Purpose and Research Questions

The aim of the Motivating Students in Computer Science project is to study factors that affect students motivation in undergraduate and graduate computer science courses. The projects began in Fall 2019 and have researched questions such as:

— How do students’ perceptions of the motivational climate in courses vary by gender, race/ethnicity, and major?

— How can instructors and teaching assistants create motivational climates that are inclusive and equitable for all students?

— What interventions are effective in training teaching assistants how to best help undergraduate students?

— To what extent do students’ perceptions of the motivational climate in courses predict their effort and achievement?

— How do students’ perceptions of the motivational climate vary across face-to-face, online, and hybrid courses?

— What factors predict whether students remain in or drop out of computer science courses?

Theoretical Framework

Based on the research of motivation scientists, one of the basic premises of our research is that instructors and teaching assistants (TAs) can create an inclusive and equitable motivational climate by designing courses that consider students’ perceptions of the five MUSIC model components, as shown in the figure. We’ve focused on students’ perceptions of Success and Caring, and supported these by creating an Interesting/enjoyable environment in which students feel eMpowered to solve Useful problems.

Project to Train Computer Science TAs to Motivate Students

— Based on our NSF IUSE grant (# 2315574) titled Training Computer Science Teaching Assistants to Motivate Students, we are creating materials that we’re using to train computer science TAs at Virginia Tech.

— Here’s a link to our project, with some of our materials.

News

— News Article: MUSIC for TAs: Increasing engagement within computer science, in the classroom and beyond

— A cool doodle of our training!

Publications

Jones, B. D., Ellis, M. O., & Kim, I. (2025, July 30). Training teaching assistants to create a positive motivational climate. American Association for the Advancement of Science. https://aaas-iuse.org/training-teaching-assistants-to-create-a-positive-motivational-climate/

Ellis, M., Jones, B. D., Gu, F., & Fenerci, H. (2024). Designing an effective motivational climate: Effects on students’ effort and achievement. International Journal for the Scholarship of Teaching and Learning, 18(1), Article 9. https://digitalcommons.georgiasouthern.edu/ij-sotl/vol18/iss1/9

Jones, B. D., Ellis, M., Gu, F., & Fenerci, H. (2023). Motivational climate predicts effort and achievement in a large computer science course: Examining differences across sexes, races/ethnicities, and academic majors. International Journal of STEM Education, 10, Article 65. https://doi.org/10.1186/s40594-023-00457-0

Presentations

Jones, B. D., Zhu, X., Ellis, M., Fenerci, H., & Ambarkutuk, Z. (2023, August). Relationships between course motivational climate and students’ computer science beliefs and goals. Research to be presented at the annual convention of the American Psychological Association, Washington DC.

Ellis, M., Jones, B. D., Fenerci, H, & McCarty. (2023, June). Assessing the motivational climate in computer science courses to improve instruction. Research presented at the Illinois Computer Science Summer Teaching Workshop, Illinois University, virtual meeting.

Fenerci, H., Kaplan, A., Jones, B. D., & Ellis, M. (2023, April). Challenges in capturing motivational climate as a complex dynamic system: Application with the MUSIC Model of Motivation. Research presented at the annual meeting of the American Educational Research Association, Chicago, IL.

Jones, B. D., Ellis, M., Gu, F., & Fenerci, H. (2023, April). Course perceptions predict effort and achievement in an engineering course: Comparing genders, ethnicities, and majors. Paper presented at the annual meeting of the American Educational Research Association, Chicago, IL.

Ellis, M., Jones, B. D., Fenerci, H., & Gu, F. (2023, February). Differences in motivational climate in face-to-face, online, and hybrid courses. Research presented at the Conference on Higher Education  Pedagogy, Blacksburg, VA.

— Students’ effort and achievement was higher in online and hybrid courses, and the motivational climate was the same or better than face-to-face courses.

Ellis, M., Jones, B. D., Fenerci-Soysal, H., & Gu, F. (2022, May). Redesigning a computer science course during the pandemic: Effects on students’ motivation and achievement. Presentation at the Pandemic Pedagogy Research Symposium 2022, Duke University, virtual meeting.

— The findings indicate that with careful planning, a first-year computer science and engineering course can be successfully transitioned from face-to-face to online and then to hybrid. Students were more motivated and learned more with the new hybrid course design.

Research Team at Virginia Tech

The research team is comprised of several faculty and students, including: Margaret Ellis, Brett Jones, Hande Fenerci, Inyoung Kim, Xiao Zhu, Jenni Gallagher, Saylor Bane, Zeynep Ambarkutuk

Shown above: Researchers and project leaders Margaret Ellis and Brett Jones, faculty members at Virginia Tech

Funding

Our research has been funded by the National Science Foundation and the Virginia Tech Pathways Grant Program through the Office of Undergraduate Education.

— Jones, B. D. (PI, 40%), Ellis, M. (Co-PI, 40%), Kim, I. (Co-PI, 20%). (August 1, 2023 to July 31, 2025; NSF Award #IUSE-2315574). Training Computer Science Teaching Assistants to Motivate Students. National Science Foundation, $399,592.

— Jones, B. D. (Co-PI, 50%), & Ellis, M. (Co-PI, 50%). (2022). Redesigning Computer Science Courses to Motivate and Retain Students. Pathways Grant Program, $10,000.