authors would be credited with scores of 0.47, 0.32, and 0.21, respectively.

After calculating all the scores for each author of each paper, we added all the credit scores together in terms of each author’s country/region. For brevity, we present only the top 10 countries/regions in terms of their total credit scores calculated using these two different methods, respectively.

To address research question 5, we used the same seven topic categories identified and used in our review of IJ-STEM publications (Li, Froyd, & Wang, 2019 ). We tested coding 100 articles first to ensure the feasibility. Through test-coding and discussions, we found seven topic categories could be used to examine and classify all 798 items.

K-12 teaching, teacher, and teacher education in STEM (including both pre-service and in-service teacher education)

Post-secondary teacher and teaching in STEM (including faculty development, etc.)

K-12 STEM learner, learning, and learning environment

Post-secondary STEM learner, learning, and learning environments (excluding pre-service teacher education)

Policy, curriculum, evaluation, and assessment in STEM (including literature review about a field in general)

Culture and social and gender issues in STEM education

History, epistemology, and perspectives about STEM and STEM education

To address research question 6, we coded all 798 publications in terms of (1) qualitative methods, (2) quantitative methods, (3) mixed methods, and (4) non-empirical studies (including theoretical or conceptual papers, and literature reviews). We assigned each publication to only one research topic and one method, following the process used in the IJ-STEM review (Li, Froyd, & Wang, 2019 ). When there was more than one topic or method that could have been used for a publication, a decision was made in choosing and assigning a topic or a method. The agreement between two coders for all 798 publications was 89.5%. When topic and method coding discrepancies occurred, a final decision was reached after discussion.

Results and discussion

In the following sections, we report findings as corresponding to each of the six research questions.

The status and trends of journal publications in STEM education research from 2000 to 2018

Figure  1 shows the number of publications per year. As Fig.  1 shows, the number of publications increased each year beginning in 2010. There are noticeable jumps from 2015 to 2016 and from 2017 to 2018. The result shows that research in STEM education had grown significantly since 2010, and the most recent large number of STEM education publications also suggests that STEM education research gained its own recognition by many different journals for publication as a hot and important topic area.

The distribution of STEM education publications over the years

Among the 798 articles, there were 549 articles with the word “STEM” (or STEAM, or written with the phrase of “science, technology, engineering, and mathematics”) included in the article’s title or both title and abstract and 249 articles without such identifiers included in the title but abstract only. The results suggest that many scholars tended to include STEM in the publications’ titles to highlight their research in or about STEM education. Figure  2 shows the number of publications per year where publications are distinguished depending on whether they used the term STEM in the title or only in the abstract. The number of publications in both categories had significant increases since 2010. Use of the acronym STEM in the title was growing at a faster rate than using the acronym only in the abstract.

The trends of STEM education publications with vs. without STEM included in the title

Not all the publications that used the acronym STEM in the title and/or abstract reported on a study involving all four STEM areas. For each publication, we further examined the number of the four areas involved in the reported study.

Figure  3 presents the number of publications categorized by the number of the four areas involved in the study, breaking down the distribution of these 798 publications in terms of the content scope being focused on. Studies involving all four STEM areas are the most numerous with 488 (61.2%) publications, followed by involving one area (141, 17.7%), then studies involving both STEM and non-STEM (84, 10.5%), and finally studies involving two or three areas of STEM (72, 9%; 13, 1.6%; respectively). Publications that used the acronym STEAM in either the title or abstract were classified as involving both STEM and non-STEM. For example, both of the following publications were included in this category.

Dika and D’Amico ( 2016 ). “Early experiences and integration in the persistence of first-generation college students in STEM and non-STEM majors.” Journal of Research in Science Teaching , 53 (3), 368–383. (Note: this article focused on early experience in both STEM and Non-STEM majors.)

Sochacka, Guyotte, and Walther ( 2016 ). “Learning together: A collaborative autoethnographic exploration of STEAM (STEM+ the Arts) education.” Journal of Engineering Education , 105 (1), 15–42. (Note: this article focused on STEAM (both STEM and Arts).)

Publication distribution in terms of content scope being focused on. (Note: 1=single subject of STEM, 2=two subjects of STEM, 3=three subjects of STEM, 4=four subjects of STEM, 5=topics related to both STEM and non-STEM)

Figure  4 presents the number of publications per year in each of the five categories described earlier (category 1, one area of STEM; category 2, two areas of STEM; category 3, three areas of STEM; category 4, four areas of STEM; category 5, STEM and non-STEM). The category that had grown most rapidly since 2010 is the one involving all four areas. Recent growth in the number of publications in category 1 likely reflected growing interest of traditional individual disciplinary based educators in developing and sharing multidisciplinary and interdisciplinary scholarship in STEM education, as what was noted recently by Li and Schoenfeld ( 2019 ) with publications in IJ-STEM.

Publication distribution in terms of content scope being focused on over the years

Patterns of publications across different journals

Among the 36 journals that published STEM education articles, two are general education research journals (referred to as “subject-0”), 12 with their titles containing one discipline of STEM (“subject-1”), eight with journal’s titles covering two disciplines of STEM (“subject-2”), six covering three disciplines of STEM (“subject-3”), seven containing the word STEM (“subject-4”), and one in STEAM education (“subject-5”).

Table  2 shows that both subject-0 and subject-1 journals were usually mature journals with a long history, and they were all traditional subscription-based journals, except the Journal of Pre - College Engineering Education Research , a subject-1 journal established in 2011 that provided open access (OA). In comparison to subject-0 and subject-1 journals, subject-2 and subject-3 journals were relatively newer but still had quite many years of history on average. There are also some more journals in these two categories that provided OA. Subject-4 and subject-5 journals had a short history, and most provided OA. The results show that well-established journals had tended to focus on individual disciplines or education research in general. Multidisciplinary and interdisciplinary education journals were started some years later, followed by the recent establishment of several STEM or STEAM journals.

Table 2 also shows that subject-1, subject-2, and subject-4 journals published approximately a quarter each of the publications. The number of publications in subject-1 journals is interested, because we selected a relatively limited number of journals in this category. There are many other journals in the subject-1 category (as well as subject-0 journals) that we did not select, and thus it is very likely that we did not include some STEM education articles published in subject-0 or subject-1 journals that we did not include in our study.

Figure  5 shows the number of publications per year in each of the five categories described earlier (subject-0 through subject-5). The number of publications per year in subject-5 and subject-0 journals did not change much over the time period of the study. On the other hand, the number of publications per year in subject-4 (all 4 areas), subject-1 (single area), and subject-2 journals were all over 40 by the end of the study period. The number of publications per year in subject-3 journals increased but remained less than 30. At first sight, it may be a bit surprising that the number of publications in STEM education per year in subject-1 journals increased much faster than those in subject-2 journals over the past few years. However, as Table 2 indicates these journals had long been established with great reputations, and scholars would like to publish their research in such journals. In contrast to the trend in subject-1 journals, the trend in subject-4 journals suggests that STEM education journals collectively started to gain its own identity for publishing and sharing STEM education research.

STEM education publication distribution across different journal categories over the years. (Note: 0=subject-0; 1=subject-1; 2=subject-2; 3=subject-3; 4=subject-4; 5=subject-5)

Figure  6 shows the number of STEM education publications in each journal where the bars are color-coded (yellow, subject-0; light blue, subject-1; green, subject-2; purple, subject-3; dark blue, subject-4; and black, subject-5). There is no clear pattern shown in terms of the overall number of STEM education publications across categories or journals, but very much individual journal-based performance. The result indicates that the number of STEM education publications might heavily rely on the individual journal’s willingness and capability of attracting STEM education research work and thus suggests the potential value of examining individual journal’s performance.

Publication distribution across all 36 individual journals across different categories with the same color-coded for journals in the same subject category

The top five journals in terms of the number of STEM education publications are Journal of Science Education and Technology (80 publications, journal number 25 in Fig.  6 ), Journal of STEM Education (65 publications, journal number 26), International Journal of STEM Education (64 publications, journal number 17), International Journal of Engineering Education (54 publications, journal number 12), and School Science and Mathematics (41 publications, journal number 31). Among these five journals, two journals are specifically on STEM education (J26, J17), two on two subjects of STEM (J25, J31), and one on one subject of STEM (J12).

Figure  7 shows the number of STEM education publications per year in each of these top five journals. As expected, based on earlier trends, the number of publications per year increased over the study period. The largest increase was in the International Journal of STEM Education (J17) that was established in 2014. As the other four journals were all established in or before 2000, J17’s short history further suggests its outstanding performance in attracting and publishing STEM education articles since 2014 (Li, 2018b ; Li, Froyd, & Wang, 2019 ). The increase was consistent with the journal’s recognition as the first STEM education journal for inclusion in SSCI starting in 2019 (Li, 2019a ).

