JoinResearch & Teaching
Examining Perspectives of Teaching Among Biology Teaching Assistants
Journal of College Science Teaching—January/February 2022 (Volume 51, Issue 3)
By Joshua W. Reid and Emily G. Weigel
Recent reform efforts in postsecondary science teaching have called for shifts in instructional methods to include more evidence-based instructional practices. However, a myriad of factors play a role in whether an instructor adopts these more student-centered methods. One such factor is teaching perspective. In this study, we explored the teaching perspectives of both graduate and undergraduate teaching assistants (TAs), as well as shifts in their perspectives after participation in an active-learning professional development course. Findings from this study suggest that while undergraduate TAs hold more nurturing perspectives of teaching, graduate TAs hold more apprenticeship perspectives; both groups, however, can experience perspective change through professional development and teaching experience. These findings have implications for professional developers and those who work closely with TAs.
Recent reform efforts in postsecondary science teaching have called for shifts in instructional methods to include more evidence-based instructional practices. However, a myriad of factors play a role in whether an instructor adopts these more student-centered methods. One such factor is teaching perspective. In this study, we explored the teaching perspectives of both graduate and undergraduate teaching assistants (TAs), as well as shifts in their perspectives after participation in an active-learning professional development course.
Recent reform efforts in postsecondary science teaching have called for shifts in instructional methods to include more evidence-based instructional practices. However, a myriad of factors play a role in whether an instructor adopts these more student-centered methods. One such factor is teaching perspective. In this study, we explored the teaching perspectives of both graduate and undergraduate teaching assistants (TAs), as well as shifts in their perspectives after participation in an active-learning professional development course.
Research & Teaching
Integrated Concentration in Science
An Interdisciplinary Problem-Solving Program
Journal of College Science Teaching—January/February 2022 (Volume 51, Issue 3)
By Stephanie Purington and Martina Nieswandt
The Integrated Concentration in Science (iCons) 4-year program at the University of Massachusetts Amherst was designed to promote interdisciplinary STEM collaboration in the solution of real-world problems and encourage student independence and interdependence through a student-centered teaching approach that structures all projects as group endeavors. Researchers evaluated the first- and second-year courses to determine whether instructors implemented the student-driven curriculum as planned and how students perceived the courses with respect to pedagogy and collaboration experiences. Results of a mixed-methods study that included observations, interviews, and surveys showed that instructors implemented a student-centered approach as planned; provided help only when students asked for it or obviously needed scaffolded support; and answered most student queries with questions intended to promote discussion, research, and reframing. Students expressed satisfaction with the courses and felt their experiences aligned with their expectations of receiving more guidance than direct instruction. At the end of each course, students confirmed that they had, in fact, received good guidance, feedback, and critique from their instructors and little in the way of lectures. Students also expressed that their collaboration skills improved, especially in the areas of group communication and sharing their ideas.
The Integrated Concentration in Science (iCons) 4-year program at the University of Massachusetts Amherst was designed to promote interdisciplinary STEM collaboration in the solution of real-world problems and encourage student independence and interdependence through a student-centered teaching approach that structures all projects as group endeavors.
The Integrated Concentration in Science (iCons) 4-year program at the University of Massachusetts Amherst was designed to promote interdisciplinary STEM collaboration in the solution of real-world problems and encourage student independence and interdependence through a student-centered teaching approach that structures all projects as group endeavors.
Research & Teaching
E–6 Preservice Teachers and Elementary Science Teaching
Assessing Confidence and Content Knowledge
The study assessed the science teaching confidence of preservice teachers in teaching elementary science by addressing two research questions: (1) Did preservice teachers understand the science concepts well enough to be effective in teaching elementary science content? (2) Did preservice teachers have the necessary science concepts and skills to teach elementary science? The study used science content knowledge pre- and post-course tests and a validated science teaching efficacy belief instrument to answer the questions. The findings suggest that preservice teachers strongly agreed that they understood science content well enough to be effective in teaching elementary science content and were comfortable in teaching elementary science. Overall, content knowledge pre- and post-course tests indicated a statistically significant difference, suggesting that preservice teachers had necessary content knowledge to teach elementary science. As we would like to see 100% positive outcomes among preservice teachers regarding content knowledge and effective elementary science teaching, the study suggests that science methods courses should expose elementary preservice teachers to more physical science and Earth and space science content and activities.
