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Abstract Identity development frameworks provide insight into why and to what extent individuals engage in STEM‐related activities. While studies of “STEM identity” often build off previously validated disciplinary and/or science identity frameworks, quantitative analyses of constructs that specifically measure STEM identity and its antecedents are scarce, making it challenging for researchers or practitioners to apply a measurement‐based perspective of participation in opportunities billed as “STEM.” In this study, we tested two expanded structural equation models of STEM identity development, building off extensions of science and disciplinary‐identity frameworks, that incorporated additional factors relevant to identity development: gender, ethnicity, home science support, parental education, and experiencing science talk in the home. Our models test theorized relationships between interest, sense of recognition, performance‐competence, and identity in the context of STEM with undergraduate students (N = 522) enrolled in introductory STEM courses at a Hispanic Serving Institution. Our findings support our measurement of STEM identity and its indicators, providing researchers with a predictive model associated with academic intentions across disciplinary domains in STEM. Further, our expanded model (i.e., Model I+) indicates significant contributions of participant gender, which has a larger indirect effect on STEM identity (β = 0.50) than the direct effect of STEM interest (β = 0.29), and of home support in relation to performance‐competence in academic contexts. Our model also posits a significant contribution of family science talk to sense of recognition as a STEM person, expanding our understandings of the important role of the home environment while challenging prior conceptions of science capital and habitus. We situate our results within a broader discussion regarding the validity of “STEM identity” as a concept and construct in the context of communities often marginalized in STEM fields.
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The Nuts and Bolts of Developing a Sustainable, Collaborative Network for STEM Transformation
Abstract The (STEM)2Network (Sustainable, Transformative Engagement across a Multi-Institution/Multidisciplinary STEM Network) is a National Science Foundation Research Coordination Network-Undergraduate Biology Education funded project intended to bridge disciplinary and institutional silos that function as barriers to systemic change in science, technology, engineering, and mathematics (STEM) in higher education. We utilized three foundational frameworks to develop an adaptable model that we posit is applicable across contexts. The model includes a core infrastructure that, combined with intentional self-reflection, results in an adaptable design that can be tailored to individual institutions, contexts, and goals. Herein, we describe the inception of the network, the foundational theoretical frameworks that guide network development and growth, and detail network structure and operations with the intention of supporting others in creating their own networks. We share the nuts and bolts of how we developed the (STEM)2Network, and include a supplemental network development planning guide to support others in utilizing the (STEM)2Network model to reach their own objectives.
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- Award ID(s):
- 2120495
- PAR ID:
- 10520269
- Publisher / Repository:
- Springer Science + Business Media
- Date Published:
- Journal Name:
- Innovative Higher Education
- Volume:
- 49
- Issue:
- 5
- ISSN:
- 0742-5627
- Format(s):
- Medium: X Size: p. 909-925
- Size(s):
- p. 909-925
- Sponsoring Org:
- National Science Foundation
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