Publication distribution of selected five journals over the years. (Note: J12: International Journal of Engineering Education; J17: International Journal of STEM Education; J25: Journal of Science Education and Technology; J26: Journal of STEM Education; J31: School Science and Mathematics)

Top 10 countries/regions where scholars contributed journal publications in STEM education

Table  3 shows top countries/regions in terms of the number of publications, where the country/region was established by the authorship using the two different methods presented above. About 75% (depending on the method) of contributions were made by authors from the USA, followed by Australia, Canada, Taiwan, and UK. Only Africa as a continent was not represented among the top 10 countries/regions. The results are relatively consistent with patterns reported in the IJ-STEM study (Li, Froyd, & Wang, 2019 )

Further examination of Table 3 reveals that the two methods provide not only fairly consistent results but also yield some differences. For example, Israel and Germany had more publication credit if only the corresponding author was considered, but South Korea and Turkey had more publication credit when co-authors were considered. The results in Table 3 show that each method has value when analyzing and comparing publications by country/region or institution based on authorship.

Recognizing that, as shown in Fig. 1 , the number of publications per year increased rapidly since 2010, Table  4 shows the number of publications by country/region over a 10-year period (2009–2018) and Table 5 shows the number of publications by country/region over a 5-year period (2014–2018). The ranks in Tables  3 , 4 , and 5 are fairly consistent, but that would be expected since the larger numbers of publications in STEM education had occurred in recent years. At the same time, it is interesting to note in Table 5 some changes over the recent several years with Malaysia, but not Israel, entering the top 10 list when either method was used to calculate author's credit.

Patterns of single-author and multiple-author publications in STEM education

Since STEM education differs from traditional individual disciplinary education, we are interested in determining how common joint co-authorship with collaborations was in STEM education articles. Figure  8 shows that joint co-authorship was very common among these 798 STEM education publications, with 83.7% publications with two or more co-authors. Publications with two, three, or at least five co-authors were highest, with 204, 181, and 157 publications, respectively.

Number of publications with single or different joint authorship. (Note: 1=single author; 2=two co-authors; 3=three co-authors; 4=four co-authors; 5=five or more co-authors)

Figure  9 shows the number of publications per year using the joint authorship categories in Fig.  8 . Each category shows an increase consistent with the increase shown in Fig. 1 for all 798 publications. By the end of the time period, the number of publications with two, three, or at least five co-authors was the largest, which might suggest an increase in collaborations in STEM education research.

Publication distribution with single or different joint authorship over the years. (Note: 1=single author; 2=two co-authors; 3=three co-authors; 4=four co-authors; 5=five or more co-authors)

Co-authors can be from the same or different countries/regions. Figure  10 shows the number of publications per year by single authors (no collaboration), co-authors from the same country (collaboration in a country/region), and co-authors from different countries (collaboration across countries/regions). Each year the largest number of publications was by co-authors from the same country, and the number increased dramatically during the period of the study. Although the number of publications in the other two categories increased, the numbers of publications were noticeably fewer than the number of publications by co-authors from the same country.

Publication distribution in authorship across different categories in terms of collaboration over the years

Published articles by research topics

Figure  11 shows the number of publications in each of the seven topic categories. The topic category of goals, policy, curriculum, evaluation, and assessment had almost half of publications (375, 47%). Literature reviews were included in this topic category, as providing an overview assessment of education and research development in a topic area or a field. Sample publications included in this category are listed as follows:

DeCoito ( 2016 ). “STEM education in Canada: A knowledge synthesis.” Canadian Journal of Science , Mathematics and Technology Education , 16 (2), 114–128. (Note: this article provides a national overview of STEM initiatives and programs, including success, criteria for effective programs and current research in STEM education.)

Ring-Whalen, Dare, Roehrig, Titu, and Crotty ( 2018 ). “From conception to curricula: The role of science, technology, engineering, and mathematics in integrated STEM units.” International Journal of Education in Mathematics Science and Technology , 6 (4), 343–362. (Note: this article investigates the conceptions of integrated STEM education held by in-service science teachers through the use of photo-elicitation interviews and examines how those conceptions were reflected in teacher-created integrated STEM curricula.)

Schwab et al. ( 2018 ). “A summer STEM outreach program run by graduate students: Successes, challenges, and recommendations for implementation.” Journal of Research in STEM Education , 4 (2), 117–129. (Note: the article details the organization and scope of the Foundation in Science and Mathematics Program and evaluates this program.)

Frequencies of publications’ research topic distributions. (Note: 1=K-12 teaching, teacher and teacher education; 2=Post-secondary teacher and teaching; 3=K-12 STEM learner, learning, and learning environment; 4=Post-secondary STEM learner, learning, and learning environments; 5=Goals and policy, curriculum, evaluation, and assessment (including literature review); 6=Culture, social, and gender issues; 7=History, philosophy, Epistemology, and nature of STEM and STEM education)

The topic with the second most publications was “K-12 teaching, teacher and teacher education” (103, 12.9%), followed closely by “K-12 learner, learning, and learning environment” (97, 12.2%). The results likely suggest the research community had a broad interest in both teaching and learning in K-12 STEM education. The top three topics were the same in the IJ-STEM review (Li, Froyd, & Wang, 2019 ).

Figure  11 also shows there was a virtual tie between two topics with the fourth most cumulative publications, “post-secondary STEM learner & learning” (76, 9.5%) and “culture, social, and gender issues in STEM” (78, 9.8%), such as STEM identity, students’ career choices in STEM, and inclusion. This result is different from the IJ-STEM review (Li, Froyd, & Wang, 2019 ), where “post-secondary STEM teacher & teaching” and “post-secondary STEM learner & learning” were tied as the fourth most common topics. This difference is likely due to the scope of journals and the length of the time period being reviewed.

Figure  12 shows the number of publications per year in each topic category. As expected from the results in Fig.  11 the number of publications in topic category 5 (goals, policy, curriculum, evaluation, and assessment) was the largest each year. The numbers of publications in topic category 3 (K-12 learner, learning, and learning environment), 1 (K-12 teaching, teacher, and teacher education), 6 (culture, social, and gender issues in STEM), and 4 (post-secondary STEM learner and learning) were also increasing. Although Fig.  11 shows the number of publications in topic category 1 was slightly more than the number of publications in topic category 3 (see Fig.  11 ), the number of publications in topic category 3 was increasing more rapidly in recent years than its counterpart in topic category 1. This may suggest a more rapidly growing interest in K-12 STEM learner, learning, and learning environment. The numbers of publications in topic categories 2 and 7 were not increasing, but the number of publications in IJ-STEM in topic category 2 was notable (Li, Froyd, & Wang, 2019 ). It will be interesting to follow trends in the seven topic categories in the future.

Publication distributions in terms of research topics over the years

Published articles by research methods

Figure  13 shows the number of publications per year by research methods in empirical studies. Publications with non-empirical studies are shown in a separate category. Although the number of publications in each of the four categories increased during the study period, there were many more publications presenting empirical studies than those without. For those with empirical studies, the number of publications using quantitative methods increased most rapidly in recent years, followed by qualitative and then mixed methods. Although there were quite many publications with non-empirical studies (e.g., theoretical or conceptual papers, literature reviews) during the study period, the increase of the number of publications in this category was noticeably less than empirical studies.

Publication distributions in terms of research methods over the years. (Note: 1=qualitative, 2=quantitative, 3=mixed, 4=Non-empirical)

Concluding remarks

The systematic analysis of publications that were considered to be in STEM education in 36 selected journals shows tremendous growth in scholarship in this field from 2000 to 2018, especially over the past 10 years. Our analysis indicates that STEM education research has been increasingly recognized as an important topic area and studies were being published across many different journals. Scholars still hold diverse perspectives about how research is designated as STEM education; however, authors have been increasingly distinguishing their articles with STEM, STEAM, or related words in the titles, abstracts, and lists of keywords during the past 10 years. Moreover, our systematic analysis shows a dramatic increase in the number of publications in STEM education journals in recent years, which indicates that these journals have been collectively developing their own professional identity. In addition, the International Journal of STEM Education has become the first STEM education journal to be accepted in SSCI in 2019 (Li, 2019a ). The achievement may mark an important milestone as STEM education journals develop their own identity for publishing and sharing STEM education research.