The study assessed the science teaching confidence of preservice teachers in teaching elementary science by addressing two research questions: (1) Did preservice teachers understand the science concepts well enough to be effective in teaching elementary science content? (2) Did preservice teachers have the necessary science concepts and skills to teach elementary science? The study used science content knowledge pre- and post-course tests and a validated science teaching efficacy belief instrument to answer the questions.
The study assessed the science teaching confidence of preservice teachers in teaching elementary science by addressing two research questions: (1) Did preservice teachers understand the science concepts well enough to be effective in teaching elementary science content? (2) Did preservice teachers have the necessary science concepts and skills to teach elementary science? The study used science content knowledge pre- and post-course tests and a validated science teaching efficacy belief instrument to answer the questions.
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A Flipped Classroom Approach and Digital Learning in an Undergraduate Molecular Biology Course
Journal of College Science Teaching—January/February 2022 (Volume 51, Issue 3)
By Andreas Kakarougkas and Reham Abdellatif
Teaching modalities such as Flipped Classroom Approach (FCA) are becoming increasingly popular in higher education. FCA requires that instructional content is completed outside the classroom, thus allowing active-learning activities to take place in class. In this article, we investigate the application of this approach to an undergraduate molecular biology course. The instructional content was delivered using the MITx 7.28x Molecular Biology Series MOOC via the edX platform. Discussions, activities, group problem-solving, and quizzes were carried out in the classroom based on the instructional content covered online. To gain student feedback on the teaching approach, we performed a mid-semester focus group and a post-semester survey. Student interaction with the instructional content was collected via the edX platform’s edX Insights feature. Completion of the instructional content and thorough class preparation are important prerequisites for FCA. Data from the edX platform showed a high completion rate of the instructional content, despite student feedback that completing the online content was too time consuming. Students indicated that the topics, materials, and instructor made the experience engaging, which motivated them to complete the assigned materials. Overall, our results indicate that this teaching modality engages students, promotes active learning, and aids information retention.
Teaching modalities such as Flipped Classroom Approach (FCA) are becoming increasingly popular in higher education. FCA requires that instructional content is completed outside the classroom, thus allowing active-learning activities to take place in class. In this article, we investigate the application of this approach to an undergraduate molecular biology course. The instructional content was delivered using the MITx 7.28x Molecular Biology Series MOOC via the edX platform.
Teaching modalities such as Flipped Classroom Approach (FCA) are becoming increasingly popular in higher education. FCA requires that instructional content is completed outside the classroom, thus allowing active-learning activities to take place in class. In this article, we investigate the application of this approach to an undergraduate molecular biology course. The instructional content was delivered using the MITx 7.28x Molecular Biology Series MOOC via the edX platform.
FEATURE
Exploring the Effects of a Neglected Area
The United Nations Sustainable Development Goals in Science Education
Journal of College Science Teaching—January/February 2022 (Volume 51, Issue 3)
By Emma Tribble, Rohan Skariah, Emily Tran, and Ozcan Gulacar
One of the major challenges of teaching science has been engaging students in discussions of concepts due to lack of perceived relevancy of topics to students’ individual goals and societal issues. Science has been viewed as a set of abstract topics disconnected from the real world. To increase student motivation, self-efficacy, and interest in pursuing a degree in STEM fields, educators highlight the role of science in explaining environmental issues and generating potential solutions. One of our previous studies investigated the effect of learning about phosphate sustainability on general chemistry students’ perceptions of science relevancy. The positive outcomes encouraged our group to develop several comprehensive Prezi modules to introduce the United Nations Sustainable Development Goals (SDGs) in science classes and reveal their connections to the topics taught in schools. The overall objectives of this project are to suggest an effective and meaningful method to make science relevant to students, enhance their sustainability awareness, and encourage them to take actions to help the global community achieve the SDGs. In this article, we explain the contents and structures of the presentations and discuss their potential uses in science classrooms to improve students’ curiosity and engagement.
