The Rochester Museum and Science Center and partners will plan, design, fabricate, and evaluate its new Water Worlds exhibition using a hybrid exhibition model that integrates hands-on science and interactive technology with authentic collections objects in immersive environments. Reimagining the gallery in this way will allow the museum’s professional staff to work with outside experts in the sciences—including environmental science, sustainability, water resources, and climate—to create a unified watershed-themed narrative for the gallery. Hands-on, inquiry-focused exhibits will inspire visitors to explore the Lake Ontario watershed and analyze critical local issues including water pollution, flooding, invasive species, and the impact of a changing climate on local waterways, as well as innovative solutions to these challenges.
The Fairbanks Museum and Planetarium will design, produce, and install Science Alive—a 1,500-square-foot astronomy and meteorology exhibit—as well as develop and implement supporting programs to promote lifelong learning through participation in scientific explorations. Science Alive will leverage the museum’s strengths in meteorology and astronomy by translating these core competencies into dynamic and relevant exhibits and programs. It also will address the community’s STEM educational deficiencies through science methodologies and content. The project’s exhibition and programming components will benefit students, visitors, and the community.
Three-dimensional digital models are increasingly prevalent in preserving tangible and intangible aspects of Indigenous material heritage. Yet, there are no comprehensive, clearly laid-out best practices that can guide researchers, Indigenous communities, and museum personnel in designing ethically sound and socially engaged 3D heritage preservation projects. The use of 3D technologies for heritage preservation and providing public access to digital 3D collections is well-established in the European context. While there have been several robust efforts on digitizing European national heritage, in the U.S. context, the focus often involves work with Indigenous heritage, instantly placing 3D projects into a post-colonial research paradigm with a complex set of ethical ramifications. This research examines emerging thoughts from the European context and connects them with best practices in digital Indigenous data management to identify practices that contribute to cultures of academic integrity that are inclusive of all stakeholder voices. This work fosters ethical cultures of STEM through the development of a comprehensive Responsible Conduct of Research guiding document that can be adapted to address culture-specific Indigenous perspectives as well as project-specific challenges in future 3D heritage preservation endeavors.
Project goals are accomplished through workshops and virtual collaborations that bring together researchers, Indigenous community members, and heritage preservation professionals with previous experience in the responsible management, protection, and sharing of Indigenous digital data and the use of 3D technology for heritage preservation. The collaboratively produced guidelines outline ethical considerations that can be used in developing: 1) partnerships with origin/descendant communities, 2) institution- and collection-specific museum policies on using 3D technology, 3) Tribal policies for culturally appropriate use of 3D technologies, and 4) training material and curriculum that integrates with other research compliance regulations pertaining to heritage preservation. The project explores the questions that have emerged through previous experiences using 3D technologies to preserve Indigenous ancestral heritage. These questions include the factors contributing to developing ethically sound 3D heritage preservation projects; the practices useful in 3D projects to foster a culture of integrity that equally engages academic and Indigenous perspectives; consideration for what constitutes Responsible Conduct of Research in using 3D technologies to preserve Indigenous cultural heritage; and addressing practice-based questions that contribute to understanding ethical challenges in digitally preserving and presenting Indigenous heritage. The project situates 3D modeling and heritage representation as part of the larger discourse on decolonizing core methodologies in museum management and anthropological collection practices. Results from this work can be adapted to training future researchers and digital heritage management professionals and creating meaningful partnerships in heritage documentation. This research cultivates cultures of academic integrity by informing heritage management policy on the critical importance of heritage ethics for the creation and management of 3D digitization projects involving Indigenous collections. This award is funded by the Directorate of Geosciences and the Directorate of Education and Human Resources.
