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1. The impact of a multimodal professional network on developing social capital and research capacity of faculty at historically black colleges and universities

   https://doi.org/10.1007/s10639-022-11464-z  

   Ives, Jillian; Drayton, Brian; Hobbs, Kathryn; Falk, Joni (December 2022, Education and Information Technologies)

   Abstract This qualitative case study examined how a multimodal professional network environment (STEM for all Video Showcase) affected five STEM educational researchers’ capacity to engage in grant funded research at U.S. Historically Black Colleges and Universities (HBCUs). Guided by the social capital and professional network literature as a conceptual framework, we analyzed data from surveys, interviews, and online discussion posts. We aimed to understand HBCU-based researchers’ supports and barriers in writing and/or conducting grant funded research in STEM education, and ways in which the multimodal professional network experience supported their research and professional networking, if at all. We found that organizational structures shaped participants’ social capital as well as their grant funded research activities. Further, participating in a multimodal professional network enabled participants to further develop their research capacity and to also expand their collegial networks. We offer recommendations for institutions to support the research endeavors of their faculty and suggest ways in which organizations using or developing professional multimodal networks can enhance faculty research development. 

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2. Barriers to collecting student participation and completion data for a national STEM education grant program in the United States: a multiple case study

   https://doi.org/10.1186/s40594-022-00348-w  

   Ruhf, Robert J.; Williams, Cody T.; Zelinsky, Megan; Becho, Lyssa Wilson (December 2022, International Journal of STEM Education)

   Abstract Background Billions of dollars are spent annually on grant-funded STEM (science, technology, engineering, and mathematics) education programs. These programs help students stay on track toward STEM careers when standard educational practices do not adequately prepare them for these careers. It is important to know that reliable and accurate student participation and completion data are being collected about these programs. This multiple case study investigates how student data are collected and reported for a national STEM education program in the United States, the National Science Foundation (NSF) Advanced Technological Education (ATE) program. Our overall aim is to provide insights to funding agencies, STEM education faculty, and others who are interested in addressing issues related to the collection and reporting of student participation and completion data within their own contexts. Emphasis is placed on the barriers encountered in collecting participation and completion data, particularly with regard to unduplicated participation counts and marketable credential data. The ATE program was selected for this study because there is already a mechanism (known as the ATE Survey) in place for annually collecting systematic data across all projects within the program. Results A multiple case study, including interviews of primary investigators, allowed for in-depth analysis of the ATE Survey’s point-in-time data on project-level participation in various activities, and for identification of the following barriers to tracking student-level data: lack of time and help to gather these data, lack of a consistent system for tracking students across different institutions, and a perceived lack of guidance from the funding agency about what data to track. We also saw that different data are needed from different projects to determine a project’s true impact. Defining “success” the same way across all projects is inadequate. Conclusions Although, due to the limited sample size, these findings cannot be generalized to the larger ATE population, they provide specific insights into the various barriers that projects encounter in collecting participation and completion data. 

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3. Gidakiimanaanawigamig’s Circle of Learning: A Model for Partnership between Tribal Community and Research University

   https://doi.org/10.24926/ijps.v4i3.176  

   Dalbotten, Diana M; Ito, Emi; Eriksson, Susan; Pellerin, Holly; Greensky, Lowana; Kowalczak, Courtney; Berthelote, Antony (October 2017, Interdisciplinary Journal of Partnership)

   Since 2002, the National Center for Earth-Surface dynamics has collaborated with the Fond du Lac Band of Lake Superior Chippewa, the Fond du Lac Tribal and Community College, the University of Minnesota, and other partner institutions to develop programs aimed at supporting Native American participation in science, technology, engineering, and mathematics (STEM) fields, and especially in the Earth and Environmental Sciences. These include the gidakiimanaaniwigamig math and science camps for students in kindergarten through 12th grade, the Research Experience for Undergraduates on Sustainable Land and Water Resources, which takes place on two native reservations, and support for new majors at tribal colleges. All of these programs have a common focus on collaboration with communities, place-based education, community-inspired research projects, a focus on traditional culture and language, and resource management on reservations. Strong partnerships between university, tribal college, and Native American reservation were a foundation for success, but took time and effort to develop. This paper explores steps towards effective partnerships that support student success in STEM via environmental education. 

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4. Work in Progress – The Development of a K-12 Integrated STEM Observation Protocol.

   Roehrig, G.H; Ring-Whalen, E.A.; Wieselmann, J.R.; Dare, E.A.; Ellis, J.A. (January 2019, ASEE Annual Conference proceedings)

   This WIP presentation is intended to share and gather feedback on the development of an observation protocol for K-12 integrated STEM instruction, the STEM-OP. Specifically, the STEM-OP is being developed for use in K-12 science and/or engineering settings where integrated STEM instruction takes place. While the importance of integrated STEM education is established through national policy documents, there remains disagreement on models and effective approaches for integrated STEM instruction. Our broad definition of integrated STEM includes the use of two or more STEM disciplines to solve a real-world problem or design challenge that supports student development of 21st century skills. This issue is confounded by the lack of observation protocols sensitive to integrated STEM teaching and learning that can be used to inform research of the effectiveness of new models and strategies. Existing instruments most commonly used by researchers, such as the Reformed Teaching Observation Protocol (RTOP), were designed prior to the development of the Next Generation Science Standards and the integration of engineering into science standards. These instruments were also designed for use in reform-based science classrooms, not engineering or integrated STEM learning environments. While engineering-focused observation protocols do exist for K-12 classrooms, they do not evaluate beyond an engineering focus, making them limited tools to evaluate integrated STEM instruction. In order to facilitate the implementation of integrated STEM in K-12 classrooms and the development of the nascent integrated STEM education literature, our research team is developing a new integrated STEM observation protocol for use in K-12 science and engineering classrooms. This valid and reliable instrument will be designed for use in a variety of educational contexts and by different education stakeholders to increase the quality of K-12 STEM education. At the end of this project, the STEM-OP will be made available through an online platform that will include an embedded training program to facilitate its broad use. In the first year of this four-year project, we are working on the initial development of the STEM-OP through video analysis and exploratory factor analysis. We are utilizing existing classroom video from a previous project with approximately 2,000 unique classroom videos representing a variety of grade levels (4-9), science content (life, earth, and physical science), engineering design challenges, and school demographics (urban, suburban). The development of the STEM-OP is guided by published frameworks that focus on providing quality K-12 integrated STEM and engineering education, such as the Framework for Quality K-12 Engineering Education. Our anticipated results at the time the ASEE meeting will include a review of our item development process and finalized items included on the draft STEM-OP. Additionally, we anticipate being able to share findings from the exploratory factor analysis (EFA) on our video-coded data, which will identify distinct instructional dimensions responsible for integrated STEM instruction. We value the opportunity to gather feedback from the engineering education community as the integration of engineering design and practices is integral to quality integrated STEM instruction. 

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5. How Constructivist Learning Impact Middle-School Girls’ STEM Career Interests

   Xu, Y; Zhang, S; Yang, M; Muthukumar, V (April 2024, AERA 2024)

   This study collected data from a five-week summer camp that provided programming workshops and engineering-based group activities to girls in grades 6-11. The camp was part of the actions designed to increase girls’, especially minorities’, participation in computer science and engineering. All activities were designed to ensure that learning took place in a constructivist environment. With the collection and analyses of survey data, the objective of this study is to examine whether and how a constructivist learning environment impacted adolescent girls’ STEM interests beyond their gains in STEM knowledge and self-efficacy. 

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