The ChemAttitudes project recieved supplemental funding to create materials for train-the-trainer workshops in order to inoculate the chemistry outreach community with members who have the knowledge and resources to train others on strategies for stimulating interest, sense of relevance, and feelings of self-efficacy that were tested in the earlier work of the project. The project team recruited participants from minority serving professional organizations as a strategy for broadening participation. Can it work? Did it work?
This poster was presented at the 2021 NSF AISL Awardee Meeting.
This poster was presented at the 2021 National Science Foundation (NSF) Advancing Informal STEM Learning (AISL) Awardee Meeting.
The goal of this two-year project is to examine systemic issues within learning spaces and provide educators with anti-racist approaches that validate and uplift Black learners. Through a combination of media, educator and role model professional development, and intentional outreach, Black SciGirls will create more gender-equitable and anti-racist informal STEM learning environments for Black girls.
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TEAM MEMBERS:
Rita KarlAdrienne StephensonLataisia JonesRonda Taylor BullockAngel Miles NashJohnavae Campbell
The U.S. Fish and Wildlife Service estimates that over 41 million people connect to nature through birding. Learning about birds in their natural environments offers opportunities for informal engagement in STEM by a broad range of individuals and groups. Birders often engage in scientific data gathering and analyses, geolocation and remote sensing, and phenology. They also become aware of ecological changes in bird habitats and migratory patterns due to rising temperatures and climate-related events like sea level rise, droughts, fires, and extreme weather. As such, the birding community is an ideal network to better understand and communicate the impacts of climatological changes on bird populations to the public. With this Innovations in Development project, the National Audubon Society will develop a new avian-focused, conservation and climate science community science curriculum for its Nature Centers, and test the effectiveness of the curriculum in educating the public about avian-focused conservation and climatological changes through guided nature experiences. Birding can serve as a pivotal entrée for young people into STEM fields and careers. Through its programs and partnerships, Audubon will leverage its national network to ensure that through this project a more diverse group of voices, particularly young adults and young adults of color, become involved in asking critical questions and developing solutions to address important environmental issues of the future. If successful, the broader impacts of this project on capacity building and public engagement could be far-reaching and long-lasting.
Over the three-year project duration, Audubon will bring educators from its nationwide network of thirty-four Nature Centers (including urban, suburban, and rural sites), together with over 510 young adults (ages 18-25) from its network of college campus chapters. An evidence-based curriculum and community science activities will be created and tested, relying heavily on a team of experts in ornithology, climate science research, STEM curriculum design, diversity, and informal science education. College students will advise on the design of content and activities to effectively interest and engage young adults. These students will be recruited from the new Audubon Campus Chapters Program, which includes 111 college and university campuses, among them, 19 Historically Black Colleges and Universities (HBCUs) and other Minority Serving Institutions (MSIs). The target population will be surveyed to also understand their current and likely participation in guided nature experiences and knowledge base in climate science. Current best practices in guided nature experiences will be gathered from across the Audubon network. The implementation efforts will result in a national STEM model, with train-the-trainer guides and workshops for informal science educators and public engagement opportunities focused on improving the state and condition of avian habitats and communities through climate science research. An external evaluation will be conducted and will include data collection methods such as retrospective pre and post surveys, semi-structured interviews, focus groups, and an embedded assessment to determine impact. The findings will be used to iteratively refine the evidence-based curriculum and measure STEM learning outcomes for the guided nature experience participants. The evaluation will address four areas: (1) fidelity of program implementation to promote accountability; (2) formative evaluation to understand needs and interests of young adults (ages 18-25), and subsequently inform program design; (3) outcomes for Center educators, to inform iterative improvement; and (4) outcomes for program participants, to contribute to the growing knowledge base on effective practices for STEM learning in informal settings.
This Innovations in Development 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. 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 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.
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TEAM MEMBERS:
Loren SmithMark ScallionHeather Starck
In this article I critically examine the historical context of science education in a natural history museum and its relevance to using museum resources to teach science today. I begin with a discussion of the historical display of race and its relevance to my practice of using the Museum’s resources to teach science. I continue with a critical review of the history of the education department in a natural history museum to demonstrate the historical constitution of current practices of the education department. Using sociocultural constructs around identity formation and transformation, I
In our efforts to sustain U.S. productivity and economic strength, underrepresented minorities (URM) (for the purpose of this paper defined as persons of African American, Hispanic American, and Native American racial/ethnic descent), provide an untapped reservoir of talent that could be used to fill technical jobs. Over the past 25 years, educational diversity programs have encouraged and supported URM pursuing STEM degrees. Yet, their representation in STEM still lags far behind that of White, non-Hispanic men.