The Apsáalooke (Crow Indian) Nation in Montana, as well as other Indigenous communities across the United States, disproportionally experience negative consequences from water-related environmental hazards, such as contaminated water. In this project, fifth- and sixth-grade Apsáalooke youth will act as change agents through investigating water issues in their communities and presenting findings to their communities. They will conduct this water-related research in the context of an informal summer program designed to integrate Indigenous and Western perspectives on science. For example, youth will learn the cultural significance of water sites while also practicing methods for collecting and analyzing data relative to those sites, guided by Apsáalooke elders and science professionals. During the summer program, Indigenous high school students and tribal college students will mentor the youth. To develop this program, the project team will conduct interviews with elders and Apsáalooke community members in scientific fields to determine the desired features of a program that integrates Indigenous and Western science. They will use the findings from these interviews to develop a multimedia toolkit, which includes a set of comprehensive materials that will enable other researchers and informal educators to implement similar programs. This toolkit will include information about water science and water quality, lesson plans and related resources for the summer program, professional development materials to prepare the high school youth to act as mentors, handouts for family members to facilitate at-home engagement with their children, and more. The project team will research how the implementation of the toolkit influences the participants' water-related knowledge and attitudes toward science. The toolkit, and the associated empirical findings, will be disseminated widely through local, regional, and national professional networks that serve American Indians.
Montana State University, in partnership with Little Big Horn College, will implement and research an informal summer program for Apsáalooke youth in the fifth and sixth grades, as well as a mentorship program for Indigenous high school students and tribal college students. The older students will participate in a four-week internship program in which they learn about conducting water research and facilitating science activities that foreground Apsáalooke perspectives and cultural practices. The high school and tribal college students will partner with Apsáalooke elders and science professionals to facilitate and implement a two-week summer program for the fifth- and sixth-grade youth. This program will use the toolkit materials that were previously developed in consultation with elders and other community stakeholders. Regression analyses of validated pre- and post-surveys, as well as inductive analyses of interviews with stakeholders, will be used to study how the mentoring program affects the high school and tribal college students' attitudes toward science and career interests, and how the summer program affects the fifth- and sixth-graders' water-related knowledge. The research team will also study how youth participation in the program affects their family and community members' water-related knowledge. This project will result in a multimedia toolkit, freely available to the public and widely disseminated through professional networks, which specifies how other informal educators and researchers can implement similar mentorship programs and summer programs for Indigenous youth. Ultimately, this project will broaden participation through resulting in empirically-tested materials that advance practice in informal education for Indigenous youth and their communities. This project is funded by the Advanced Informal STEM Learning (AISL) program. As part of its overall strategy to enhance learning in informal environments, the AISL program seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM (science, technology, engineering, and mathematics) 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 Innovations in Development 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.
The science museum field is only starting to look at ways of providing visitors with opportunities for the authentic observation of complex, real-time biological phenomenon. The project will develop and research a microscope-based exhibit with pedagogical scaffolding (i.e., helpful prompts) that responds to visitors' changing views as they explore live samples and biological processes. As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds innovative research, approaches, and resources for use in a variety of settings. Scientific observation is a systematic, complex practice, critical in the biological sciences where investigation is heavily reliant on visual data. Using techniques and equipment similar to what scientists themselves use, the exhibit will enable visitors to see and explore the complex, dynamic visual evidence that scientists themselves see. The exhibit will use new and more affordable high-resolution imaging technology and image analysis software to make microscopic images of living organisms visible. Armed with "smart" (i.e., computer-assisted) pedagogical scaffolding that supports inquiry, the project will develop exhibits that help informal learners bridge the gap between everyday observation and authentic scientific observation. The platform will incorporate strategies grounded in prior work on learning through observation that will be applicable to a range of biological content and live specimens. The project platform will be designed for use to a variety of informal science learning environments, including nature centers and mobile laboratories as well as interactive science centers. The project platform itself, including the microscope, related imaging, and learning technologies will be relatively inexpensive, bring it within reach of small science museum and schools. The exhibit will directly engage thousands of learners who visit the Exploratorium and will reach underserved audiences through partnerships with BioBus, a mobile unit that serves the New York City area, and the Noyo Center of Marine Science, a science museum that serves rural areas in Northern California.
