The nebulous relationship between mathematics and computation in education has led to questions surrounding computational science students’ experiences in mathematics courses. However, many of these conversations are framed in terms of students’ misconceptions or their ‘poor mathematical skills’. In contrast, I propose leveraging student’s computational strengths as a pedagogical approach for creating relevant and engaging mathematics experiences. In order to build an understanding of the ways in which computation affects student’s experience and understanding of mathematics, I adapted a framework designed to link student’s computational experiences and attitudes by adding explicit linkage to these mathematical experiences. Then I developed a series of Jupyter notebooks focused on introducing linear algebra through computing. This study followed computational science students as they worked through the modules in small groups across six weeks. They completed weekly reflections, and pre/post-study interviews. The theoretical framework was operationalized as an analytical framework to link student experience and attitudes. Results highlighted the shift in students’ views of the nature of mathematics, their abilities, and the interplay between disciplines. The computational environment enabled students to naturally consider multiple solution paths, develop resilience, and enhanced their ability to explore mathematical concepts in a novel way. This was in contrast with students’ initial views that framed mathematics as a set series of steps and formulas to follow. This study both provides a novel perspective in the discourse surrounding research on computational students’ experiences in mathematics and highlights the pedagogical power of computing as a novel environment for learning mathematics.

Sarah is a current PhD candidate in PRIME (Program for Mathematics Education) at MSU and a mathematics master’s student. She earned her bachelor’s degrees in Mathematics and Engineering Physics from Whitworth University. During this time her research projects were at the intersection of mathematics, engineering, and computation, including modeling biological fluid shifts in microgravity and evaluating electric propulsion systems for asteroid and comet sample-return missions. Sarah continued this research at Princeton in the Mechanical and Aerospace Engineering program before turning to mathematics education research. Her passion is twofold. First, her work explores the structural inequities within undergraduate STEM education at all levels and ways to critically explore these in an ongoing effort to pursue equity. Secondly, she is passionate about exploring how computation enacted through coding in undergraduate mathematics classrooms can bring about deeper understandings of mathematical structures and develop mathematical creativity. Her most recent project focuses on introducing CMSE 201 students to linear algebra through a series of modules in Jupyter Notebooks and the relation with mathematical creativity.