To understand the reasons why this is occurring, the American Association for
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TEAM MEMBERS:
Yolanda S. GeorgeVirginia Van HorneShirley M. Malcom
resourceprojectProfessional Development, Conferences, and Networks
Project SYSTEMIC (A Systems Thinking Approach to STEM Ecosystem Development in Chicago) will apply systems thinking to a community-level STEM ecosystem development effort in one of Chicago's largest and most distressed neighborhoods. The project aims to broaden participation of African American and low-income Chicago Public School students (preK-12) in STEM learning opportunities. The proposed model of collaborative change for this project builds on the work of two coordinated collective impact initiatives--the Chicago STEM Pathways Cooperative and Austin Coming Together, a network of local organizations committed to improving educational and economic outcomes for the community. A key feature of this project is that it adds innovative, interactive, visual problem structuring and solving strategies to highlight and uncover the systemic interdependencies that contribute to the BP challenge for African American youth. The project will convene a series of workshops to engage community stakeholders in the mapping of the STEM ecosystem. A broad and representative cross-section of community stakeholders will design and develop evidence-based STEM ecosystem organizing and implementation strategies. Key outcomes anticipated from this project are the development of a shared understanding, agenda, activities, and commitment to collectively address the underlying challenges of STEM access and participation for African American youth. The goal of this community-driven project is to develop a viable system model that elevates neighborhood voices, historically excluded from the problem-solving table and decision-making processes, to leverage existing assets, build local capacity, increase messaging and awareness of the value of STEM, identify needed new programs, and develop coordination/resource sharing mechanisms across partners to support implementation. The evaluation of this project will be grounded in systems thinking and culturally-responsive approaches that seek to understand the diverse perspectives of stakeholders while measuring progress toward project goals. Evaluation data will be used to assess the problem structuring process, to evaluate the organizational strategy designed to address the structured problem, and to support adaptive learning among stakeholders.
This is an "Inclusion across the Nation of Communities of Learners of Underrepresented Discoverers in Engineering and Science" (INCLUDES) Design and Development Launch Pilot that will implement a plan to assess the feasibility of a strategy designed to ensure high levels of improvement in K-12 grade students' mathematics achievement. The plan will focus on an often-neglected group of students--those who have been performing at the lowest quartile on state tests of mathematics, including African American, Hispanic, Native American, students with disabilities, and those segregated in urban and rural communities across the country. The project will draw on lessons learned from the nation's Civil Rights Movement and a community-organizing strategy learned during the struggle to achieve voting rights for African Americans. The Algebra Project (AP) is a national, nonprofit organization that uses mathematics as an organizing tool to ensure quality public school education for every child in America; it believes that every child has a right to a quality education to succeed in this technology-based society. AP's unique approach to school reform intentionally develops sustainable, student-centered models by building coalitions of stakeholders within the local communities, particularly the historically underserved populations. The AP works to change the deeply rooted social attitudes that encourage the disenfranchisement of a third of the nation's population. It delivers a multi-pronged approach to build demand for and support of quality public schools, including research and development, school development, and community development education reform efforts through K-12 initiatives.