Consistent with our previous reviews (Li, Froyd, & Wang, 2019 ; Li, Wang, & Xiao, 2019 ), the vast majority of publications in STEM education research were contributed by authors from the USA, where STEM and STEAM education originated, followed by Australia, Canada, and Taiwan. At the same time, authors in some countries/regions in Asia were becoming very active in the field over the past several years. This trend is consistent with findings from the IJ-STEM review (Li, Froyd, & Wang, 2019 ). We certainly hope that STEM education scholarship continues its development across all five continents to support educational initiatives and programs in STEM worldwide.

Our analysis has shown that collaboration, as indicated by publications with multiple authors, has been very common among STEM education scholars, as that is often how STEM education distinguishes itself from the traditional individual disciplinary based education. Currently, most collaborations occurred among authors from the same country/region, although collaborations across cross-countries/regions were slowly increasing.

With the rapid changes in STEM education internationally (Li, 2019b ), it is often difficult for researchers to get an overall sense about possible hot topics in STEM education especially when STEM education publications appeared in a vast array of journals across different fields. Our systematic analysis of publications has shown that studies in the topic category of goals, policy, curriculum, evaluation, and assessment have been the most prevalent, by far. Our analysis also suggests that the research community had a broad interest in both teaching and learning in K-12 STEM education. These top three topic categories are the same as in the IJ-STEM review (Li, Froyd, & Wang, 2019 ). Work in STEM education will continue to evolve and it will be interesting to review the trends in another 5 years.

Encouraged by our recent IJ-STEM review, we began this review with an ambitious goal to provide an overview of the status and trends of STEM education research. In a way, this systematic review allowed us to achieve our initial goal with a larger scope of journal selection over a much longer period of publication time. At the same time, there are still limitations, such as the decision to limit the number of journals from which we would identify publications for analysis. We understand that there are many publications on STEM education research that were not included in our review. Also, we only identified publications in journals. Although this is one of the most important outlets for scholars to share their research work, future reviews could examine publications on STEM education research in other venues such as books, conference proceedings, and grant proposals.

Availability of data and materials

The data and materials used and analyzed for the report are publicly available at the various journal websites.

Journals containing the word "computers" or "ICT" appeared automatically when searching with the word "technology". Thus, the word of "computers" or "ICT" was taken as equivalent to "technology" if appeared in a journal's name.

Abbreviations

Information and Communications Technology

International Journal of STEM Education

Kindergarten–Grade 12

Science, Mathematics, Engineering, and Technology

Science, Technology, Engineering, Arts, and Mathematics

Science, Technology, Engineering, and Mathematics

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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

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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).

Topics and Trends in Current Science Education

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Introduction: To Be More Relevant the Field of Science Education Needs to Be Less Relevant

Introduction: Science Education Research and Practice in Taiwan: A Little Giant!

Introduction

• classroom practices
• learning science
• pedagogical content knowledge
• pro-service teacher education
• science education
• scientific literacy
• socio-scientific issues
• teacher professional development
• teaching resources
• teaching science

Table of contents (35 chapters)

Front matter, overview of the book.

• Catherine Bruguière, Andrée Tiberghien, Pierre Clément

Socio-scientific Issues

The need for a public understanding of sciences.

• Isabelle Stengers

Questions Socialement Vives and Socio-scientific Issues: New Trends of Research to Meet the Training Needs of Postmodern Society

• Laurence Simonneaux

Teachers’ Beliefs, Classroom Practices and Professional Development Towards Socio-scientific Issues

• Virginie Albe, Catherine Barrué, Larry Bencze, Anne Kristine Byhring, Lyn Carter, Marcus Grace et al.

Which Perspectives Are Referred in Students’ Arguments About a Socio-scientific Issue? The Case of Bears’ Reintroduction in the Pyrenees

• Ana M. Domènech, Conxita Márquez

Learning About the Role and Function of Science in Public Debate as an Essential Component of Scientific Literacy

• Ingo Eilks, Jan Alexis Nielsen, Avi Hofstein

Exploring Secondary Students’ Arguments in the Context of Socio-scientific Issues

• Fatih Çağlayan Mercan, Buket Yakmacı-Güzel, Füsun Akarsu

Teachers’ Beliefs on Science-Technology-Society (STS) and Nature of Science (NOS): Strengths, Weaknesses, and Teaching Practice

• Ángel Vázquez–Alonso, María-Antonia Manassero–Mas, Antonio García–Carmona, Antoni Bennàssar-Roig

Teachers’ Practices and Teachers Professional Development

Professional learning of science teachers.

• Jan H. Van Driel

Nanoeducation: Zooming into Teacher Professional Development Programmes in Nanoscience and Technology

• Ron Blonder, Ilka Parchmann, Sevil Akaygun, Virginie Albe

Education for Sustainable Development: An International Survey on Teachers’ Conceptions

• Pierre Clément, Silvia Caravita

Learning to Teach Science as Inquiry: Developing an Evidence-Based Framework for Effective Teacher Professional Development

• Barbara A. Crawford, Daniel K. Capps, Jan van Driel, Norman Lederman, Judith Lederman, Julie A. Luft et al.

Weaving Relationships in a Teaching Sequence Using ICT: A Case Study in Optics at Lower Secondary School

• Suzane El Hage, Christian Buty

Inquiry-Based Mathematics and Science Education Across Europe: A Synopsis of Various Approaches and Their Potentials

• Katrin Engeln, Silke Mikelskis-Seifert, Manfred Euler

Measuring Chemistry Teachers’ Content Knowledge: Is It Correlated to Pedagogical Content Knowledge?

• Oliver Tepner, Sabrina Dollny

The Students: Multiple Perspectives

Editors and affiliations.

Catherine Bruguière, Pierre Clément

Andrée Tiberghien

Bibliographic Information

Book Title : Topics and Trends in Current Science Education

Book Subtitle : 9th ESERA Conference Selected Contributions

Editors : Catherine Bruguière, Andrée Tiberghien, Pierre Clément

Series Title : Contributions from Science Education Research

DOI : https://doi.org/10.1007/978-94-007-7281-6

Publisher : Springer Dordrecht

eBook Packages : Humanities, Social Sciences and Law , Education (R0)

Copyright Information : Springer Science+Business Media Dordrecht 2014

Hardcover ISBN : 978-94-007-7280-9 Published: 09 December 2013

Softcover ISBN : 978-94-024-0060-1 Published: 23 August 2016

eBook ISBN : 978-94-007-7281-6 Published: 19 November 2013

Series ISSN : 2213-3623

Series E-ISSN : 2213-3631

Edition Number : 1

Number of Pages : X, 601

Number of Illustrations : 45 b/w illustrations, 57 illustrations in colour

Topics : Science Education

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Scientific Research in Education

Researchers, historians, and philosophers of science have debated the nature of scientific research in education for more than 100 years. Recent enthusiasm for "evidence-based" policy and practice in education—now codified in the federal law that authorizes the bulk of elementary and secondary education programs—have brought a new sense of urgency to understanding the ways in which the basic tenets of science manifest in the study of teaching, learning, and schooling.

Scientific Research in Education describes the similarities and differences between scientific inquiry in education and scientific inquiry in other fields and disciplines and provides a number of examples to illustrate these ideas. Its main argument is that all scientific endeavors share a common set of principles, and that each field—including education research—develops a specialization that accounts for the particulars of what is being studied. The book also provides suggestions for how the federal government can best support high-quality scientific research in education.

RESOURCES AT A GLANCE

• Press Release
• Education — Education Research and Theory
• Education — Math and Science Education

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National Research Council. 2002. Scientific Research in Education . Washington, DC: The National Academies Press. https://doi.org/10.17226/10236. Import this citation to: Bibtex EndNote Reference Manager

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• Paperback:  978-0-309-08291-4
• Ebook:  978-0-309-13309-8

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Understanding Science

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Educational research.

The teaching resources recommended on our site are consistent with what is known about how students learn the nature and process of science. Educational research suggests that the most effective instruction in this area is explicit and reflective, and provides multiple opportunities for students to work with key concepts in different contexts. But just how do we know that this sort of instruction works? And how do we know which concepts are hardest for students to learn and which are the most difficult misconceptions to address? To find out, browse the links below. Each link summarizes a journal article from the education research literature and helps reveal how we know what we know about how students learn.