One of the major challenges of teaching science has been engaging students in discussions of concepts due to lack of perceived relevancy of topics to students’ individual goals and societal issues. Science has been viewed as a set of abstract topics disconnected from the real world. To increase student motivation, self-efficacy, and interest in pursuing a degree in STEM fields, educators highlight the role of science in explaining environmental issues and generating potential solutions.
One of the major challenges of teaching science has been engaging students in discussions of concepts due to lack of perceived relevancy of topics to students’ individual goals and societal issues. Science has been viewed as a set of abstract topics disconnected from the real world. To increase student motivation, self-efficacy, and interest in pursuing a degree in STEM fields, educators highlight the role of science in explaining environmental issues and generating potential solutions.
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Gender Inequities Throughout STEM
Journal of College Science Teaching—January/February 2022 (Volume 51, Issue 3)
By Alexandru Maries, Kyle Whitcomb, and Chandralekha Singh
Efforts to promote equity and inclusion using evidence-based approaches are vital to correcting long-standing societal inequities that have disadvantaged women and discouraged them from pursuing studies, including in many STEM disciplines. We used 10 years of institutional data from a large public university to investigate the grade point average trends in different STEM disciplines for men and women who declared a major and then either completed the degree or dropped the major after declaring it. We found alarming trends, such as that women who dropped majors on average earned higher grades than men, and in some STEM majors, women who dropped the majors were earning comparable grades to men who persisted in those majors. While these quantitative findings call for a deeper understanding of the reasons women and men drop a major, we provide suggestions for approaches to make learning environments more equitable and inclusive so traditionally excluded groups can have a higher sense of belonging and thrive.
Efforts to promote equity and inclusion using evidence-based approaches are vital to correcting long-standing societal inequities that have disadvantaged women and discouraged them from pursuing studies, including in many STEM disciplines. We used 10 years of institutional data from a large public university to investigate the grade point average trends in different STEM disciplines for men and women who declared a major and then either completed the degree or dropped the major after declaring it.
Efforts to promote equity and inclusion using evidence-based approaches are vital to correcting long-standing societal inequities that have disadvantaged women and discouraged them from pursuing studies, including in many STEM disciplines. We used 10 years of institutional data from a large public university to investigate the grade point average trends in different STEM disciplines for men and women who declared a major and then either completed the degree or dropped the major after declaring it.
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From Balancing Redox Reactions to Determining Change of Oxidation Numbers
Journal of College Science Teaching—January/February 2022 (Volume 51, Issue 3)
By Pong Kau Yuen and Cheng Man Diana Lau
Redox reaction is a core concept in teaching and learning chemistry. This article explores a new method for balancing organic redox reactions that requires the balancing of both atoms and charges. The H+, O, H2O, and e– are used as balanced vehicles in two half reactions. A non-oxidation number approach can be applied to both molecular and ionic equations. The article also provides standard operating procedures and examples. The number of transferred electrons is first determined by balancing a half redox reaction; consequently; the change of oxidation numbers can be calculated. The mathematical equation of Te– = n Te– = n ΔON is established, and the change of oxidation numbers (ΔON) can be counted by the number of transferred electrons (Te–) and the number of atoms with oxidation numbers change (n). By using this mathematical equation as a new approach, students can conveniently calculate the change of mean oxidation numbers for an assigned atom in a half redox reaction.
Redox reaction is a core concept in teaching and learning chemistry. This article explores a new method for balancing organic redox reactions that requires the balancing of both atoms and charges. The H+, O, H2O, and e– are used as balanced vehicles in two half reactions. A non-oxidation number approach can be applied to both molecular and ionic equations. The article also provides standard operating procedures and examples.