The Algebra Project and the Young People's Project (YPP) will join efforts to bring together over 70 individuals and organizations, including 17 universities of which 8 are Historical Black Colleges and Universities, school districts, mathematics educators, and researchers to examine their experiences, and use collective learning to refine and hone strategies that they have piloted and tested to promote mathematics inclusion. The role of YPP in the proposed project will be to organize and facilitate the youth component, such that project activities reflect the language and culture of students, continuously leveraging and building upon their voice, creative input, and ongoing feedback. YPP will conduct workshops for students organized around math-based games that provide collective experiences in which student learning requires individual reflection, small group work, teamwork and discussion. The proposed work will comprise the design of effective learning opportunities; building and supporting a cadre of teachers who can effectively work with students learning under the proposed approach; using technologies to enhance teaching and learning; and utilizing evaluation and research to drive continuous improvement. Because bringing together an effective network with diverse expertise to collaborate towards national impact requires expert facilitation processes, the project will establish working groups around three major principles: (1) Organizing from the bottom up through students, their teachers, and others in local communities committed to their education, allied with individuals and organizations who have expertise and dedication for achieving the stated goals, can produce significant progress and the conditions for collective impact; (2) Effective learning materials and formal and informal learning opportunities in mathematics can be designed and implemented for students performing in the bottom academic quartile; and (3) Teachers and other educators can become more proficient and more confident in their capacity to produce students who are successful in learning the level of mathematics required for full participation in STEM. The working groups will also be tasked to consider two cross-cutting topics: (a) the communication structures and technologies needed to operate and expand the present network, and to create the "backbone" and other structures needed to operate and expand the network; and (b) the measurements and metrics for major needs, such as assessing students' mathematics literacy, socio-emotional development in specified areas; teachers' competencies; as well as the work of the network. The final product of this plan will be a "Theory of Collective Action and Strategic Plan". The plan will contain recommendations for collective actions needed in order for the current network to coordinate, add appropriate partners, develop the needed backbone structures, and become an NSF Alliance for national impact on the broadening participation challenge of improving the mathematics achievement. An external evaluator will conduct both formative and summative aspects of this process.
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TEAM MEMBERS:
Robert MosesNell CobbGregory BudzbanMaisha MosesWilliam Crombie
The Mississippi Alliance for Women in Computing (MAWC) project will identify factors that influence and motivate female students and female African American students in Mississippi to enroll and persist in an undergraduate engineering- or science-based computing major. There is a particular need for programming that is inclusive of women and women of color who are from the southern region of the United States. These students typically have less access to extracurricular activities that encourage computing, and are less likely to visualize themselves in a computing major or career. This proposed research is to help girls to know that computer science exists and what jobs in computer science are available with a degree in computer science. A rich environment exists in Mississippi for an alliance focused on building co-curricular and mentorship opportunities. A scalable pipeline model, expandable to a Southern Alliance for Women in Computing (SAWC), will be developed with three major objectives: to attract women and women of color to computing, to improve retention rates of women in undergraduate computing majors, and to help postsecondary women make the transition to the computing workforce. Activities to support these objectives include: scaling the National Center for Women and Information Technology Aspirations in Computing award program in Mississippi, expanding scholarships for Aspirations winners, expanding student-led computing outreach programs, establishing a Mississippi Black Girls Code chapter, informing and collaborating with the Computer Science for Mississippi initiative, creating a summer bridge and living-learning community for women in computing majors, and increasing professional development opportunities for women in computing through conferences, lunch and learn meetings, job shadowing, and internships.
The project will analyze whether the co-curricular activities of MAWC lead to computing self-efficacy and ultimately female students selecting to pursue and persist in computing majors and careers. In order to understand student participation and efficacy changes, data collection for this research will be through demographic and background surveys administered to women entering an undergraduate engineering- or science-based computing major at a university in Mississippi and student surveys and evaluations in MAWC-sponsored programs. Using discriminate analysis methods, specific research questions to be addressed are: 1) Which pre-collegiate experiences influenced them to enroll, 2) Which stakeholders influenced these girls in their decision-making process, and 3) What programs are effective in impacting their persistence in the major. Predictor variables for each respective research question are: pre-collegiate experiences, stakeholders, and programs. Outcome variables are: (a) a female undergraduate student with no involvement with MAWC programming, (b) MAWC activity participant, or (c) a MAWC participant having graduated with a bachelor?s degree in a STEM major. Results will complement published longitudinal research on the gendered and raced dimensions of computing literacy acquisition in Mississippi as well as research on effective CS role model programming.
NASA’s Science Mission Directorate (SMD) explores the Earth, the Sun, our solar system, the galaxy and beyond through four SMD divisions: Earth Science, Heliophysics, Planetary Science and Astrophysics. Alongside NASA scientists, teams of education and public outreach (EPO) specialists develop and implement programs and resources that are designed to inspire and educate students, teachers, and the public about NASA science.
