This award is funded in part under the American Rescue Plan Act of 2021 (Public Law 117-2).
This project will create the specification for a learner-controlled system to represent youth learning in Out-of-School-Time (OST) settings, to improve access to future Science, Technology, Engineering, and Mathematics (STEM) learning opportunities. For learners to pursue a STEM education, and STEM careers, they must be able to move through "gatekeeping" mechanisms that filter and sort students based on factors such as prior coursework and grades, teacher recommendations, and language proficiency assessments. Even though abundant evidence shows that such measures fail to capture all important aspects of STEM learning, they are traditionally relied upon in secondary and post-secondary STEM education contexts as indicators of preparation for future STEM learning. These systemic processes exclude certain minoritized groups, including Black, Indigenous, and other people of color (BIPOC), low income, immigrant and refugee youth, and youth learning English, from high-quality secondary and post-secondary STEM learning experiences because existing measures do not validate their prior knowledge and experiences. Yet, minoritized youth often engage in OST STEM learning opportunities, where their readiness for future learning opportunities is nurtured and valued. One challenge is to reliably document this readiness in a usable format so youth can access new STEM learning opportunities, especially in post-secondary contexts. This project builds strategically upon earlier work focusing on the democratization of STEM learning through vehicles such as digital micro-credentials or badges, and upon digital portfolios. Missing from these earlier efforts was integration of these platforms with an infrastructure that connected youth learners to OST STEM learning organizations and to future STEM learning opportunities. This Innovations in Development project brings together minoritized youth and their families, OST providers, and admissions officials from higher education institutions to explore the needed design features for OST "transcripts," and user stories that describe how software systems can support their creation and sharing. Grounded in the concept of mastery-based learning, where learning is demonstrated via action, learners will control what is included in the transcript so that they create their own narratives about their learning experiences. Recognizing that documentation is not the key focus of most STEM OST organizations, this project will provide direct support for identifying and codifying learning goals or outcomes that learners and their families find relevant and important within different STEM activities. This project is funded by the Advancing Informal STEM Learning (AISL) program which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments.
The project will take a Design-Based Implementation Research (DBIR) approach and proceed by convening representatives from three main stakeholder groups (youth and their families, OST providers, and admissions staff) to engage in a series of discovery and design activities. Project partners, including the Mastery Transcript Consortium (MA), STEAMville (IL), STUDIO (WA), and Wolverine Pathways (MI), will work together with the PIs to design templates learners can use to characterize STEM learning from each provider, aligned with different STEM learning foci (e.g., computer science, computational thinking, cross-cutting concepts, science and engineering practices, and mathematics). Data collected from these sessions will be used to address the following research questions: (1) How and why do youth and families from minoritized communities understand and choose to participate in STEM OST learning opportunities?, (2) How do youth understand and interact with STEM OST learning opportunities?, (3) How do OST providers characterize the STEM learning goals in the activities they provide?, and (4) How do college admissions personnel view the role of informal STEM learning as part of a holistic admissions process? This work has the potential to further the understanding of how OST learning can be documented and shared as a part of the larger ecosystem of STEM learning trajectories. By deeply engaging the perspectives and voices of minoritized youth and families, this project seeks to develop a valid and trustworthy instrument that recognizes and serves their STEM learning, thus broadening the participation of minoritized youth in STEM education and careers. This work will also benefit OST providers, by translating the documentation of youth STEM learning into forms that may help communicate the efficacy of their programs in ways that further their missions, including communicating evidence of effectiveness to both future participants and funders.
Research shows that algebra is a major barrier to student success, enthusiasm and participation in STEM for under-represented students, particularly African-American students in under-resourced high schools. Programs that develop ways to help students master algebra concepts and a belief that they can perform algebra may lead to more students entering engineering careers. This project will provide an online engineering program to support 9th and 10th grade Baltimore City Public Schools students, a predominantly low-income African-American cohort, to develop concrete goals of becoming engineers. The goals of the program are to help students with a growing interest in engineering to maintain that interest throughout high school. The project will also support students aspire to an engineering career. The project will develop in students an appreciation of requisite courses and skills, and increase self-efficacy in mathematics. The project will also develop a replicable model of informal education capable of reinforcing the mathematical foundations that students learn during the school day. Additionally, the project will broaden participation in engineering by being available to students during out-of-school time and by having relaxed entrance criteria compared to existing opportunities in supplemental engineering curricula. The project is a collaboration between the Baltimore City Public Schools, Johns Hopkins University Applied Physics Laboratory, Northrop Grumman Corporation, and Expanded School-Based Mental Health programs to support students both during and after participation. The project will benefit society by providing skills that will allow high school students to become members of tomorrow's highly trained STEM workforce.