The project will move beyond simulation and modeling of complex visual phenomena and provide learners with experiences using real visual evidence that can deeply engage them with the content and practice of biological science. By grounding the work in prior theoretical and empirical findings, project research will refine and broaden understanding of scaffolding strategies and their effect on informal science learning at exhibits. Project research will investigate how the project supports learners (1) asking productive questions (i.e., those answerable through observations) that are meaningful to them, (2) interpreting what they see, and (3) connecting their observations to biological concepts to build a more coherent understanding of the content and practice of biological disciplines. A series of comparative studies across and within venues, specimens, and content will assess engagement and scaffolding strategies, with a particular focus on appropriately integrating computational imaging techniques in a way that is responsive to the interests and needs of different venues' audiences. Project research will contribute important knowledge on ways to support informal learners who are engaged in authentic observation of biological phenomenon. Project research findings and technology resources will be widely shared with informal STEM researchers and practitioners concerned with engaging the public in current research in biology, as well as those interested in supporting observation in other disciplines (e.g., meteorology, ocean science, environmental science) that rely on an evidence base of live, dynamic, complex imagery.
This Innovations in Development 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
Virtual Reality (VR) shows promise to broaden participation in STEM by engaging learners in authentic but otherwise inaccessible learning experiences. The immersion in authentic learner environments, along with social presence and learner agency, that is enabled by VR helps form memorable learning experiences. VR is emerging as a promising tool for children with autism. While there is wide variation in the way people with autism present, one common set of needs associated with autism that can be addressed with VR is sensory processing. This project will research and model how VR can be used to minimize barriers for learners with autism, while also incorporating complementary universal designs for learning (UDL) principles to promote broad participation in STEM learning. As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds innovative research, approaches, and resources for use in a variety of settings. This project will build on a prototype VR simulation, Mission to Europa Prime, that transports learners to a space station for exploration on Jupiter's moon Europa, a strong candidate for future discovery of extraterrestrial life and a location no human can currently experience in person. The prototype simulation will be expanded to create a full, immersive STEM-based experience that will enable learners who often encounter cognitive, social, and emotional barriers to STEM learning in public spaces, particularly learners with autism, to fully engage and benefit from this STEM-learning experience. The simulation will include a variety of STEM-learning puzzles, addressing science, mathematics, engineering, and computational thinking through authentic and interesting problem-solving tasks. The project team's learning designers and researchers will co-design puzzles and user interfaces with students at a post-secondary institute for learners with autism and other learning differences. The full VR STEM-learning simulation will be broadly disseminated to museums and other informal education programs, and distributed to other communities.
Project research is designed to advance knowledge about VR-based informal STEM learning and the affordances of VR to support learners with autism. To broaden STEM participation for all, the project brings together research at the intersection of STEM learning, cognitive and educational neuroscience, and the human-technology frontier. The simulation will be designed to provide agency for learners to adjust a STEM-learning VR experience for their unique sensory processing, attention, and social anxiety needs. The project will use a participatory design process will ensure the VR experience is designed to reduce barriers that currently exclude learners with autism and related conditions from many informal learning opportunities, broadening participation in informal STEM learning. Design research, usability, and efficacy studies will be conducted with teens and adults at the Pacific Science Center and Boston Museum of Science, which serve audiences with autism, along with the general public. Project research is grounded in prior NSF-funded research and leverages the team's expertise in STEM learning simulations, VR development, cognitive psychology, universal design, and informal science education, as well as the vital expertise of the end-user target audience, learners with autism. In addition to being shared at conferences, the research findings will be submitted for publication to peer-reviewed journals for researchers and to appropriate publications for VR developers and disseminators, museum programs, neurodiverse communities and other potentially interested parties.
This Innovations in Development 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:
Teon EdwardsJodi Asbell-ClarkeJamie LarsenIbrahim Dahlstrom-Hakki
For thousands of years, Native Hawaiian/Pacific Islander (NHPI) seafarers have successfully utilized systemic observation of their environment to traverse vast expanses of open ocean and thrive on the most remote islands on earth. Developing NHPI trust in the scientific enterprise requires building connections that bridge the values and concepts of 'ike kupuna (traditional knowledge) with scientific knowledge systems and contemporary technology. This project will develop and research a pop-up science exhibit that connects indigenous Hawaiian knowledge with contemporary Western science concepts. The exhibit will show how community knowledge (that is consistent with underlying scientific principles and natural laws) has informed innovation by indigenous peoples. This community-initiated and developed project will begin with a single pop-up exhibit designed to incorporate several hands-on culture-based STEM activities that integrate traditional and modern technologies. For example, the exhibit may cover indigenous systems of star navigation for ocean voyaging, systems of netting for food and water containers, or systems of home design with local and natural materials. This project seeks to develop preliminary evidence of the effectiveness of such an approach for supporting rural Hawaiian youths' STEM engagement, understanding, and personal connections to Native Hawaiian STEM knowledge. Findings from this pilot and feasibility study will inform the development of a larger pop-up science center grounded in indigenous Hawaiian STEM knowledge, and advance intellectual knowledge around culturally sustaining pedagogy by helping informal STEM education practitioners understand community initiated and developed STEM exhibits.