In the United States, African Americans are underrepresented in science careers and underserved in pre-collegiate science education. This project engaged African American elementary students in culturally relevant science education through archaeology and thereby increased positive dispositions toward science. While imagining what the lives of their ancestors were like, students practiced scientific inquiry and used natural sciences to analyze archaeological sites. The project helped to improve science literacy among African American elementary students through archaeological inquiry and
Techbridge has proposed a broad implementation project that will scale up a tested multi-faceted model that increases girls' interest in STEM careers. The objectives of this project are to increase girls' engineering, technology, and science skills and career interests; build STEM capacity and sustainability across communities; enhance STEM and career exploration for underrepresented girls and their families; and advance research on the scale-up, sustainability, and impact of the model with career exploration. The Techbridge approach is grounded in Eccles' expectancy value model, and helps bridge critical junctures as girls transition from elementary to middle school and middle school to high school, immersing participants in a network of peers and supportive adults. Techbridge targets girls in grades 5-12 with a model that includes five components: a previously tested and evaluated curriculum, career exploration, professional development for staff and teachers, family engagement, and dissemination. The inquiry-based curriculum introduces electrical engineering and computer science through engaging, hands-on units on Cars and Engines, Green Design, and Electrical Engineering. The Techbridge model will be enhanced to include a central repository for curriculum and support materials, electronic girl-driven career exploration resources, an online learning community and video tools for staff, and customized family guides. Project deliverables include the dissemination of the enhanced model to three cities, 24 school sites and teachers, 2,000 girls, and over 600 role models. A supplementary research component will study the broad implementation of the Techbridge model by examining the fidelity of implementation and the program's impact on girls' STEM engagement and learning. The research questions are as follows: (1) To what extent and how do new program sites demonstrate adherence to the Techbridge program model? (2) Do new sites experience similar or increased participant responsiveness to Techbridge programming with regard to scientific learning outcomes, career awareness, attitude and interest in engineering? (3)How are changes experienced by girls sustained over time, if at all? (4) To what extent and how do new sites balance instilling the Techbridge essentials, those critical components Techbridge identifies as essential for success, with the need for local adaptation and ownership of the program? and (5) Given the potential for customization in local communities, do new sites maintain programmatic quality of delivery experienced at the original site? If so, what are elements essential to success regarding quality delivery? The mixed-methods study will include document analysis, embedded assessments, participant survey scales, and observations. Qualitative data methods include interviews with teachers, role models, staff and focus groups with girls. A project evaluation will also be conducted which investigates project outcomes for participants (girls, teachers, role models, and families) and fidelity of the implementation and enhancements at expansion sites, using a quasi-experimental approach. Career and learning outcomes for girls will be determined using embedded assessments, portfolios, surveys, school data, and previously validated instruments such as the Career Interest Questionnaire and the Modified Attitudes towards Science Inventory. The Managing Complex Change model is used as a framework for the project evaluation for the purpose of examining factors related to the effectiveness of scaling. The dissemination of research and evaluation findings will be achieved through the use of publications, blogs, social media, and conferences. It is anticipated that this project will broaden the participation of Hispanic, African-American, and English language learner girls, build capacity for STEM programming and sustainability at the dissemination sites, and disseminate findings to over 1 million educators, researchers, and community members. Broader impacts include contributing to the field's understanding of how virtual role models and field trips can engage young women, increase corporate advocacy, and engage participants in research and dissemination efforts.
Michigan Technological University will collaborate with David Heil and Associates to implement the Family Engineering Program, working in conjunction with student chapters of engineering societies such as the American Society for Engineering Education (ASEE), the Society of Hispanic Professionals (SHP) and a host of youth and community organizations. The Family Engineering Program is designed to increase technological literacy by introducing children ages 5-12 and their parents/caregivers to the field of engineering using the principles of design. The project will reach socio-economically diverse audiences in the upper peninsula of Michigan including Native American, Hispanic, Asian, and African American families. The secondary audience includes university STEM majors, informal science educators, and STEM professionals that are trained to deliver the program to families. A well-researched five step engineering design process utilized in the school-based Engineering is Elementary curriculum will be incorporated into mini design challenges and activities based in a variety of fields such as agricultural, chemical, environmental, and biomedical engineering. Deliverables include the Family Engineering event model, Family Engineering Activity Guide, Family Engineering Nights, project website, and facilitator training workshops. The activity guide will be pilot tested, field tested, and disseminated for use in urban, suburban, and rural settings. Strategic impact will result from the development of content-rich engineering activities for families and the dissemination of a project model that incorporates the expertise of engineering and educational professionals at multiple levels of implementation. It is anticipated that 300 facilitators and 7,000-10,000 parents and children will be directly impacted by this effort, while facilitator training may result in more than 27,000 program participants.
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TEAM MEMBERS:
Neil HutzlerEric IversenChristine CunninghamJoan ChaddeDavid Heil