Wireless radio communications, such as Wi-Fi, transmit public and private data from one device to another, including cell phones, computers, medical equipment, satellites, space rockets, and air traffic control. Despite their critical role and prevalence, many people are unfamiliar with radio waves, how they are generated and interact with their surroundings, and why they are the basis of modern communication and navigation. This topic is not only increasingly relevant to the technological lives of today’s youth and public, it is critical to the National Science Foundation’s Industries of the Future activities, particularly in advancing wireless education and workforce development. In this project, STEM professionals from academia, industry and informal education will join forces to design, evaluate, and launch digital apps, a craft-based toolkit, activity guides, and mobile online professional learning, all of which will be easily accessed and flexibly adapted by informal educators to engage youth and the public about radio frequency communications. Experiences will include embodied activities, such as physically linking arms to create and explore longitudinal and transverse waves; mobile experiences, such as augmented reality explorations of Wi-Fi signals or collaborative signal jamming simulations; and technological exploration, such as sending and receiving encrypted messages.
BSCS Science Learning, Georgia Tech, and the Children’s Creativity Museum (CCM) with National Informal STEM Education Network (NISE Net) museum partners will create pedagogical activity designs, digital apps, and a mobile online professional learning platform. The project features a rigorous and multipronged research and development approach that builds on prior learning sciences studies to advance a learning design framework for nimble, mobile informal education, while incorporating the best aspects of hands-on learning. This project is testing two related hypotheses: 1) a mobile strategy can be effective for supporting just-in-time informal education of a highly technical, scientific topic, and 2) a mobile suite of resources, including professional learning, can be used to teach informal educators, youth, and the general public about radio frequency communications. Data sources include pre- and post- surveys, interviews, and focus groups with a wide array of educators and learners.
A front-end study will identify gaps in public understanding and perceptions specific to radio frequency communications, and serve as a baseline for components of the summative research. Iterative formative evaluation will incorporate participatory co-design processes with youth and informal educators. These processes will support materials that are age-appropriate and culturally responsive to not only youth, with an emphasis on Latinx youth, but also informal educators and the broader public. Summative evaluation will examine the impact of the mobile suite of resources on informal educators’ learning, facilitation confidence and intentions to continue to incorporate the project resources into their practice. The preparation of educators in supporting public understanding of highly technological STEM topics can be an effective way for supporting just-in-time public engagement and interests in related careers. Data from youth and museum visitors will examine changes to interest, science self-efficacy, content knowledge, and STEM-related career interest. If successful, this design approach may influence how mobile resources are designed and organized effectively to impact future informal education on similarly important technology-rich topics. All materials will be released under Creative Commons licenses allowing for widespread sharing and remixing; research and design findings will be published in academic, industry, and practitioner journals.
This project is co-funded by two NSF programs: The Advancing Informal STEM Learning 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. 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.
Potential STEM talent is lost each day for some of the most underserved and underrepresented populations in our nation's incarcerated men, women, and youth. With years devoid of quality STEM education and opportunities while in prison, incarcerated individuals are often significantly underprepared in STEM and for the STEM workforce. This educational debt exacerbates the pattern of marginalization for these vulnerable populations. Their STEM literacy, employability and potential for earning sustainable wages upon release are stifled. This deficit in opportunity is especially stark for underrepresented groups in the United States. Roughly 61% of the prison population is non-white, which far exceeds the national average of 35%. The U.S. also has the highest per capita incarceration rates in the world, incarcerating 698 men, women, and youth for every 100,000 people. Equally unsettling, for the first time in American history the population growth rate for incarcerated women has outpaced men by almost 2 to 1 for the past 25 years. While there are many contributing factors to the high rate of incarceration in the U.S., high quality prison STEM education programs have been shown to help counter socio-economic and education debts through greater STEM knowledge attainment, successful societal integration, and increased wage and advancement potential, which increase the likelihood that formerly incarcerated individuals and their children can live productive lives. The NSF INCLUDES STEM Opportunities in Prison Settings (STEM-OPS) Alliance endeavors to build a national network aimed at providing and supporting viable pathways to STEM for the incarcerated and formerly incarcerated. Using a collective impact approach, the Alliance will work collaboratively with key stakeholders and the target population to advance extant and untapped knowledge on high quality prison STEM education and opportunities. This work builds on efforts supported by the National Science Foundation, including exploratory work piloted by two NSF INCLUDES Design and Development Launch Pilots. If successful, this Alliance has the potential to significantly transform the face of the STEM workforce and the narrative regarding the incarcerated and formerly incarcerated and their potential to succeed in STEM.
The STEM-OPS Alliance is comprised of partner organizations committed to ensuring that STEM preparation during and post incarceration is commonplace and successful. During its first year, the Alliance will focus on establishing its national network through a shared vision and goals and a collective impact approach. It will conduct systems ecology mapping to inform the supports and resources needed for the target population to succeed in STEM. Focus groups and interviews will be conducted with incarcerated middle/high school aged youth to better understand their experiences in K-12 schools and with STEM education prior to and during incarceration. The results of the mapping and youth study will be used to inform the future work of the Alliance. Affordances the network endeavors to achieve include: (a) creating accessible STEM opportunities for the target populations through STEM courses, in-prison laboratories, research experiences for undergraduates (REUs), internships, and mentoring, (b) a culturally responsive platform to connect formerly incarcerated job seekers with STEM employment opportunities, (c) an evidence-based toolkit for effective STEM in-prison program design and implementation, (d) an annual convening of key stakeholders and representatives from the target populations to share learnings, disseminate findings and resources, and support the growth and development of the Alliance, and (d) leveraging connections to the greater NSF INCLUDES National Network. A formative and summative evaluation will be conducted by an external evaluator. Through its network, the STEM OPS Alliance is well poised to directly impact 700-880 incarcerated and formerly incarcerated men and women and reach a significant number of organizations working to improve STEM opportunities and outcomes within prison contexts.