This pop-up science center pilot will be led by a local Hawaiian community organization, INPEACE, in collaboration with several local community members and other community-based organizations. The preliminary research will iteratively explore whether and how an existing Hawaiian culture-based framework can be used to design hands-on STEM exhibits to enhance rural learner engagement, depth of STEM knowledge, and connection to Native Hawaiian STEM knowledge. Research efforts led by Kamehameha Schools, which has a long history of conducting research from an indigenous worldview, will engage 120 learners from various rural communities across Hawaii, from which 40 will be pre-selected middle-school youth, and 80 individuals will be from public audiences of learners ages 12 and up. Through a series of observations, interviews, pre and post surveys with validated instruments, and focus groups, the research will probe: (1) The learners' thoughts on the science practice and its relevance to old and new Hawaii and modern society. (2) The level at which related STEM topics have been understood, and (3) The learners' perceptions about their connection to Native Hawaiian STEM knowledge. Results from this pilot study will inform a future pop-up science center development project, and add to the scarce literature on community-driven, culturally sustaining exhibition development.
This Pilots and Feasibility Studies project is funded by the NSF 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.
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.
As new technologies continue to dominate the world, access to and participation in science, technology, engineering, mathematics (STEM), and computing has become a critical focus of education research, practice, and policy. This issue is exceptionally relevant for American Indians, who remain underrepresented as only 0.2% of the STEM workforce, even though they make up 2% of the U.S. population. In response to this need, this Faculty Early Career Development Program (CAREER) project takes a community-driven design approach, a collaborative design process in which Indigenous partners maintain sovereignty as designers, to collaboratively create three place-based storytelling experiences, stories told in historical and cultural places through location-based media. The place-based storytelling experiences will be digital installations at three culturally, politically, and historically significant sites in the local community where the public can engage with Indigenous science. The work is being done in partnership with the Northwestern Band of the Shoshone Nation (NWBSN).
The principal investigator and the NWBSN will investigate: (a) what are effective strategies and processes to conduct community-driven design with Indigenous partners?; (b) how does designing place-based storytelling experiences develop tribal members' design, technical, and computational skills?; (c) how does designing these experiences impact tribal members' scientific, technological, and cultural identities? The goals are to establish a process of community-driven design, build infrastructure to support this process, and understand how this methodological approach can result in culturally-appropriate ways to engage with science through technology. The principal investigator will work with the tribe to complete three intergenerational design cycles (a design cycle is made up of multiple design iterations). Each design cycle will result in one place-based storytelling experience. The goal is to include roughly 15 youth (ages 6-18), 10 Elders, and 10 other community members (i.e. members ages 18-50, likely parents) in each design cycle (35 tribal members total). Some designers are likely to participate in multiple design cycles. The tribe currently has 48 youth ages 6-18 and the project aims to engage at least 30 across all three design cycles. Over four years of designing three different experiences, the NWBSN aims to recruit at least 100 tribal members (just under 20% of the tribe) to make contributions (as designers, storytellers, or to provide cultural artifacts or design feedback).
This CAREER award 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.
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.