• “That’s what scientists have to do”: Preservice elementary teachers’ conceptions of the nature of science during a moon investigation.  (Abell et al., 2001)
• Influence of a reflective activity-based approach on elementary teachers’ conceptions of nature of science.  (Akerson et al., 2000)
• Evaluating knowledge of the nature of (whole) science.  (Allchin, 2011)
• Learners’ responses to the demands of conceptual change: Considerations for effective nature of science instruction.  (Clough, 2006)
• Examining students’ views on the nature of science: Results from Korean 6th, 8th, and 10th graders.  (Kang et al., 2004)
• Influence of explicit and reflective versus implicit inquiry-oriented instruction on sixth graders’ views of nature of science.  (Khishfe and Abd-El-Khalick, 2002)
• Teachers’ understanding of the nature of science and classroom practice: Factors that facilitate or impede the relationship.  (Lederman, 1999)
• Revising instruction to teach nature of science.  (Lederman and Lederman, 2004)
• Science teachers’ conceptions of the nature of science: Do they really influence teacher behavior?  (Lederman and Zeidler, 1987)
• Examining student conceptions of the nature of science.  (Moss, 2001)
• Student conceptualizations of the nature of science in response to a socioscientific issue.  (Sadler et al., 2004)
• Explicit reflective nature of science instruction: Evolution, intelligent design, and umbrellaology.  (Scharmann et al., 2005)
• Developing views of nature of science in an authentic context: An explicit approach to bridging the gap between nature of science and scientific inquiry.  (Schwartz et al., 2004)
• Tangled up in views: Beliefs in the nature of science and responses to socioscientific dilemmas.  (Zeidler et al., 2002)

Abell, S., M. Martini, and M. George. 2001. “That’s what scientists have to do”: Preservice elementary teachers’ conceptions of the nature of science during a moon investigation.  International Journal of Science Education  23(11):1095-1109. Two sections of an undergraduate course in elementary science education were observed during an extended investigation, in which students made observations of the moon and tried to develop explanations for what they saw. Students worked in groups, were engaged in many aspects of the process of science, and were asked to reflect on their own learning regarding the moon. Eleven student journals of the experience, along with interview transcripts from these students, were analyzed for student learning regarding observation in science, the role of creativity and inference in science, and social aspects of science. Major findings include:

• Students recognized that observations are key in science but didn’t recognize the role that observation plays in science.
• Students recognized that their own work involved observing, predicting, and coming up with explanations, but they did not generally connect this to the process of science.
• Students recognized that collaboration facilitated their own learning but did not generally connect this to the process of science.

This research highlights the pedagogical importance of making the nature and process of science explicit: even though students were actively engaged in scientific processes, they did not get many of the key messages that the instructors implicitly conveyed. The researchers also recommend asking students to reflect on how their own understandings of the nature and process of science are changing over time.

Akerson, V.L., F. Abd-El-Khalick, and N.G. Lederman. 2000. Influence of a reflective activity-based approach on elementary teachers’ conceptions of nature of science.  Journal of Research in Science Teaching  37(4):295-317. Fifty undergraduate and graduate students enrolled in a science teaching methods course engaged in six hours of activities designed to target key nature-of-science concepts, consistent with those outlined in Lederman and Lederman (2004). After the initial set of activities and throughout the course, students were encouraged to reflect on those concepts as opportunities arose within the designated pedagogical content, and were assigned two writing tasks focusing on the nature of science. By the end of the course, students were so accustomed to these reflections that they frequently identified such opportunities for themselves. Students were pre- and post-tested with an open-ended questionnaire targeting the key concepts, and a subset of students was interviewed on these topics. Responses were analyzed for key concepts to determine whether students held adequate conceptions in these areas. Major findings include:

• There were few differences between graduates and undergraduates: most students began the course with largely inadequate conceptions.
• Students began the course understanding least about the empirical nature of science, the tentative nature of scientific knowledge, the difference between theories and laws, and the role of creativity in science.
• Significant gains were achieved as a result of instruction. Student conceptions improved most in the areas of the tentative nature of scientific knowledge, the difference between theories and laws, and the difference between observation and inference.

The explicit, reflective instruction was effective, but despite the gains achieved, many students still held inadequate conceptions at the end of the course. This supports the idea that students hold tenacious misconceptions about the nature and process of science, and, the authors argue, suggests that instructors should additionally focus on helping students see the inadequacy of their current conceptions. The authors suggest that the role of subjectivity, as well as of social and cultural factors, in science are best learned through rich historical case studies, which are hard to fit into a methods course. Finally, the authors conclude that nature-of-science instruction is effective in a methods course, but would likely be more effective in a science content course.

Allchin, D. 2011. Evaluating knowledge of the nature of (whole) science.  Science Education  95:518-542. The author argues that commonly used instruments assessing knowledge of the nature of science are inadequate in several ways. They focus too much on declarative knowledge instead of conceptual understanding, are designed for research not classroom assessment, and are inauthentic in the sense that they do not examine student knowledge in contexts similar to those in which we want students to use this knowledge. Furthermore, lists of the tenets of the nature of science (which such assessments are based upon) are oversimplified and incomplete. The author argues that instead of assessing whether students can list the characteristics of scientific knowledge, we should be interested in whether students can effectively analyze information about scientific and socioscientific controversies and assess the reliability of scientific claims that affect their decision making. In order to do this, students need to understand how the process of science lends credibility to scientific ideas. The author proposes an alternative assessment form (based on the AP free responses essay) that requires well-informed analysis on the part of the student, involves authentic contexts, and can be adapted for many different assessment purposes and situations. In it, students are asked to analyze historic and modern case studies of scientific and socioscientific controversies. Prototypes for this type of assessment are provided.

Clough, M. 2006. Learners’ responses to the demands of conceptual change: Considerations for effective nature of science instruction.  Science Education  15:463-494. The author introduces the idea that many aspects of student learning about the nature and process of science can be explained, and that learning may be improved, by viewing this learning as a process of conceptual change. Just as in learning about Newtonian physics, students often enter an instructional setting with tenacious misconceptions about what science is and how it works — probably resulting from previous instruction (e.g., cookbook labs) and other experiences. Students may then distort new information to fit their existing incorrect knowledge frameworks. The author proposes that this is why explicit, reflective instruction (which provides students with opportunities to assess their previous conceptions) helps students learn about the nature and process of science, while implicit, non-reflective instruction does not. Furthermore, the author argues that explicit instruction on the nature and process of science can be placed along a continuum from decontextualized to highly contextualized. Examples of each are:

• Decontextualized: black-box activities
• Moderately contextualized: students reflecting on the process of science in their own labs
• Highly contextualized: students reflecting on a modern or historic example of science in progress

Highly contextualized activities are useful because they make it difficult for a student to dismiss their learning as applying only to “school science” and because teachers are less likely to view such activities as add-ons. However, decontextualized activities also have advantages because they make it very easy to be explicit and emphasize key concepts. The author concludes that instruction that incorporates instruction from all along the continuum and that draws students’ attention to the connections between the different positions along the continuum is likely to be most effective.

Kang, S., L. Scharmann, and T. Noh. 2004. Examining students’ views on the nature of science: Results from Korean 6th, 8th, and 10th graders.  Science Education  89(2):314-334. A multiple-choice survey (supplemented by open-ended questions) on the nature and process of science was given to a large group of 6th, 8th, and 10th grade students in Korea. Most students thought that:

• Science is mainly concerned with technological advancement
• Theories are proven facts
• Theories can change over time
• Scientific knowledge is not constructed, but discovered (i.e., can be read off of nature)

Interestingly, Korean students don’t tend to hold the common Western misperception of theories as “just hunches.” The researchers found little improvement in understanding in older students. This suggests that special attention is needed to help students learn about the nature of science. The researchers argue that we should begin instruction in this area early in elementary school.

Khishfe, R., and F. Abd-El-Khalick. 2002. Influence of explicit and reflective versus implicit inquiry-oriented instruction on sixth graders’ views of nature of science.  Journal of Research in Science Teaching  39(7):551-578. Two sixth grade classes (62 students total) in Lebanon experienced two different versions of a curriculum spanning ten 50 minute segments. One class participated in an inquiry-oriented science curriculum, which included a discussion component that explicitly emphasized how the nature of science was demonstrated through student activities. The other participated in the same inquiry curriculum, but their discussion focused exclusively on science content or the skills students had used in the activity. Both groups completed open-ended questionnaires and participated in interviews regarding their views of the nature of science before and after the intervention. The two groups started off with similar, low levels of understanding, but the students in the class with explicit discussion of the nature of science substantially improved their understanding of key elements of the nature of science (the tentative, empirical, and creative nature of scientific knowledge, as well as the difference between observation and inference) over the course of the intervention. The other group did not. However, even with the enhanced, explicit curriculum, only 24% of the students achieved a consistently accurate understanding of the nature of science. These findings support the idea that inquiry alone is insufficient to improve student understanding of the nature of science; explicit, reflective instruction is necessary as well. The researchers further conclude that this instruction should be incorporated throughout teaching over an extended period of time in order to see gains among a larger fraction of students. The researchers emphasize that explicit, reflective teaching does not mean didactic teaching, but rather instruction that specifically targets nature of science concepts and that provides students with opportunities to relate their own activities to the activities of scientists and the scientific community more broadly.

