74 research outputs found
Toward equity through participation in Modeling Instruction in introductory university physics
We report the results of a five year evaluation of the reform of introductory calculus-based physics by implementation of Modeling Instruction (MI) at Florida International University (FIU), a Hispanic-serving institution. MI is described in the context of FIUâs overall effort to enhance student participation in physics and science broadly. Our analysis of MI from a âparticipationistâ perspective on learning identifies aspects of MI including conceptually based instruction, culturally sensitive instruction, and cooperative group learning, which are consistent with research on supporting equitable learning and participation by students historically under-represented in physics (i.e., Black, Hispanic, women). This study uses markers of conceptual understanding as measured by the Force Concept Inventory (FCI) and odds of success as measured by the ratio of students completing introductory physics and earning a passing grade (i.e., Câ or better) by students historically under-represented in physics to reflect equity and participation in introductory physics. FCI pre and post scores for students in MI are compared with lecture-format taught students. Modeling Instruction students outperform students taught in lecture-format classes on post instruction FCI (61.9% vs 47.9%,
Linking engagement and performance: The social network analysis perspective
Theories developed by Tinto and Nora identify academic performance, learning
gains, and involvement in learning communities as significant facets of student
engagement that, in turn, support student persistence. Collaborative learning
environments, such as those employed in the Modeling Instruction introductory
physics course, provide structure for student engagement by encouraging
peer-to-peer interactions. Because of the inherently social nature of
collaborative learning, we examine student interactions in the classroom using
network analysis. We use centrality---a family of measures that quantify how
connected or "central" a particular student is within the classroom
network---to study student engagement longitudinally. Bootstrapped linear
regression modeling shows that students' centrality predicts future academic
performance over and above prior GPA for three out of four centrality measures
tested. In particular, we find that closeness centrality explains 28 % more of
the variance than prior GPA alone. These results confirm that student
engagement in the classroom is critical to supporting academic performance.
Furthermore, we find that this relationship for social interactions does not
emerge until the second half of the semester, suggesting that classroom
community develops over time in a meaningful way
Educational commitment and social networking: The power of informal networks
The lack of an engaging pedagogy and the highly competitive atmosphere in
introductory science courses tend to discourage students from pursuing science,
technology, engineering, and mathematics (STEM) majors. Once in a STEM field,
academic and social integration has been long thought to be important for
students' persistence. Yet, it is rarely investigated. In particular, the
relative impact of in-class and out-of-class interactions remains an open
issue. Here, we demonstrate that, surprisingly, for students whose grades fall
in the "middle of the pack," the out-of-class network is the most significant
predictor of persistence. To do so, we use logistic regression combined with
Akaike's information criterion to assess in- and out-of-class networks, grades,
and other factors. For students with grades at the very top (and bottom), final
grade, unsurprisingly, is the best predictor of persistence---these students
are likely already committed (or simply restricted from continuing) so they
persist (or drop out). For intermediate grades, though, only out-of-class
closeness---a measure of one's immersion in the network---helps predict
persistence. This does not negate the need for in-class ties. However, it
suggests that, in this cohort, only students that get past the convenient
in-class interactions and start forming strong bonds outside of class are or
become committed to their studies. Since many students are lost through
attrition, our results suggest practical routes for increasing students'
persistence in STEM majors.Comment: 12 pages, 2 figures, 8 tables, 6 pages of Supplementary Material
Classroom Reform with CMPLE: A Cogenerative Mediation Process for Learning Environments
We have designed a classroom goal setting process whereby students and instructors rank, discuss, and combine their learning preferences and then rate their classroom with respect to those preferences. All participants have the opportunity to be collectively engaged in building a preferred learning environment
Toward University Modeling InstructionâBiology: Adapting Curricular Frameworks from Physics to Biology
University Modeling Instruction (UMI) is an approach to curriculum and pedagogy that focuses instruction on engaging students in building, validating, and deploying scientific models. Modeling Instruction has been successfully implemented in both high school and university physics courses. Studies within the physics education research (PER) community have identified UMIâs positive impacts on learning gains, equity, attitudinal shifts, and self-efficacy. While the success of this pedagogical approach has been recognized within the physics community, the use of models and modeling practices is still being developed for biology. Drawing from the existing research on UMI in physics, we describe the theoretical foundations of UMI and how UMI can be adapted to include an emphasis on models and modeling for undergraduate introductory biology courses. In particular, we discuss our ongoing work to develop a framework for the first semester of a two-semester introductory biology course sequence by identifying the essential basic models for an introductory biology course sequence
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