The goal of the National Science Foundation?s Research Coordination Network (RCN) program is to advance a field or create new directions in research or education by supporting groups of investigators to communicate and coordinate their research, training and educational activities across disciplinary, organizational, geographic and international boundaries. This RCN will bring together scholars and practitioners working at the intersection of equity and interdisciplinary making in STEM education. Making is a culture that emphasizes interest-driven learning by doing within an informal, peer-led and creative social environment. Hundreds of maker spaces and maker-oriented classroom pedagogies have developed across the country. Maker spaces often include digital technologies such as computer design, 3-D printers, and laser cutters, but may also include traditional crafts or a variety of artist-driven creations. The driving purpose of the project is to collectively broaden STEM-focused maker participation in the United States through pursuing common research questions, sharing resources, and incubating emergent inquiry and knowledge across multiple working sites of practice. The network aims to build capacity for research and knowledge, building in consequential and far-reaching mechanisms to leverage combined efforts of a core group of scholars, practitioners, and an extended network of formal and informal education partners in urban and rural sites serving people from groups underrepresented in STEM. Maker learning spaces can be particularly fruitful spaces for STEM learning toward equity because they foster interest-driven, collective, and community-oriented learning in making for social and community change. The network will be led by a team of multi-institutional and multi-disciplinary researchers from different geographic regions of the United States and guided by a steering committee of prominent researchers and practitioners in making and equity will convene to facilitate network activities.
Equitable processes are rooted in a commitment to understand and build on the skills, practices, values, and knowledge of communities marginalized in STEM. The research network aims to fill in gaps in current understandings about making and equity, including the many ways different projects define equity and STEM in making. The project will survey the existing research terrain to develop a dynamic and cohesive understanding of making that connects to learners' STEM ideas, communities, and historical ways of making. Additionally, the network will collaboratively develop central research questions for network partners. The network will create a repository for ethical and promising practices in community-based research and aggregate data across sites, among other activities. The network will support collaboration across a multiplicity of making spaces, research institutions, and community organizations throughout the country to share data, methodologies, ways of connecting to local communities and approaches to robust integration of STEM skills and practices. Project impacts will include new research partnerships, a dissemination hub for research related to making and equity, professional development for researchers and practitioners, and leveraging collective research findings about making values and practices to improve approaches to STEM-rich making integration in informal learning environments. The project is funded by NSF's Advancing Informal STEM Learning (AISL) program, which supports innovative research, approaches, and resources for use in a variety of settings. As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds innovative research, approaches, and resources for use in a variety of settings.
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.
The Center for Integrated Quantum Materials pursues research and education in quantum science and technology. With our research and industry partners, the Museum of Science, Boston collaborates to produce public engagement resources, museum programs, special events and media. We also provide professional development in professional science communication for the Center's students, post-docs, and interns; and coaching in public engagement. The Museum also sponsors The Quantum Matters(TM) Science Communication Competition (www.mos.org/quantum-matters-competition) and NanoDays with a Quantum Leap. In association with CIQM and IBM Q, the Museum hosted the first U.S. museum exhibit on quantum computing.
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TEAM MEMBERS:
Robert WesterveltCarol Lynn AlpertRay AshooriTina Brower-Thomas
Exploratorium’s The Phenomenal Genome: Evolving Public Understanding of Genetics in the Post-Mendelian Era project addresses the increasing need to develop genomic literacy in the public at large. The explosion of genomics research over the past two decades has led to an increasingly complex picture of the determinants of human health and human phenotypes, and the applications of this research are now making their way into the clinic, the media, and the hands of consumers. The goal of this project is to create a model for increasing genomic literacy through Informal Science Education programming (ISE), creating a pathway for better decision making for the health of individuals and society at large. The Phenomenal Genome focuses on general science museum visitors and teachers of middle and high school students.
The core of the Exploratorium’s approach to science education is the creation of intriguing, provocative and investigable phenomena that are experienced directly and personally through exhibits, facilitated explorations, programs, and teacher professional development. Over two years, we will develop, test, and iterate inquiry-based professional development to help teachers develop understanding and integrate the principles of contemporary genomics and genetics into their classrooms. 120 middle and high school teachers will be served during this period, and many more beyond that, as the activities and workshops developed become a regular part of our teacher professional development programming. A learning scientist specializing in teacher learning will conduct research to determine which approaches and experiences are most effective for this context, and why.
In a parallel process, we will develop and test exhibits and experiences on the museum floor for museum visitors, using a similar iterative process of prototype testing with an embedded learning scientist to study visitor learning. We plan to define the approaches that work across audiences and contexts, as well as those that work best in particular contexts.
Through this work, we will develop new resources for teaching and learning contemporary genomics and genetics, and identify promising practices in communicating contemporary genomics and genetics in informal spaces across audiences. We will disseminate our findings via conferences, peer-reviewed articles, and workshops for the ISE community.