Redox reaction is a core concept in teaching and learning chemistry. This article explores a new method for balancing organic redox reactions that requires the balancing of both atoms and charges. The H+, O, H2O, and e– are used as balanced vehicles in two half reactions. A non-oxidation number approach can be applied to both molecular and ionic equations. The article also provides standard operating procedures and examples.
special section
Using an Instructional Team During Pandemic Remote Teaching Enhanced Student Outcomes in a Large STEM Course
Journal of College Science Teaching—January/February 2022 (Volume 51, Issue 3)
By Susan D. Hester, Jordan M. Elliott, Lindsey K. Navis, L. Tori Hidalgo, Young Ae Kim, Paul Blowers, Lisa K. Elfring, Karie L. Lattimore, and Vicente Talanquer
The unplanned shift to online instruction due to the COVID-19 pandemic challenged many instructors teaching large-enrollment courses to design learning environments that actively engaged all students. We looked at how one instructor used her instructional team—a group of student assistants with diverse, structured responsibilities—to adapt her large-enrollment (>500 students) introductory chemistry course to a live-remote format, as well as the impact the team’s involvement had on students’ reported experiences of online learning. We found that the instructional team’s involvement was instrumental in adapting the course to the live-remote online format. The integration of the instructional team had a significant positive impact on students’ experiences in the course, including their perceptions of social and cognitive engagement and teacher presence. Students in the section with the integrated instructional team also outperformed students in other sections of the same course on standardized course exams and final course grade. These results suggest that a structured instructional team composed of students can be a mechanism for promoting positive student experiences and learning in large-enrollment, remote STEM courses.
The unplanned shift to online instruction due to the COVID-19 pandemic challenged many instructors teaching large-enrollment courses to design learning environments that actively engaged all students. We looked at how one instructor used her instructional team—a group of student assistants with diverse, structured responsibilities—to adapt her large-enrollment (>500 students) introductory chemistry course to a live-remote format, as well as the impact the team’s involvement had on students’ reported experiences of online learning.
The unplanned shift to online instruction due to the COVID-19 pandemic challenged many instructors teaching large-enrollment courses to design learning environments that actively engaged all students. We looked at how one instructor used her instructional team—a group of student assistants with diverse, structured responsibilities—to adapt her large-enrollment (>500 students) introductory chemistry course to a live-remote format, as well as the impact the team’s involvement had on students’ reported experiences of online learning.
special section
Addressing the COVID-19 Pandemic in Introductory Psychology Using the Jigsaw Method Adapted for Remote Learning
Journal of College Science Teaching—January/February 2022 (Volume 51, Issue 3)
By Monica Kim Ngan Thieu, John C. Foo, and Caroline B. Marvin
People’s ability to evaluate scientific research is important to dealing with the COVID-19 pandemic. STEM educators can use the pandemic to frame instruction of scientific literacy and critical-thinking skills. In a small pilot introductory psychology course taught online in spring 2021, we created jigsaw-style modules organized around real-world applications of psychological research in which students applied results from empirical papers to address current issues and integrated their findings into group projects. In this article, we discuss a module focusing on how children’s development might be impacted by different COVID-19 pandemic school opening policies. We found that students successfully applied empirical results to inform approaches to public policy. Our experience can offer guidance to future STEM instructors incorporating current events into course content to support student learning in a virtual learning environment.
People’s ability to evaluate scientific research is important to dealing with the COVID-19 pandemic. STEM educators can use the pandemic to frame instruction of scientific literacy and critical-thinking skills. In a small pilot introductory psychology course taught online in spring 2021, we created jigsaw-style modules organized around real-world applications of psychological research in which students applied results from empirical papers to address current issues and integrated their findings into group projects.
People’s ability to evaluate scientific research is important to dealing with the COVID-19 pandemic. STEM educators can use the pandemic to frame instruction of scientific literacy and critical-thinking skills. In a small pilot introductory psychology course taught online in spring 2021, we created jigsaw-style modules organized around real-world applications of psychological research in which students applied results from empirical papers to address current issues and integrated their findings into group projects.
From the Field: Events and Opportunities, January 25, 2022
By Debra Shapiro