Lederman, N.G. 1999. Teachers’ understanding of the nature of science and classroom practice: Factors that facilitate or impede the relationship.  Journal of Research in Science Teaching  36(8):916-929. Five high school biology teachers were observed weekly for one year to examine whether their conceptions of the nature of science were reflected in their teaching. The researcher also collected data from questionnaires, student and teacher interviews, and classroom materials. All five teachers had accurate understandings of the nature of science. The most experienced teachers used pedagogical techniques consistent with the nature of science, though they weren’t explicitly trying to do so and did not claim to be trying to improve students’ understanding of the nature of science. Less experienced teachers did not teach in a manner consistent with their views of the nature of science. This suggests that an adequate understanding of the nature and process of science and curricular flexibility alone are not sufficient to ensure that teachers will use pedagogical techniques that reflect that understanding. In addition, the researchers found that students in these classrooms gained little understanding of the nature of science, regardless of whether they were taught by a more or less experienced teacher. This lends further support to the idea that teachers need to be explicit about how lessons and activities relate to the nature and process of science in order for students to improve their understandings in this area. The researcher concludes that teacher education programs need to make a concerted effort to help teachers improve their ability to explicitly translate their understanding of the nature of science into their teaching practices. Furthermore, teachers should be encouraged to view an understanding of the nature of science as an important pedagogical objective in its own right.

Lederman, N.G., and J.S. Lederman. 2004. Revising instruction to teach nature of science.  The Science Teacher  71(9):36-39. The authors describe seven aspects of the nature of science that are important for K-12 students to understand:

• the difference between observation and inference
• the difference between laws and theories
• that science is based on observations of the natural world
• that science involves creativity
• that scientific knowledge is partially subjective
• that science is socially and culturally embedded
• that scientific knowledge is subject to change.

They argue that most lessons can be modified to emphasize one or more of these ideas and provide an example from biology instruction. Many teachers use an activity in which students study a slide of growing tissue and count cells at different stages of mitosis in order to estimate the lengths of these stages. The authors recommend modifying this activity in several ways:

• asking students to reason about how they know when one stage ends to emphasize the sort of subjectivity with which scientists must deal
• asking students to grapple with ambiguity in their data
• asking students to reason about why different groups came up with different estimates and how confident they are in their estimates in order to emphasize the tentativity of scientific knowledge
• asking students to distinguish between what they directly observed on the slide and what they inferred from those observations.

The authors emphasize that incorporating the nature and process of science into this activity involves, not changing the activity itself, but carefully crafting reflective questions that make explicit relevant aspects of the nature and process of science.

Lederman, N.G., and D.L. Zeidler. 1987. Science teachers’ conceptions of the nature of science: Do they really influence teacher behavior?  Science Education  71(5):721-734. Eighteen high school biology classrooms led by experienced teachers were studied over the course of one semester. Teachers’ understandings of the nature and process of science were assessed at the beginning and end of the semester. In addition, the researchers made extensive observations of each classroom at three different points in the semester and categorized the teachers’ and students’ behaviors along many variables relating to teaching the nature and process of science. The researchers found  no  relationship between a teacher’s knowledge of the nature and process of science and the teacher’s general instructional approach, the nature-of-science content addressed in the classroom, the teacher’s attitude, the classroom atmosphere, or the students’ interactions with the teacher. This finding challenges the widely held assumption that student understanding of the nature and process of science can be improved simply by improving teacher understanding. Instead, the teachers’ level of understanding of this topic was unrelated to classroom performance. The authors emphasize that this doesn’t indicate that a teacher’s ideas don’t matter at all; teachers need at least a basic understanding of the topics they will teach, but this alone isn’t enough. The authors suggest that to improve their teaching in this area, instructors also need to be prepared with strategies designed specifically for teaching the nature and process of science.

Moss, D.M. 2001. Examining student conceptions of the nature of science.  International Journal of Science Education  23(8):771-790. Five 11th and 12th grade students, with a range of academic achievement, taking an environmental science class, were interviewed six times over the course of a year. The class was project-based and engaged students in data collection for real scientific research. Interviews focused on students’ views of selected aspects of the nature and process of science. The researcher coded and interpreted transcripts of the interviews. Major findings include:

• In contrast to previous studies, most students understood that scientific knowledge builds on itself and is tentative. Students also seemed to understand science as a social activity.
• Many students didn’t know what makes science science and had trouble distinguishing science from other ways of knowing.
• Many students viewed science as merely procedural.
• Most students didn’t understand that scientists regularly generate new research questions as they work.
• Despite the authentic, project-based nature of the course, there were few shifts in student views of the nature and process of science.

This research supports the view that explicit instruction is necessary to improve student understanding of the nature/process of science. The researcher suggests that this can be done by having students develop their own descriptions of the fundamentals of the nature and process of science. The researcher also suggests that teachers need to focus on helping students understand the boundaries of science, perhaps by explicitly discussing how science compares to other human endeavors.

Sadler, T.D., F.W. Chambers, and D. Zeidler. 2004. Student conceptualizations of the nature of science in response to a socioscientific issue.  International Journal of Science Education  26(4):387-409. A group of average- to below average-achieving high school students was asked to read contradictory reports about the status of the global warming debate and answer a series of open-ended questions that related to the nature and process of science. Each report included data to support its conclusions. The researchers examined and coded students’ oral and written responses. On the positive side, the researchers found that:

• Most students understood that science and social issues are intertwined.
• Most students were comfortable with the idea that scientific data can be used to support different conclusions and that ideological positions may influence data interpretation.
• Almost half of the students were unable to accurately identify and describe data, and some conflated expectations and opinions with data.
• There was a tendency for students to view the interpretation consistent with their prior opinion as the most persuasive argument – even in cases where they judged the opposite interpretation to have the most scientific merit. This suggests that students may not incorporate scientific information into their decision-making process, dichotomizing their personal beliefs and scientific evidence.

The researchers suggest that instruction should focus on the above two issues and that teachers should encourage students to consider scientific findings when making decisions. In addition, students should be encouraged to deeply reflect on socioscientific issues and consider them from multiple perspectives.

Scharmann, L.C., M.U. Smith, M.C. James, and M. Jensen. 2005. Explicit reflective nature of science instruction: Evolution, intelligent design, and umbrellaology.  Journal of Science Teacher Education  16(1):27-41. Through multiple iterations of a preservice science teacher education course, the researchers designed a 10 hour instructional unit. In the unit, students:

• attempt to arrange a set of statements along a continuum from more to less scientific
• develop a set of criteria for making such judgments
• participate in a set of inquiry activities designed to teach the nature of science (e.g., the black box activity)
• read and reflect on articles about the nature of science
• analyze intelligent design, evolutionary biology, and umbrellaology (a satirical description of the field of umbrella studies) in terms of the criteria they developed.

The final iteration of this set of activities was judged by the authors to be highly effective at changing students’ views of the nature of science and perhaps even helping them recognize that intelligent design is less scientific than evolutionary biology. Furthermore, the researchers suggest that using a continuum approach regarding the classification of endeavors as more or less scientific may be helpful for students who have strong religious commitments and that explicit, respectful discussion of religion in relation to science early in instruction is likewise important for these students.

Schwartz, R.S., N.G. Lederman, and B. Crawford. 2004. Developing views of nature of science in an authentic context: An explicit approach to bridging the gap between nature of science and scientific inquiry.  Science Education  88(4):610-645. A group of preservice science teachers participated in a program that included 10 weeks of work with a scientific research group, discussions of research and the nature of science, and writing prompts which asked the preservice teachers to make connections between their research and the process of science. Participants were interviewed and observed, and responded to a questionnaire about the nature of science. Eighty-five percent of the participants improved their understanding of the nature of science over the course of the program. The two participants who did not improve their understanding were the two that focused on the content of their research and did not reflect on how this related to the nature of science. Participants also seemed to gain a better understanding of how to teach the nature and process of science explicitly. The researchers conclude that the research experience alone did little to improve students understanding, but that this experience was important for providing the context in which active reflection about the nature and process of science could occur. They recommend that scientific inquiry in the K-12 classroom incorporate reflective activities and explicit discussions relating the inquiry activity to the nature and process of science.