The research will test whether an informal, scaffolded online algebra-for-engineering program increases students' mastery and self-efficacy in mathematics. The research will advance knowledge regarding informal education by applying Social Cognitive Career Theory as a framework for measuring program impact. The theoretical framework will aid in identifying mechanisms through which students with interest in engineering might persist in maintaining this interest through high school via algebra skill mastery and increased self-efficacy. The project will recruit 200 youth from the Baltimore City Public Schools to participate in the project over three years. Qualitative data will be collected to assess how student and school socioeconomic factors impact implementation, student engagement, and outcomes. The research will answer the following questions: 1) What effect does program participation have on math mastery? 2) What direct and indirect effects do program completion and supports have on students' mathematics self-efficacy? 3) What direct and indirect effects do program components have on engineering career goals by the end of the program? 4) What direct and indirect effects does math self-efficacy have on career goals? 5) To what extent are the effects of program participation on engineering career goals mediated by math self-efficacy and engineering interest? 6) How do school factors relate to the implementation of the program? 7) What socioeconomic-related factors relate to the regularity and continuation of student participation in the program? The quantitative methods of data analysis will employ descriptive and multivariate statistical methods. Qualitative data from interviews will be analyzed using an emergent approach and a coding scheme guided by theoretical constructs. Project results will be communicated to scholars and practitioners. The team will also share information through school newsletters and parent communication through Baltimore City Public Schools.
This project is funded by the Innovative Technology Experiences for Students and Teachers (ITEST) program, which supports projects that build understandings of practices, program elements, contexts and processes contributing to increasing students' knowledge and interest in science, technology, engineering, and mathematics (STEM) and information and communication technology (ICT) careers.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
Many of the Hispanic children and families who live in the Rio Grande Valley lack opportunities to engage in inspirational and educational experiences introducing Science, Technology, Engineering and Mathematics (STEM) concepts and related careers. The University of Texas, Rio Grande Valley (UTRGV) will adapt and research the "Energy and U Show," which will introduce thousands of children and families to an exciting and dramatic that shows interconverting different forms of energy. The show will meld the excitement of chemical demonstrations and the natural connection between energy and STEM education in a fully produced, on-stage science extravaganza. A foundational philosophy of the show is that there is additional real value in getting children and youth onto a college campus. For many of its participants, this is their first time sitting in a seat at a university, the first opportunity for them to envision themselves in this environment. In partnership with the University of Minnesota, which originally developed the show, UTRGV will adapt the show, now presented in English, to a bilingual, culturally accessible format that is designed to Hispanic family audiences and student groups in learning about energy and related careers. Evaluation results demonstrate that the show has effectively engaged thousands of Minnesota students. The target audience will be upper elementary (4th-5th grade), middle school students, and their parents. This project will be led by UTRGV, nation's second-largest Hispanic Serving Institution, with a student enrollment of 28,000, of which over 90% are Hispanic and more than 60% are first-generation college students). In addition to the show, the project will include: (1) a manual to guide implementation of the program and related resources at different national or international venues; (2) educational resources for parents, teachers and school counselors introducing STEM careers and specific STEM college majors; (3) mentoring of UTRGV faculty in outreach activities; and (4) dissemination of the show to other campuses and venues.
The project will conduct ongoing research and evaluation guiding the adaptation of the show and investigation of factors contributing to positive educational impacts of the project, which will be carried out by a bilingual/bicultural researcher. Project research instruments will measure student level of engagement, interest and learning, as well as college interest, in surveys and analysis of data pre and post demonstration. The project will specifically investigate the impact of language on student impacts. Each component of this project will be studied to determine program intervention effectiveness (the scientific demonstration and language of the demonstration). To determine program effectiveness, a baseline of data before program implementation will be established concerning Hispanic students, their persistence, and perceptions of the environment. The project will measure parent perceptions of STEM careers for their children through pre and post demonstration surveys and focus groups. Student and parent research participants will be able to use surveys or respond to other research activities in the language of their choice. Project findings will contribute to the knowledge base concerning how linguistically and culturally adapted science shows and related resources adapted into can have positive impacts regarding the STEM knowledge and careers of students and parents from low-income and Hispanic communities.
