This position paper, co-authored Center for Childhood Creativity's Director Elizabeth Rood and Director of Research Helen Hadani, details the importance of exposing children ages 0-8 to science, technology, engineering, and math (STEM) experiences. The review of more than 150 empirical studies led Rood and Hadani to conclude that, despite what has been previously thought, modern research supports the understanding that children are capable of abstract thinking and STEM-learning from infancy, beginning before their first birthday.
The Roots of STEM Success, authored in support of classroom
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Helen Shwe HadaniElizabeth RoodAmy EisenmannRuthe FousheeGarrett JaegerGina JaegerJoanna KauffmannKatie KennedyLisa Regalla
resourceresearchMuseum and Science Center Programs
This article focuses on the efforts of the Collaborative for Early Science Learning (CESL), a group of six museums led by the Sciencenter in Ithaca, New York, that partner with their local Head Start programs to provide training for teachers and opportunities for family engagement. These efforts address the gap between children’s readiness to explore science through everyday experiences and adults’ support. CESL believes that hands-on professional development (PD) opportunities for teachers and families can reduce adult discomfort with facilitating science programming and increase their
Slides from the January 30, 2018 Webinar present information for preparing proposals for the NSF INCLUDES Alliance Solicitation (NSF 18-529). Includes a brief description of NSF INCLUDES, an explanation of Collaborative Change strategies and the NSF INCLUDES 5 elements of collaborative change, proposal recommendations, details on the NSF cooperative agreements and the NSF Merit Review criteria, and provides useful resources.
In partnership with the Center for Research on Lifelong STEM Learning, we completed year one of a multi-year study on the impact of the Curiosity Machine model on students. There is a specific focus on linking dosage to impact. The constructs that were explored were:
* STEM identities (e.g., how students think of themselves in science)
* “Possible selves” (see STEM as a component of their own career or future learning pathways, e.g., course taking in STEM areas)
* Self-efficacy (e.g., beliefs in their abilities in STEM subject areas, self-perception of confidence in STEM)
* Interest in
The 5-year longitudinal study on Iridescent's Family Science Learning model was conducted with 2,173 participants from 9 schools and museum sites in Los Angeles and New York City. Participants were underserved elementary school students and their parents. Families met once a week for 5 weeks in a row. Five families (~20 participants) came for all 5 years.
Each program implementation was coordinated by Iridescent team members. The goal of this study was to:
* To identify scalable methods of engaging underserved audiences in STEM.
* To identify sustainable methods of supporting long-term
This NSF INCLUDES Design and Development Launch Pilot will improve math achievement among elementary school students of color in public schools in Albuquerque, New Mexico. Recognizing the need to coordinate efforts related to students' math and science achievement, key stakeholders formed the NM STEM Ecosystem, a dynamic network of cross-sector partners committed to making real impact on STEM education and degree attainment in Albuquerque. The NM STEM Ecosystem identified the math achievement gap between low-income students of color and their more economically-advantaged peers as the Broadening Participation (BP) Challenge it would address first. While math achievement gaps between students of color and Caucasian students appear nationally, the situation is particularly dire in New Mexico. In order to keep doors open to future STEM careers, it is crucial that learning pathways for math are articulated early and that these pathways honor families' cultural ways of knowing. The innovative strategy of Math Families & Communities Empowering Student Success (Math FACESS) is to use a collective impact approach to close the math achievement gap by connecting formal and informal STEM educators around a coherent, multi-faceted program of early mathematics teaching and learning that empowers parents and teachers to support children's mathematical development. Implementation of Math FACESS includes four major components: 1) Teachers at two pilot schools will participate in professional development related to Math Talk and Listening; 2) Parents at the pilot schools will participate in parent workshops and community-based activities focused on supporting their children's math achievement; 3) Project partners will implement community-based family activities organized around a theme of Twelve Months of Math; and 4) Ecosystem partners will study what worked and what didn't, in order to identify best practices that can be shared with system leaders to scale effective practices and increase impact.
The near-term objectives for Math FACESS are: 1) improve students' attitudes, practices, and achievement in math; 2) improve parents' attitudes, practices, and confidence in math and increase their utilization of family math resources; 3) improve data-sharing among partners related to math participation and achievement; and 4) create pathways within the Ecosystem for family math learning. The effectiveness of the collective impact model and impacts on partner organizations also will be assessed. Through the math FACESS Launch Pilot, the NM STEM Ecosystem plans to: 1) demonstrate the power of a collective impact social innovation framework to address a systemic community condition -- in this case, the math achievement gap; 2) contribute to theory-of-change research that demonstrates student achievement can be affected by working with parents and teachers; and 3) provide a model that values different ways of knowing and uses cultural context in the design of STEM learning opportunities for students, families, and schools.