Zeidler, D.L., K.A. Walker, W.A. Ackett, and M.L. Simmons. 2002. Tangled up in views: Beliefs in the nature of science and responses to socioscientific dilemmas.  Science Education  86(3):343-367. A sample of 248 high school and college students were given open-ended questions eliciting their views of the nature of science. In addition, researchers elicited students’ views on a socioscientific issue (the appropriateness of animal research) using both a Likert scale item and open-ended questions. From this large sample, 42 pairs of students with differing views of the appropriateness of animal research were selected. These pairs of students were allowed to discuss the issue with each other and were probed by an interviewer. Finally, they were presented with data anomalous to their own view and were probed again on their confidence in the data and their willingness to change their view. Researchers analyzed these 82 students’ responses to the open-ended questions using concept mapping and compared their responses to Likert items. They found that students  did  change their views on the issue as a result of discussion and exposure to anomalous data. They also found that younger students tended to be less skeptical of anomalous data presented to them from an official-sounding report. In only a few cases were students’ views of the nature of science obviously related to their analysis of the socioscientific issue. These were mainly situations in which a student expressed a belief that scientists interpret data to suit their personal opinion, and then, correspondingly, the student selectively accepted or rejected evidence according to whether it supported his or her opinion. In addition, many students seemed to believe that all opinions are equally valid and immune to change regardless of the scientific evidence. The authors conclude that instruction on the nature of science should be incorporated throughout science courses and should include discussion in which students are asked to contrast different viewpoints on socioscientific issues and evaluate how different types of data might support or refute those positions.

Thanks to Norm Lederman and Joanne Olson for consultation on relevant research articles.

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Home > Centers > Center for Science Education > Dissertations and Theses

Center for Science Education Dissertations and Theses

Theses/dissertations from 2019 2019.

The Impact of Integrating Traditional Ecological Knowledge in Summer Camps on Middle School Students' Understanding of the Nature of Science , Sapoóq'is Wiíit'es Ciarra Solina Greene

Theses/Dissertations from 2018 2018

Computer-Based Instruction as a Form of Differentiated Instruction in a Traditional, Teacher-led, Low-Income, High School Biology Classroom , Cheryl Casey

Theses/Dissertations from 2017 2017

Analyzing the Online Environment: How are More Effective Teachers Spending Their Time? , Scott Davis Barrentine

Can a Three-Day Training Focusing on the Nature of Science and Science Practices as They Relate to Mind in the Making Make a Difference in Preschool Teachers' Self-Efficacy Engaging in Science Education? , Colleen Meacham

A Pilot Study on Methods to Introduce Teachers to New Science Standards , Noelle Frances Garcia Niedo

Using the Task Analysis Process with Teachers to Uncover Language Demands within an Eight-Week NGSS Summer Course , Leah Plack

How Does a Next Generation Science Standard Aligned, Inquiry Based, Science Unit Impact Student Achievement of Science Practices and Student Science Efficacy in an Elementary Classroom? , Kayla Lee Whittington

Theses/Dissertations from 2016 2016

Tryon Trekkers: An Evaluation of a STEM Based Afterschool Program for At-Risk Youth , Chessa Eckels Anderson

Learning Through Nature: A Study of a Next Generation Science Standards Based Teacher Workshop that Blends Outdoor Learning Experiences with Formal Science , Ashley Fanning

Connecting to Nature, Community, and Self: A Conservation Corps Approach to Re-engaging At-Risk Youth in Science Education , Sara Jo Linden

Growing STEM Education on the Playground: A Case Study of the Factors That Influence Teachers’ Use of School Gardens , Megan Poole

Creating a Learning Continuum: A Critical Look at the Intersection of Prior Knowledge, Outdoor Education, and Next Generation Science Standards Disciplinary Core Ideas and Practices , Trisha Leigh Schlobohm

Keeley Probes as a Tool for Uncovering Student Ideas: How Do Teachers Use Formative Assessment Probes to Plan and Adapt Instruction? , Kalin Tobler

The Effectiveness of Participation in a Project-based Learning Project on At-risk Student Self-Efficacy , Benjamin Aaron Weber

Origin and Use of Pedagogical Content Knowledge: A Case Study of Three Math Teachers and Their Students , Christopher Neal Wood

Theses/Dissertations from 2015 2015

Engineering a Healthier Watershed: Middle School Students Use Engineering Design to Lessen the Impact of Their Campus' Impervious Surfaces on Their Local Watershed , Elizabeth Claire Gardner

Isn’t Citizen Science a Hoot? A Case-study Exploring the Effectiveness of Citizen Science as an Instrument to Teach the Nature of Science through a Local Nocturnal Owl-Monitoring Project , Tess Marie Kreofsky

Focus on a STEM, Based in Place, Watershed Curriculum: A confluence of stormwater, humans, knowledge, attitudes, and skills , Lecia Molineux Schall

Theses/Dissertations from 2014 2014

Evaluation of a High School Science Fair Program for promoting Successful Inquiry-based Learning , Julia Nykeah Betts

The Power of Reflective Professional Development in Changing Elementary School Teachers' Instructional Practices , Carolina Christmann Cavedon

Using Art to Teach Students Science Outdoors: How Creative Science Instruction Influences Observation, Question Formation, and Involvement , Christina Schull Cone

"What Does This Graph Mean?" Formative Assessment With Science Inquiry to Improve Data Analysis , Andrea Dawn Leech

Associations between Input and Outcome Variables in an Online High School Bioinformatics Instructional Program , Douglas S. Lownsbery

Using Music-Related Concepts to Teach High School Math , Vytas Nagisetty

Project NANO: Will Allowing High School Students To Use Research Grade Scanning Electron Microscopes Increase Their Interest in Science? , Leslie TenEyck Smith

Effects of Ethnicity and Gender on Sixth-Grade Students' Environmental Knowledge and Attitudes After Participation in a Year-Long Environmental Education Program , Rachel Stagner

Integrating K-W-L Prompts into Science Journal Writing: Can Simple Question Scaffolding Increase Student Content Knowledge? , Brandon Joel Wagner

Theses/Dissertations from 2013 2013

An Investigation into Instructional Support for Data Analysis in High School Science Inquiry , Anika Rae Baker-Lawrence

Deoxyribonucleic Acid and Other Words Students Avoid Speaking Aloud: Evaluating the Role of Pronunciation on Participation in Secondary School Science Classroom Conversations , Stacie Elizabeth Beck

Increasing Evidence Based Reasoning in an 8th Grade Classroom Through Explicit Instruction , Erol Chandler

Lighting the Fire: How Peer-Mentoring Helps Adult Learners Increase Their Interest in STEM Careers: A Case Study at the Community College Level , Patricia Marie DeTurk

How Does Student Understanding of a Concept Change Throughout a Unit of Instruction? Support Toward the Theory of Learning Progressions , Brian Jay Dyer

Impact of Teacher Feedback on the Development of State Issued Scoring Guides for Science Inquiry and Engineering Design Performance Assessments , Timothy Paul Fiser

An Investigation into Teacher Support of Science Explanation in High School Science Inquiry Units , Rebecca Sue Hoffenberg

Science Journals in the Garden: Developing the Skill of Observation in Elementary Age Students , Karinsa Michelle Kelly

Thinking Aloud in the Science Classroom: Can a literacy strategy increase student learning in science? , Lindsey Joan Mockel

Patterns in Nature Forming Patterns in Minds : An Evaluation of an Introductory Physics Unit , Christopher Ryan Sheaffer

Grouped to Achieve: Are There Benefits to Assigning Students to Heterogeneous Cooperative Learning Groups Based on Pre-Test Scores? , Arman Karl Werth

Theses/Dissertations from 2012 2012

Sustainability Education as a Framework for Enhancing Environmental Stewardship in Young Leaders: An Intervention at Tryon Creek Nature Day Camp , Andrea Nicole Lawrence

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Do "Clickers" Improve Student Engagement and Learning in Secondary Schools? , Andrew James Mankowski

An Action Research Study to Determine the Feasibility of Using Concept Maps as Alternative Assessments by a Novice Teacher , Nancy Smith Mitchell

Using Brownfields to Think Green: Investigating Factors that Influence Community Decision-Making and Participation , Charissa Ruth Stair

Investigating Student Understanding of the Law of Conservation of Matter , Shirley Lynn Tremel

The Effect of Role Models on the Attitudes and Career Choices of Female Students Enrolled in High School Science , Stephanie Justine Van Raden

Improving Hypothesis Testing Skills: Evaluating a General Purpose Classroom Exercise with Biology Students in Grade 9. , Michael Gregg Wilder

Theses/Dissertations from 2010 2010

An Environment-based Education Approach to Professional Development: A Mixed Methods Analysis of the Creeks and Kids Watershed Workshop and Its Impact on K-12 Teachers , Tiffany Bridgette Austin

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Science Education Research Papers/Topics

Technologically-driven education: uncovering the two sides through article analysis.