This project is funded by the National Science Foundation's (NSF's) Advancing Informal STEM Learning (AISL) program, which supports innovative research, approaches, and resources for use in a variety of learning settings.
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TEAM MEMBERS:
Karen LozanoArturo FuentesAaron MassariBrian Warren
Since 1992, the WSU Math Corps, a combined mathematics and mentoring program, has worked to make a difference in the lives of Detroit’s children—providing them with the love and support that all kids need in the moment, while empowering them with the kinds of educational opportunities and sense of purpose, that hold the promise of good lives for themselves and a better world for all.
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TEAM MEMBERS:
Steve KahnStephen ChrisomalisTodd KubicaCarol Philips-BeyFrancisca Richter
Improving retention rates in postsecondary engineering degree programs is the single most effective approach for addressing the national shortage of skilled engineers. Both mathematics course placement and performance are strong graduation predictors in engineering, even after controlling for demographic characteristics. Underrepresented students (e.g., rural students, low-income students, first-generation students, and students of color) are disproportionately represented in cohorts that enter engineering programs not yet calculus-ready. Frequently, the time and cost of obtaining an engineering degree is increased, and the likelihood of obtaining the degree is also reduced. This educational problem is particularly acute for African American students who attended select high schools in South Carolina, with extremely high-poverty rates. As a result, the investigators proposed an NSF INCLUDES Launch Pilot project to develop a statewide consortium in South Carolina - comprising all of the public four-year institutions with ABET-approved engineering degree programs, all of the technical colleges, and 118 high schools with 70% or higher poverty rates, to pinpoint and address the barriers that prevent these students from being calculus ready in engineering.
This NSF INCLUDES Launch Pilot project will map completion/attrition pathways of students by collecting robust cross-sectional data to identify and understand the complex linkages between and behind critical decisions. Such data have not been available to this extent, especially focused on diverse populations. Further, by developing structural equation models (SEMs), the investigators will be able to build on extant research, contributing directly to understanding the relative impact of a range of latent variables on the development of engineering identity, particularly among African American, rural, low-income, and first-generation engineering students. Results of the pilot interventions are likely to contribute to the empirical and theoretical literature that focus on engineering persistence among underrepresented populations. Project plans also include developing a centralized database compatible to the Multiple Institution Database for Investigation of Engineering Longitudinal Development (MIDFIELD) project to share institutional data with K-12 and postsecondary administrators, engineering educators, and education researchers with NSF INCLUDES projects and beyond.
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TEAM MEMBERS:
Anand GramopadhyeDerek BrownEliza GallagherKristin Frady
The University of New Hampshire (UNH) NSF INCLUDES Design and Development Launch Pilot project is a collaborative effort with the Community College System of New Hampshire, Advanced Manufacturing (AM) businesses, NH Economic Development, and the University of New Hampshire to address workforce development in the Advanced Manufacturing sector in the state. The Advanced Manufacturing Program (AMP) uses a framework built on the Collective Impact collaboration model that enables AMP partners to innovate, plan, and implement strategies that significantly increase NH's community colleges (CC) as a source for future workers and leaders in AM.
Specifically, this proposal addresses the pressing need for increasing numbers of AM workers through strategies designed to increase the retention of low socioeconomic status (LSES) students in CC STEM degree programs. AMP coordinates four key implementation strategies: 1) Co-requisite remediation within mathematics and quantitative reasoning; 2) Guided Pathways mentorship with "high touch" advising and student guidance resources that combines clearly defined academic pathways leading to 4-year college transfer and job placement; 3) paid work-based learning (WBL) experiences in industry and academic research; and 4) mentor inclusiveness training to prepare the workplace and academic settings to receive LSES students into a supportive climate. Successfully coordinating these four components through the process of Collective Impact collaboration will lead to a flexible and integrated AM workforce pipeline that serves CC AM students, AM industry partners, and the state as a whole. Findings will be disseminated to academic, business, and government stakeholders in NH, the region, and nationally to inform and improve broadening participation initiatives.