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TEAM MEMBERS:
Joe HastingsArmelle CasauObenshain KorenKersti TysonAngelo Gonzales
In this NSF INCLUDES Design and Development Launch Pilot the institutions of "Building on Strengths" propose to build and pilot the infrastructure, induction process, and early implementation of the Mathematician Affiliates of Color network. This network will consist of mathematicians of color from across academia and industry who want to invest time in, share their expertise with, and learn from students of color and their teachers. Building on Strengths will draw on basic needs cognitive theory to support these interactions and will focus narrowly on short and moderate term collaborations (from one month to a semester) between visiting mathematicians, students, and collaborating teachers that will involve three specific types of interactions: doing mathematics together as a habits-of-mind practice, talking about the discipline of mathematics and the experiences of mathematicians of color in that discipline, and relationship-building activities. The foundational infrastructure developed in the project will include systems for recruitment, selection and induction, a process for pairing affiliate mathematicians with classrooms, and support structures for the collaborations. To support the goals of the network a prototype virtual space will be developed in which real-time artifacts can be collected and shared from the classroom interactions. While Building on Strengths will pilot this program in the secondary context, once a viable model is established, scaling to K-16, as well as to other STEM fields, will be possible.
The research study in the project uses an exploratory sequential mixed-methods design and will be conducted in two phases. In the first, quantitative, phase of the study the following questions will be addressed: (1) Is the teacher-mathematician collaboration associated with a change for students in perception of basic human needs being met, mathematical or racial identities, or beliefs about mathematics or who can do mathematics? (2) Is the teacher-mathematician collaboration associated with a change for adults in perceptions of the role of basic needs or in adults' identities or beliefs about mathematics or who can do mathematics? In the second, qualitative, phase of the study, two types of interactions will be selected for in-depth qualitative study, identifying cases where groups of students experienced changes in their needs, identity, and beliefs. In this qualitative case-centered phase, the following questions will be explored: (1) What is the nature of the mentor-student interaction? (2) What aspects of the intervention do students feel are most relevant to them? (3) How did the implementation of the intervention differ from the anticipated intervention? The results of the study will help improve the infrastructure for, and better support the interactions between, mathematicians of color, students of color and their mathematics teachers; the outcomes will also shed light on how students experience their interactions.
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Michael YoungMaisha MosesAlbert CuocoEden Badertscher
This article discusses the Youth in Science Action Club (SAC), which uses citizen science to investigate nature, document their discoveries, share data with the scientific community, and design strategies to protect the planet. Through collaborations with regional and national partners, SAC expands access to environmental science curriculum and training resources.
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Laura HerszenhornKatie LevedahlSuzi Taylor
This is the solicitation for proposals to the NSF 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 opportunities for the public in informal environments; provide multiple pathways for broadening access to and engagement in STEM learning experiences; advance innovative research on and assessment of STEM learning in informal environments; and engage the public of all ages in learning STEM in informal environments.
To address the need for STEM reform in K-12 schools, this article describes the design and implementation of a rigorous, interdisciplinary science and research program (ISR) in two local high schools (HS-S and HS-H). The ISR, adapted from the successful School for Science and Math at Vanderbilt program, provides seven courses over four years that focus on the development of critical thinking skills and the ability to construct and perform hypothesis-driven research projects. The courses are co-taught by a science teacher (masters or doctoral level) and a Ph.D. scientist. Overall, students in
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Jennifer A. UfnarVirginia L. Shepherd
Dr. Ann Chester, Director of the Health Sciences and Technology Academy (HSTA) in West Virginia was looking for professional researchers interested in working with HSTA's high school-aged participants through community-based participatory research (CBPR) projects. Dr. Alicia Zbehlik, with the Dartmouth Institute for Health Policy & Clinical Practice in New Hampshire, needed to further her research in knee osteoarthritis to support a pilot intervention in her target population. The two met, saw potential benefits to both organizations in forming a partnership, and agreed to undertake a one-year
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Paul Luis SicilianoBethany L. HornbeckSara HanksSummer L. KuhnAlicia J. ZbehlikAnn L. Chester
MobiLLab is a mobile science education program designed to awaken young people’s interest in science and technology (S&T). Perceived novelty, or unfamiliarity, has been shown to affect pupils’ educational outcomes at similar out-of-school learning places (OSLePs) such as museums and science centers. A study involved 215 mobiLLab pupils who responded to three surveys: a pre-preparation, at-visit, and post-visit survey. Results provide evidence for four dimensions of pupils’ at-visit novelty: curiosity, exploratory behavior, oriented feeling, and cognitive load. Findings also show that classroom