In this paper, we undertake an article analysis approach to examine the profound shift in education towards a technologically-driven curriculum. We explore the positives and negatives of this transformative phenomenon, while placing particular emphasis on the prescient warnings articulated by Goldin and Katz in "The Race Between Education and Technology." Additionally, we delve into the thought-provoking insights presented by Vidal in "Digital Education: The Approach of a Modern Teacher," spe...

Demographic Aspects In The Use Of Music- Action Integration In Teaching Mitosis

 Music and action integration have been used in a lot of pedagogical studies in the field of science education. This study sought to situate demographic factors such as sex and educational background to teach mitosis. Using the experimental-correlational design, the level of significance was identified using a t-test for the performance based on the pre and post-tests.  Results showed that music-action integration was an effective tool in teaching mitosis compared to the traditional lecture...

ASSESSMENT OF OUTDOOR LEARNING ACTIVITIES IN THE TEACHING OF BASIC SCIENCE AND TECHNOLOGY IN JUNIOR SECONDARY SCHOOLS IN EKITI STATE, NIGERIA

The study identified the outdoor learning activities in Basic Science and Technology (BST) curriculum. The study assessed the extent of the use of outdoor science learning activities in teaching BST in the junior secondary schools in the study area. It further examined the perceived influence of teachers’ use of outdoor learning activities on students’ learning in the study area. This was with a view to providing information on the outdoor science learning activities in BST Curriculum tha...

Effects Of Poverty On The Academic Performance Of Learners In The Selected Secondary Schools Of Manga Division, Manga District Kenya

ABSTRACT The purpose of this study was to establish the effects of poverty on learners' academic performance of the selected schools in Manga Division Manga District Kenya. To specific objectives of the study were to investigate the relationship between the effects mentioned and academic performance in Manga division, and to investigate the role of the community in alleviating poverty and improving education in Manga Division. The methods used for data collection were questionnaires to the st...

Parental Illiteracy And Learners' Academic Perfomance In Ntugi Zone, Abothuguchi Central Division, Merv Central District, Kenya

ABSTRACT Generally, various researcher report have revealed that more highly educated mothers have greater success in providing their children with the cognitive and language skills that contribute to early success in school (Sticht & McDonald, 1990). Also, children of mothers with high levels of education stay in school longer than children of mothers ·with low levels of education. Parental iY(f/uence on the intellectual, social, economic, psychological and moral .formation of children in s...

Effects Of Teaching Learning Resources On Chemistry Performance At "0" Level. Case Study Of Bumuli Division, Bungoma District, Kenya

ABSTRACT This case study was an investigation into the effects of teaching learning resources on chemistry performance at "0" level. The general aim of the study was to find out the impact of teaching learning resources on performance of chemistry in "0" Level. The objectives of the study were to find out the teaching learning resources for chemistry, to determine the effects of lack of teaching learning resources on chemist!)' performance, to find out the attitude of students towards chemis...

IMPACT OF UNIVERSAL PRIMARY EDUCATION ON ACADEMIC PERFORMANCE OF LEARNERS IN THE YEARS OF 2003-2006

TABLE OF CONTENTS Declaration ................................................................................................................................ ii Approval ................................................................................................................................... iii Dedication ................................................................................................................................. .iv Acknowledgement ................................

Impact Of Urbanisation On Wetland Degradation A Case Study Of Nakivubo -Luzira Urban Wetland, Nakawa Division, Kampala City, Uganda

TABLE OF CONTENTSDECLARATION IIIAPPROVAL VDEDICATIONS ViACKNOWLEDGEMENT viiLIST OF ACRONYNIMS viiiABSTRACT ixCHAPTER ONE 11.0 INTRODUCTION 11.1 BAcKGROuND TO THE STUDY 11.2 STATEMENT OF THE PROBLEM 31.3 OBJECTIVES OF THE STUDY 41.4 RESEARCH QUESTIONS 41.5 SCOPE OF THE STUDY 4CHAPTER TWO 52.0 LITERATURE REVIEW 52.1 VALUES AND NATURAL FUNCTIONS OF WETLANDS 52.1.1 Major economic uses 62.1.2 Ecological Functions 72.1.3 Socio~Economic Functions 82.1.4 How valuable are Uganda~ wetlands? 92.2 HuMAN ...

Factors Affecting Physics Performance In Secondary Schools In Buikwe Sub-county, Mu.Kono District

ABSTRACT The researcher, set out to investigate the factors affecting physics performance in Secondary school in Buikwe sub-county, Mukono District, Uganda. The researcher has set out to investigate the background of the study, statement of the problem, hypothesis significance of the study, and scope of the study. The study will benefit all government officials, teachers, parents and especially students m secondary schools. In chapter two relevant study literature has been identified which gu...

The Effects Of Discipline On Students After The Prohibition Of Corporal Punishment In Kenya: A Case Study Of Kiruri Secondary School, Murang’a District -Central Province Kenya

TABLE OF CONTENTS CHAPTER ONE I 1 .0 Introduction 1.1 Background to the study 1 1 .2 Statement of the problem 4 1.3 Purpose of the study 5 1 .4 Objectives of the study 5 1 .5 Research questions 5 1.6 Significance of the study 6 1.7 Scope of the study 6 Definition of Key terms 7 1.9 List of Acronyms 8 CHAPTER TWO 9 LITERATURE REVIEW 9 2.0 Introduction 9 2.2 Historical perspective of students discipline in Kenya 9 2.2 A legal perspective of students discipline in Kenya 12 2,3 Effective of disci...

The Impact Of Students' Poor Performance In Psychics Subject In Kenyan Secondary Schools A Case Study Of Mogotio District-kenya

ABSTRACT The major objective was to find out on the impact of students' poor performance in physics subject in Mogotio district. A total of 60 (sixty) participants, 30 teachers, 10 parents, 15 students and 10 political leaders were involved in the study. The study question was 'nvestigated in line with the research questions of the study. The first research 1uestion sought to find out the causes of poor performance of physics subject if students. The study discovered that; Poor feeding ,Poor ...

A Comparative Study Between Male And Female Students’ Performance In Mathematics In Selected Secondary Schools In Western Uganda. (Hoima District)

ABSTRACT This study was designed to diagnose students’ performance in Mathematics in senior secondary schools in Hoima district. The study centered its review of related literature on task factor on gender difference in mathematics performance, environmental factor as well as process factors in teaching mathematics. Average, percentage and measures of relationship were used as approach to data analysis. The study revealed that task factors, process factors, environmental factors and process...

Home Background And Students’ Academic Performance, A Case Of Selected Secondary Schools In Munarya Sub-county, Kapchorwa District

ABSTRACT This study intended to establish the relationship between home background and academic performance of secondary school students in Munarya sub county, Kapchorwa District. During the study, the data was collected using documentary analysis, already existing literature (secondary and primary data) in comparison with primary sources of data. The study was guided by the following specific aims, To find out the relationship between parental marital status and academic performance, to esta...

Teaching Strategies And Performance Of Teachers in Secondary Schools of Toroma County, Katakwi District, Uganda.

ABSTRACT This research examined teaching strategies and performance of teachers in secondary schools in a sample of Toroma County schools. The research was specifically working on; teaching strategies and relationship between teaching strategies and performance of teachers. The study employed descriptive survey design. Questionnaires were used to get responses from the respondents and researchers observation to confirm already given information. Random sampling was used where four schools wer...

The Effects Of Gender Issues On The Academic Performance Of Learners In Secondary Schools.

ABSTRACT The purpose of the study was to determine the impact of the gender issues on the academic performance of learners in selected schools of Central division , Trans-Nzoia West west district, Kenya. Specific objectives of the study were to: examine the impact of gender on academic performance of learners Central division , Kiambu, Kenya and to examine strategies used by schools to improve on the academic performance of the girls and boys in Waitaluk Secondary School west division. The me...

Popular Papers/Topics

Causes of pupils‟ poor performance in integrated science in selected junior high schools., biology topics perceived as difficult to learn by senior high school biology students in the mampong and ejura-sekyedumase municipalities, the effect of practical work on shs students’ understanding of some selected topics in physics, the impact of using multimedia on students' academic performance in genetics in the brong ahafo region, pre-service science teachers’ competence, self-efficacy believes and readiness levels in ict integration in teaching science, teaching methods and students’ academic performance in genetics., using activity method of teaching to improve upon the performance of shs two home economic students in integrated science at diabene secondary technical school in the western region., using model to teach double indicator titration based on the constructivist approach, using concept maps to enhance the learning of cell biology by first year students of nifa and h’mount sinai senior high schools, the status of the teaching and learning of biology in selected senior high schools in the volta region of ghana, the perception of ict on the teaching and learning of kinematics graphs: a case study, chemistry topic-difficulties perceived by shs students and how they are addressed by their teachers and the prescribed textbooks, using cooperative teaching and learning approach to improve students’ attitudes and achievement in biology: a case study of tamale business senior high school in the northern region of ghana, using jigsaw model to enhance s.h.s chemistry students’ performance in organic compounds’ classification and nomenclature, an investigation into factors that militate against teaching and learning of integrated science at the junior high school level, a survey of ten (10) selected schools in the juaboso district.

