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1. Broadening equity through recruitment: Pre-college STEM program recruitment in literature and practice.

   Delale-O'Connor, L.; A. Allen; M. Ball; D. N. Boone; R. Gonda, J; Iriti; Slinskey Legg, A. (January 2021, Connected science learning)

   The National Science Foundation (2019) points to Black, Hispanic/Latino, American Indian, Alaskan Native, Native Hawaiian and other Pacific Island peoples as underrepresented in science, technology, engineering and math (STEM) college majors and professional pathways. This underrepresentation results from an interplay of representation and process, meaning that it in part results from STEM opportunities and programming that do not reflect the experiences of racially and ethnically diverse people, offer insight into the needs of diverse communities, nor address barriers that prevent participation (McGee 2020). One way that institutions of higher education (IHEs) and community organizations try to address inequities in STEM is through pre-college programs aimed at supporting racially and ethnically minoritized (REM) youth. These pre-college STEM programs (PCSPs) work to foster increased STEM awareness and support students in achieving academic milestones that make college pathways more viable. Out-of-school learning (OSL) and informal STEM programming have the potential to fill gaps in STEM K–12 education, as well as complement and support connections with K–12 STEM by offering REM youth opportunities to connect STEM with their lives and influence both their capabilities and dispositions toward STEM (Kitchen et al. 2018). Studies have pointed to positive connections between OSL STEM participation and outcomes such as high school graduation, sustained interest in STEM, and matriculation to university (Penuel, Clark, and Bevan 2016). PCSPs may also support IHE’s development of infrastructure to increase admissions of REM students into college STEM programs. For PCSPs to be an effective element of reducing inequities in STEM, they must successfully engage with and recruit REM youth to participate. In this article, we focus on the recruitment of REM youth into STEM OSL to better understand what is effective for REM youth and their families, as well as highlight connections between OSL and in-school STEM opportunities. Our goals in this work are to (1) identify program practices with the aim of broadening STEM educational and career pathways for REM youth and (2) support strengthened pathways between STEM in K–12 schools and IHEs. 

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2. Enhancing the Success of Minority STEM Students by Providing Financial, Academic, Social, and Cultural Capital

   Enriquez, A. G.; Lipe, C. B.; Price, B. (June 2017, ASEE annual conference & exposition)

   Research has shown that student achievement is influenced by their access to, or possession of, various forms of capital. These forms of capital include financial capital, academic capital (prior academic preparation and access to academic support services), cultural capital (the attitudes, knowledge, and behaviors related to education which students are exposed to by members of their family or community), and social capital (the resources students have access to as a result of being members of groups or networks). For community college students, many with high financial need and the first in their families to go to college (especially those from underrepresented minority groups), developing programs to increase access to these various forms of capital is critical to their success. This paper describes how a small federally designated Hispanic-serving community college has developed a scholarship program for financially needy community college students intending to transfer to a four-year institution to pursue a bachelor’s degree in a STEM field. Developed through a National Science Foundation Scholarships in Science, Technology, Engineering, and Mathematics (S-STEM) grant, the program involves a collaboration among STEM faculty, college staff, administrators, student organizations, and partners in industry, four-year institutions, local high schools, and professional organizations. In addition to providing financial support through the scholarships, student access to academic capital is increased through an intensive math review program, tutoring, study groups, supplemental instruction, and research internship opportunities. Access to cultural and social capital is increased by providing scholars with faculty mentors; engaging students with STEM faculty, university researchers, and industry professionals through field trips, summer internships, professional organizations, and student clubs; supporting student and faculty participation at professional conferences, and providing opportunities for students and their families to interact with faculty and staff. The paper details the development of the program, and its impact over the last five years on enhancing the success of STEM students as determined from data on student participation in various program activities, student attitudinal and self-efficacy surveys, and academic performance including persistence, retention, transfer and graduation. 