This NSF INCLUDES Alliance is funded by NSF Inclusion across the Nation of Communities of Learners of Underrepresented Discoverers in Engineering and Science (NSF INCLUDES), a comprehensive national initiative to enhance U.S. leadership in discoveries and innovations by focusing on diversity, inclusion and broadening participation in STEM at scale. Significant co-funding has also been provided by the NSF Innovative Technology Experiences for Students and Teachers (ITEST) program and the NSF Advancing Informal STEM Learning Program (AISL).
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:
Eden BadertscherStanley AndrisseJannette CareyRich Milner
resourceresearchProfessional Development, Conferences, and Networks
Today’s digital and online media demand an approach to learning keyed to a networked and interconnected world. The growth of online communities, social and online media, open educational resources, ubiquitous computing, big data, and digital production tools means young people are coming of age with a growing abundance of access to knowledge, information, and social connection. These shifts are tied to a host of new opportunities for interest-driven learning, creative expression, and diverse forms of contribution to civic, political, and economic life. Even learning of traditional academic
The employment demands in STEM fields grew twice as fast as employment in non-STEM fields in the last decade, making it a matter of national importance to educate the next generation about science, engineering and the scientific process. The need to educate students about STEM is particularly pronounced in low-income, rural communities where: i) students may perceive that STEM learning has little relevance to their lives; ii) there are little, if any, STEM-related resources and infrastructure available at their schools or in their immediate areas; and iii) STEM teachers, usually one per school, often teach out of their area expertise, and lack a network from which they can learn and with which they can share experiences. Through the proposed project, middle school teachers in low-income, rural communities will partner with Dartmouth faculty and graduate students and professional science educators at the Montshire Museum of Science to develop sustainable STEM curricular units for their schools. These crosscutting units will include a series of hands-on, investigative, active learning, and standards-aligned lessons based in part on engineering design principles that may be used annually for the betterment of student learning. Once developed and tested in a classroom setting in our four pilot schools, the units will be made available to other partner schools in NH and VT and finally to any school wishing to adopt them. In addition, A STEM rural educator network, through which crosscutting units may be disseminated and teachers may share and support each other, will be created to enhance the teachers’ ability to network, seek advice, share information, etc.
This application requests support to enable a team of experienced science educators and biomedical and behavioral health network scientists to develop and implement the Worlds of Connections curriculum. Most middle school students are familiar with patient care-related health careers (e.g., nurses, dentists, surgeons), but few know about emerging careers in network science that can be leveraged to improve population health. This innovative and research-based science program is strategically designed to increase awareness of, understanding of, and interest in the important role of network science for health. This project will design learning activities that incite interest in network science applications to biomedical and public health research. The long- term goal is to enhance the diversity of the bio-behavioral and biomedical workforce by increasing interest in network science among members of underrepresented minority communities and to promote public understanding of the benefits of NIH-funded research for public health. The goal of this application is to identify and create resources that will overcome barriers to network science uptake among underserved minority middle school youth. The central hypothesis is that the technology-rich field of network science will attract segments of today’s youth who remain uninterested in conventional, bio-centric health fields. Project activities are designed to improve understanding of how informal STEM experiences with network science in health research can increase STEM identities, STEM possible selves, and STEM career aspirations among youth from groups historically underrepresented in STEM disciplines at the center of health science research (Aim 1) and create emerging media resources via augmented reality technologies to stimulate broad interest in and understanding of the role of network science in biomedical and public health research (Aim 2). A team led by University of Nebraska-Lincoln sociologists will partner with the University of Nebraska at Omaha; state museums; centers for math, science, and emerging media arts; NIH-funded network scientists; educators; community learning centers at local public schools; learning researchers; undergraduates; software professionals; artists; augmented reality professionals; storytellers; and evaluation experts to accomplish these goals and ensure out of school learning will reinforce Next Generation Science Standards. The Worlds of Connections project is expected to impact 35,250 youth and 20,570 educators in Lincoln and Omaha, Nebraska by: adding network science modules to ongoing 6th-8th-grade afterschool STEM clubs in community learning centers; adding network science for health resources to a summer graduate course on “activating youth STEM identities” for sixth to twelfth grade STEM teachers; connecting teachers with local network scientists; creating free, downloadable, high-quality emerging media arts-enhanced stories; and publishing peer-reviewed research on the potential of network science to attract youth to health careers. Coupled with the dissemination plan, the project design and activities will be replicable, allowing this project to serve as a model to guide other projects in STEM communication.
PUBLIC HEALTH RELEVANCE:
The lack of public understanding about the role of network science in the basic biological and social health sciences limits career options and support for historically underrepresented groups whose diverse viewpoints and questions will be needed to solve the next generation of health problems. The Worlds of Connections project will combine network science, social science, learning research, biology, computer science, mathematics, emerging media arts, and informal science learning expertise to build a series of monitored and evaluated dissemination experiments for middle school science education in high poverty schools. Broad dissemination of the curriculum and project impacts will employ virtual reality technologies to bring new and younger publics into health-related STEM careers.
DATE:
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TEAM MEMBERS:
Julia McquilanGrace Stallworth
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.