Conference
Betul Bilgin, James W Pellegrino, Cody Wade Mischel, Lewis E Wedgewood
2022 ASEE Annual Conference & Exposition, ASEE, 2022 Aug 23
2022 ASEE Annual Conference & Exposition, ASEE, 2022 Aug 23
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APA
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Bilgin, B., Pellegrino, J. W., Mischel, C. W., & Wedgewood, L. E. (2022). Developing Professional Identity: Integrating Academic and Workplace Competencies within Engineering Programs. In 2022 ASEE Annual Conference & Exposition. ASEE.
Chicago/Turabian
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Bilgin, Betul, James W Pellegrino, Cody Wade Mischel, and Lewis E Wedgewood. “Developing Professional Identity: Integrating Academic and Workplace Competencies within Engineering Programs.” In 2022 ASEE Annual Conference &Amp; Exposition. ASEE, 2022.
MLA
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Bilgin, Betul, et al. “Developing Professional Identity: Integrating Academic and Workplace Competencies within Engineering Programs.” 2022 ASEE Annual Conference &Amp; Exposition, ASEE, 2022.
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@conference{betul2022a,
title = {Developing Professional Identity: Integrating Academic and Workplace Competencies within Engineering Programs},
year = {2022},
month = aug,
day = {23},
journal = {2022 ASEE Annual Conference & Exposition},
publisher = {ASEE},
author = {Bilgin, Betul and Pellegrino, James W and Mischel, Cody Wade and Wedgewood, Lewis E},
month_numeric = {8}
}
Chemical engineering education needs a new rational approach commensurate with the evolution and expansion it has undergone via the inclusion of key elements from several fields: pharmaceuticals, renewable energy, biotechnology, and food and consumer products, among others. With the expansion of industry and growing needs for communication and leadership skills in the 21st century, practicing engineers are expected to be technically knowledgeable and professionally skillful. However, the typical chemical engineering undergraduate core curriculum has not adapted to prepare students for the multiple needs encompassed by the chemical industry. Lack of industry-relevant examples/topics and applications in the course contents results in less motivated and/or engaged students. Students therefore often struggle to identify with the profession and are not ready for the workforce when they graduate. This NSF PFE: RIEF project examines a unique experience where a student-faculty-industry integrated community is created to help bridge the gap between industry needs and the competencies developed within chemical engineering programs.
The project's main goal is to better understand how implementing up-to-date industry problems into one of the sophomore chemical engineering courses impacts students’ engineering identity formation and self-efficacy development. To analyze the impacts of the intervention, this project employs design-based research (DBR) approach to guide the development, implementation, and evaluation of materials and methods reflecting the proposed synergistic model for a course and program design. Implementing up-to-date industry-relevant problems into the course will foster student-industry-faculty engagement (PI, engineering Co-PI, and course instructor), develop student knowledge, skills, and abilities needed in the chemical engineering world today and in the future, and support professional identity formation. Moreover, industry-student engagement through the methods proposed 2 will develop students' societal and environmental awareness. This paper provides findings from Spring 2021 that will be presented in the National Science Foundation (NSF) Grantees Poster Session during the 2022 ASEE Annual Conference & Exposition.
The project's main goal is to better understand how implementing up-to-date industry problems into one of the sophomore chemical engineering courses impacts students’ engineering identity formation and self-efficacy development. To analyze the impacts of the intervention, this project employs design-based research (DBR) approach to guide the development, implementation, and evaluation of materials and methods reflecting the proposed synergistic model for a course and program design. Implementing up-to-date industry-relevant problems into the course will foster student-industry-faculty engagement (PI, engineering Co-PI, and course instructor), develop student knowledge, skills, and abilities needed in the chemical engineering world today and in the future, and support professional identity formation. Moreover, industry-student engagement through the methods proposed 2 will develop students' societal and environmental awareness. This paper provides findings from Spring 2021 that will be presented in the National Science Foundation (NSF) Grantees Poster Session during the 2022 ASEE Annual Conference & Exposition.