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TEAM MEMBERS:
Palligarnai VasudevanStephen HaleBrad KinseyLeslie BarberMelissa Aikens
The Sustainability Teams Empower and Amplify Membership in STEM (S-TEAMS), an NSF INCLUDES Design and Development Launch Pilot project, will tackle the problem of persistent underrepresentation by low-income, minority, and women students in STEM disciplines and careers through transdisciplinary teamwork. As science is increasingly done in teams, collaborations bring diversity to research. Diverse interactions can support critical thinking, problem-solving, and is a priority among STEM disciplines. By exploring a set of individual contributors that can be effect change through collective impact, this project will explore alternative approaches to broadly enhance diversity in STEM, such as sense of community and perceived program benefit. The S-TEAMS project relies on the use of sustainability as the organizing frame for the deployment of learning communities (teams) that engage deeply with active learning. Studies on the issue of underrepresentation often cite a feeling of isolation and lack of academically supportive networks with other students like themselves as major reasons for a disinclination to pursue education and careers in STEM, even as the numbers of underrepresented groups are increasing in colleges and universities across the country. The growth of sustainability science provides an excellent opportunity to include students from underrepresented groups in supportive teams working together on problems that require expertise in multiple disciplines. Participating students will develop professional skills and strengthen STEM- and sustainability-specific skills through real-world experience in problem solving and team science. Ultimately this project is expected to help increase the number of qualified professionals in the field of sustainability and the number of minorities in the STEM professions.
While there is certainly a clear need to improve engagement and retention of underrepresented groups across the entire spectrum of STEM education - from K-12 through graduate education, and on through career choices - the explicit focus here is on the undergraduate piece of this critical issue. This approach to teamwork makes STEM socialization integral to the active learning process. Five-member transdisciplinary teams, from disciplines such as biology, chemistry, computer and information sciences, geography, geology, mathematics, physics, and sustainability science, will work together for ten weeks in summer 2018 on real-world projects with corporations, government organizations, and nongovernment organizations. Sustainability teams with low participation by underrepresented groups will be compared to those with high representation to gather insights regarding individual and collective engagement, productivity, and ongoing interest in STEM. Such insights will be used to scale up the effort through partnership with New Jersey Higher Education Partnership for Sustainability (NJHEPS).
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TEAM MEMBERS:
Amy TuiningaAshwani VasishthPankaj Lai
The Broadening Experience for Scientific Training: Beginning Enhancement Track ("BEST-BET"), an NSF INCLUDES Design and Development Launch Pilot project, draws upon the expertise of five research-intensive institutions that have developed innovative programing in career and professional development for doctoral and postdoctoral trainees in biomedical research. The goal of the project is to expand the scope and leverage the work so as to engage students earlier in their career exploration. Specifically, the project will target undergraduates who may not be aware of the multitude of career options available to them. These include opportunities in academia, the biotechnology and pharmaceutical industries, science communication, science policy, and technology transfer/patent law. The effort will focus on undergraduates who come from populations generally underrepresented in STEM fields, including but not limited to ethnically, racially and socioeconomically underserved communities. The grant will support educational opportunities for students at minority-serving institutions and will assess the impact of providing new opportunities to this community. The critical contributions of a diverse and inclusive community are essential to progress in all STEM fields. By promoting diversity in education, this project aims to engage undergraduate students at a point in their professional development that could enable participation in a wide range of workforce opportunities so as to advance the progress of science and national health.
The focus of BEST BET will be to use a collective impact framework to connect the "BEST network" of institutions to partners engaged in undergraduate education of students from underrepresented communities who are interested in the life sciences. The underlying premise is that career exploration focused on opportunities that go beyond physician training will enable engagement of this community of learners in the life science workforce beyond the pre-med track and keep them engaged in degree completion. Multiple strategies will be used to attain the goals of BEST BET. They are organized in the context of two major objectives roughly divided into the scope of planned activities. The first objective focuses on "career exploration" and offers strategies to assist partner institutions to build career and skill development capacities. The second is grounded in an enhanced experience of BEST site visits whereby undergraduates will have the opportunity to envision life as a graduate student and beyond. These strategies will likely enhance persistence to complete the baccalaureate degree and move onto doctoral programs.
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TEAM MEMBERS:
Linda Hyman
resourceprojectProfessional Development, Conferences, and Networks
The NSF INCLUDES program supports models, networks, partnerships and research to ensure the broadening participation in STEM of women, members of racial and ethnic groups that have been historically underrepresented, persons of low socio-economic status, and people with disabilities.