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3. Effective inclusion practices for neurodiverse children and adolescents in informal STEM learning: a systematic review protocol

   https://doi.org/10.1186/s13643-023-02278-2  

   Jenson, Ronda J.; Lee, Michele S; Day, Arden D.; Hughes, Amy E.; Maroushek, Emma E.; Roberts, Kelly D. (December 2023, Systematic Reviews)

   Abstract Background Informal learning experiences in science, technology, engineering, and math (STEM) can enhance STEM learning that occurs in formal educational settings and curricula as well as generate enthusiasm for considering STEM careers. The aim of this systematic review is to focus on the experiences of neurodiverse students in informal STEM learning. Neurodiversity is a subgroup of neurodevelopmental conditions, such as autism, attention deficit disorder, dyslexia, dyspraxia, and other neurological conditions. The neurodiversity movement regards these conditions as natural forms of human variation, as opposed to dysfunction, and recognizes that neurodiverse individuals possess many strengths relevant to STEM fields. Methods The authors will systematically search electronic databases for relevant research and evaluation articles addressing informal STEM learning for K-12 children and youth with neurodiverse conditions. Seven databases and content-relevant websites (e.g., informalscience.org) will be searched using a predetermined search strategy and retrieved articles will be screened by two members of the research team. Data synthesis will include meta-synthesis techniques, depending on the designs of the studies. Discussion The synthesis of the findings resulting from various research and evaluation designs, across the K-12 age span, and across various informal STEM learning contexts, will lead to depth and breadth of understanding of ways to improve informal STEM learning programs for neurodiverse children and youth. The identification of informal STEM learning program components and contexts shown to yield positive results will provide specific recommendations for improving inclusiveness, accessibility, and STEM learning for neurodiverse children and youth. Trial registration The current study has been registered in PROSPERO. Registration number: CRD42021278618. 

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4. Partnering to Develop a Coordinated Engineering Education Program Across Schools, Museum Field Trips, and Afterschool Programs

   Harlow, D. (January 2020, Connected science learning)

   Engineering Explorations are curriculum modules that engage children across contexts in learning about science and engineering. We used them to leverage multiple education sectors (K–12 schools, museums, higher education, and afterschool programs) across a community to provide engineering learning experiences for youth, while increasing local teachers’ capacity to deliver high-quality engineering learning opportunities that align with school standards. Focusing on multiple partners that serve youth in the same community provides opportunities for long-term collaborations and programs developed in response to local needs. In a significant shift from earlier sets of standards, the Next Generation Science Standards include engineering design, with the goal of providing students with a foundation “to better engage in and aspire to solve the major societal and environmental challenges they will face in decades ahead” (NGSS Lead States 2013, Appendix I). Including engineering in K–12 standards is a positive step forward in introducing students to engineering; however, K–12 teachers are not prepared to facilitate high-quality engineering activities. Research has consistently shown that elementary teachers are not confident in teaching science, especially physical science, and generally have little knowledge of engineering (Trygstad 2013). K–12 teachers, therefore, will need support. Our goal was to create a program that took advantage of the varied resources across a STEM (science, technology, engineering, and math) education ecosystem to support engineering instruction for youth across multiple contexts, while building the capacity of educators and meeting the needs of each organization. Specifically, we developed mutually reinforcing classroom and field trip activities to improve student learning and a curriculum to improve teacher learning. This challenging task required expertise in school-based standards, engineering education, informal education, teacher professional development, and classroom and museum contexts. 

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5. Usable STEM knowledge for tomorrow's STEM problems

   https://doi.org/10.56367/OAG-037-10193  

   Butler Songer, Nancy (January 2023, Open Access Government)

   Usable STEM knowledge for tomorrow's STEM problems More universities and education programs need more STEM knowledge in formal and informal settings to guide learners in applying STEM learning to the creation of solutions. To address this challenge, Nancy Butler Songer, the dean of the College of Education at the University of Utah designed a learning approach, Solutioning, that guides youth to deepen science content through science and engineering practices. Creating a six-week curricular program, the learning approach provided opportunities for students to use engineering design to create and provide feedback on a trap design that would attract a local invasive insect that was harmful to their community. Research was conducted on studies to provide empirical evidence on student STEM knowledge and learning and their ability to define science and engineering. Research results indicate that even elementary-age students demonstrate significant improvement in their understanding of STEM arguments as evaluated with a pre-post assessment before and after implementing a six-week solutioning curricular program. 

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