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COSAM News Articles 2024 06 High school students explore diverse topics in science during elevated educational experience at Summer Science Institute 2024

High school students explore diverse topics in science during elevated educational experience at Summer Science Institute 2024

Published: 06/18/2024

By: Jess Gilpin

Sixteen rising juniors and seniors representing fourteen high schools across Alabama and Georgia completed a week-long Summer Science Institute, or SSI, held June 2-8, 2024, on Auburn University’s campus. Hosted by the STEM Outreach Center in the College of Sciences and Mathematics, or COSAM, the institute is a science program held annually for students with a high aptitude and interest in the fields of science and math.

Summer Science Institute partners our visiting high school scholars with over 20 Auburn University science and math research faculty to engage in topics more advanced than what is typically taught in a public or private high school environment. Through lab instruction and unique, hands-on learning opportunities, they get to explore cutting-edge science in research areas across COSAM’s five departments.

This year, institute scholars experienced atmospheric chemistry testing, wild bird study field work, modeling experimental data of the universe, a herpetology hunt in Tuskegee National Forest, solar energy experiments, using the physics of musical instruments to design and make a flute, and much more. With COSAM graduate students and an upper-level undergraduate student as their camp counselors, SSI Scholars received a week-long glimpse of campus life. During their time on campus, students were housed in campus dorms and ate at the Melton Student Center and the Edge, just like college students.

In one lab session led by Hong Zhao, assistant professor of physics, scholars learned about space weather with an interactive tutorial and trivia. From degrading power grid operations to modifying signals from radio navigation systems, they learned the importance of space weather and how to deal with the challenges associated with it. Zhao is one of eleven faculty members that provided financial support for the program through their National Science Foundation Grant broader impacts.

One scholar mentioned in their post survey, “I genuinely enjoyed every experience. Not only have I learned a myriad of things about science and mathematics, but I learned more about the college application process, how college-life is, new people I have met, etc. It has been such an amazing experience, and I will hold these memories for a very long time. I am truly grateful to have been chosen for this, and I am very thankful for everyone that has worked on this for providing us with such an amazing week.”

A fellow 2024 SSI scholar said, “I appreciated how our days were packed with STEM-related activities. Initially, I anticipated that I would be spending hours alone in my dorm in the evenings, but I valued the activities that helped me build both science knowledge and relationships with my peers.”

Students residing in Alabama or Georgia and entering their junior or senior year of high school are eligible to apply to SSI annually starting in October, and a limited number are chosen on an academically competitive basis. Participants attend at no cost with fees financed by grants and other sponsoring organizations at Auburn University.

To learn more about the program, visit the Summer Science Institute website or contact Jessica Gilpin, assistant director, COSAM STEM Outreach Center at [email protected] .

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• Dr. Junshan Lin receives a new NSF grant 06/17/2024
• Call for Distinguished Alumni Award (DAA) and Young Alumni Achievement Award (YAAA) Nominations 06/07/2024
• Timothy L. Hawthorne joins COSAM as new chair of the Department of Geosciences 05/31/2024
• Auburn alumnus bridges Auburn University and the National Renewable Energy Laboratory in DOE's Energy Earthshots Initiative 05/28/2024
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June 26, 2024

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New research shows that improving mobile internet service can reduce digital inequality

by Georgia Institute of Technology

New research shows removing data caps to cell phone usage may not only reduce digital inequality but might increase education data consumption by disadvantaged populations.

More than 90% of the U.S. population has internet access. However, many households , particularly those of low socioeconomic status, are "smartphone-dependent," meaning they rely purely on their smartphone for internet access. As a result, their connection may be unstable or slow, and they may be constrained by data caps that limit how much they can use the internet.

This puts them at a disadvantage compared to households with internet access through smartphones and other broadband connections at home and work, perpetuating digital inequality between disadvantaged and advantaged households.

The smartphone dependence of many disadvantaged households begs the question: If mobile internet service was better—e.g., if it was faster, more reliable, and/or didn't come with data constraints—could that reduce digital inequality and level the playing field? Researchers from the Georgia Tech Scheller College of Business and Southern Methodist University Cox School of Business studied this question and found the answer is "yes."

The research paper is forthcoming in Management Science and is available on the SSRN site.

Karthik Kannan, assistant professor of IT and Operations Management at the Cox School of Business and Georgia Tech Ph.D. graduate, led the project. "I was interested in the effect of data caps. For example, when you have 10GB of data per month and use more, you are charged extra, or your connection is throttled," said Kannan.

"So, I partnered with a large telecommunications provider to study what happens when their subscribers switched from capped to unlimited data plans. I was particularly interested in differences between high-income and low-income households."

Kannan, along with Eric Overby, Catherine and Edwin Wahlen Professor of Information Technology Management, and Sri Narasimhan, Gregory J. Owens Professor of Information Technology Management, at the Scheller College of Business, found that while all households increased their data use after switching to an unlimited plan, the increase was significantly larger for families of low socioeconomic status .

"That was our initial finding: that improving mobile internet service by removing the data cap had disproportionately large benefits for disadvantaged households," said Overby. "But that didn't mean much in and of itself. If those households weren't using the additional data for 'enriching' purposes like accessing educational, health care , or career-related data, the additional data consumption wouldn't translate into positive social benefits.

"Indeed, years of research on digital inequality have consistently shown a 'usage gap' in which advantaged households take fuller advantage of internet access improvements than disadvantaged households. The result is that internet improvements often exacerbate inequality. So, we dug deeper."

Specifically, the researchers leveraged the telecommunication provider's data categorization system to study changes in the consumption of educational data. They found that disadvantaged households experienced disproportionate increases in education data consumption (as well as in overall data consumption) after switching to unlimited mobile data.

Although advantaged households increased their education data consumption by approximately 15MB (or about three digital textbooks) per month after switching to unlimited data, disadvantaged households increased their education data consumption by approximately 24MB (or about five digital textbooks) per month.

"We can't be sure that these disproportionate increases in education data consumption will help disadvantaged households narrow gaps in educational outcomes. However, this is clearly a step in the right direction," said Kannan.

The research is directly relevant to the Federal Communications Commission's 2023 inquiry into the effects of data caps on disadvantaged households. Narasimhan explains, "Let's say that based on their inquiry, the FCC decides to limit the use of data caps. A logical question is: will that do any good? In other words, will disadvantaged households take advantage of their improved mobile internet service in a way that can reduce digital inequality? Prior to our research, we didn't really know. But based on our research, the answer is yes."

Journal information: Management Science

Provided by Georgia Institute of Technology

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What can polls tell us in 2024?

John lapinski, the robert a. fox leadership professor of political science and director of the robert a. fox leadership program and the penn program on opinion research and election studies, talks polling in this presidential election year..

If there is one thing Americans can count on during any presidential election year, it’s the constant commentary about polls. But how has polling changed in the digital age? How accurately can polls predict election outcomes? What purpose do they serve?

John Lapinski , the Robert A. Fox Leadership Professor of Political Science and director of the Robert A. Fox Leadership Program and the Penn Program on Opinion Research and Election Studies (PORES) , addresses these questions. Lapinski also directs the Elections Unit at NBC News, where he is responsible for projecting races for the network and producing election-related stories through exit polls.

“There have been misses with polling recently,” Lapinski admits. “Is it critically important that people have a sense of who may or may not win an election before election night? I don’t think so, but it is important, given that we live in an electoral democracy, that we have some way of measuring public opinion; otherwise, the people elected to represent us won’t know what we want.”

Lapinski notes that polling has changed dramatically over the decades. “We’ve seen big differences in response rates when using online methods versus telephone. There are differences in subgroups within a population, and it’s very pronounced with younger people,” he says.

“We’re doing a huge experiment right now at PORES, running five different surveys, including telephone interviews with both landline and cellphone interviews, a text survey, and two different online methods.”

In general, Lapinski says, polls can’t predict turnout. However, “one of the beautiful aspects of election polls is that you can determine whether they’re accurate or not because elections happen. Here’s what the poll said, here’s what the results said.”  

This year’s election, he adds, will be “super close.”

This story is by Jane Carroll. Read more at OMNIA .

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