The Algebra Project, in partnership with the Young People's Project, will convene a conference on inclusion in science, technology, engineering and mathematics(STEM) higher education in support of the National Science Foundation's Inclusion across the Nation of Communities of Learners of Underrepresented Discoverers in Engineering and Science (NSF INCLUDES) initiative. The conference will examine a critical question: What roles and structures are needed for a mini-backbone organization in order to scale a "bottom up" model of social change into an organized, full scale collective impact model? Additionally, the conference will develop participants' capacity to link action on the various design challenges, and backbone structures, to future actions that meet the needs of a potential Alliance on this Broadening Participation Challenge and others facing similar challenges.
Five pre-conference design teams will focus on key components to improve education of students from underrepresented and disadvantaged populations over a four-month period prior to the convening of the stakeholders in St. Louis, Missouri in 2017.
Community colleges play a vital role in educating undergraduate students. These higher education institutions educate nearly half of the nation's undergraduate students, particularly among low-income and first-generation students and students of color. Because of the rich diversity that currently exists at these institutional-types, there are immense opportunities to broadening participation throughout the engineering enterprise. To this end, the investigator outlines a joint collaboration with five community colleges, three school systems, two college career academies, and a state partner in Georgia - referred as the Georgia Science, Technology, and Engineering Partnerships for Success (GA STEPS) - to provide dual enrollment classes in career pathways for Georgia high school students in grades 9-12, thereby allowing secondary students to earn college credit. The Georgia STEPS program proposes to leverage mechatronics engineering as a means for broadening engineering participation for community colleges and underserved, underrepresented populations in 48 rural counties to increase engineering awareness, skills training and college and career readiness. The project builds on an existing collaboration that has developed successful engineering opportunities at the community college level, by including a wider regional network of rural Georgia counties and high schools. Further, this project has immense potential to transform engineering education and course-taking for students at the secondary and postsecondary level in Georgia and beyond. It has potential great potential to be scaled and replicated at other placed around the United States.
The project's intellectual merit and innovation is that it leverages a successful mechatronics engineering curriculum that supports engineering skills that support local industry as well as supporting innovations in the mechatronics field. The project includes a collective impact framework, involving various stakeholders and aligning quantitative and qualitative metrics and measurable objectives. The broader impacts of this project is that it increases the engineering knowledge and skills of underserved, underrepresented students that are enrolled in community colleges. Also, the impact to rural communities in Georgia support the fact that this project would meet broader groups that can be positively impacted by this type of collaborative. The ability to provide different parts of this engineering discipline across broad audiences in community colleges - that support underrepresented groups understanding of mechatronics engineering - is broadly useful to the field of engineering.
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. This includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants. This project will develop and test intergenerational science media resources for parents that are participating in adult education programs and their young children. The materials will build on the research-based and successful children's television program, Fetch with Ruff Ruffman. The target audience includes parents enrolled in adult education programs who lack a high school diploma or are in English as a Second Language classes. These resources will support parents' engagement in science activities with their children both in the adult education settings as well as at home. Adult and family educators will receive professional development resources and training to support their integration of the parent/child activities. Project partners include the National Center for Families Learning, Kentucky Educational Television, and Alabama Public Television,
The goals of the Ruff Family Science project are to: (1) investigate adult education settings that feature an intergenerational learning model, in order to learn about the unique characteristics of adults and families who are enrolled in these programs; (2) examine the institutional circumstances and educator practices that support joint parent/child engagement in science; (3) iteratively develop new prototype resources meet the priorities and needs of families and educators involved in intergenerational education settings; and (4) develop the knowledge needed to create a fuller set of materials in the future that will motivate and support diverse, low-income parents to investigate science with their children. The research strategy is comprised of three main components: Phase 1: Needs Assessment: Determine key motivations and behaviors common to adult education students who are also parents; surface obstacles and assets inherent in these parents' current practices; and examine the needs and available resources for supplementing parents' current engagement in family science learning. Phase 2: Prototype Development: Iteratively develop two prototype Activity Sets, along with related educator supports and training materials, designed to promote joint parent-child engagement with English and Spanish-speaking families around physical science concepts. Phase 3: Prototype Field Test: Test how the two refined prototype Activity Sets work in different educational settings (adult education, parent education, and parent and child together time). Explore factors that support or impede effective implementation. Sources of data for the study include observations of adult and parent education classes using an expert interview protocol, focus groups, adult and family educator interviews, and parent surveys.