There is a dearth of prominent STEM role models for underrepresented populations. For example, according to a 2017 survey, only 3.1% of physicists in the United States are Black, only 2.1% are Hispanic, and only 0.5% are Native American. The project will help bridge these gaps by developing exhibits that include simulations of historical scientific experiments enacted by little-known scientists of color, virtual reality encounters that immerse participants in the scientists' discovery process, and other content that allows visitors to interact with the exhibits and explore the exhibits' themes. The project will develop transportable, interactive exhibits focusing on light: how we perceive light, sources of light from light bulbs to stars, uses of real and artificial light in human endeavors, and past and current STEM innovators whose work helps us understand, create, and harness light now. The exhibits will be developed in three stages, each exploring a characteristic of light (Color, Energy, or Time). Each theme will be explored via multiple deliveries: short documentary and animated films, virtual reality experiences, interactive "photobooths," and technology-based inquiry activities. The exhibit components will be copied at seven additional sites, which will host the exhibits for their audiences, and the project's digital assets will enable other STEM learning organizations to duplicate the exhibits. The exhibits will be designed to address common gaps in understanding, among adults as well as younger learners, about light. What light really is and does, in scientific terms, is one type of hidden story these exhibits will convey to general audiences. Two other types of science stories the exhibits will tell: how contemporary research related to light, particularly in astrophysics, is unveiling the hidden stories of our universe; and hidden stories of STEM innovators, past and present, women and men, from diverse backgrounds. These stories will provide needed role models for the adolescent learners, helping them learn complex STEM content while showing them how scientific research is conducted and the diverse community of people who can contribute to STEM innovations and discoveries.
The project deliverables will be designed to present complex physics content through coherent, immersive, and embodied learning experiences that have been demonstrated to promote engagement and deeper learning. The project will research whether participants, through interacting with these exhibits, can begin to integrate discrete ideas and make connections with complex scientific content that would be difficult without technology support. For example, students and other novices often lack the expertise necessary to make distinctions between what is needed and what is extra within scientific problems. The proposed study follows a Design-Based Research (DBR) approach characterized by iterative cycles of data collection, analysis, and reflection to inform the design of educational innovations and advance educational theory. Project research includes conceiving, building, and testing iterative phases, which will enable the project to capture the complexity of learning and engagement in informal learning settings. Research participants will complete a range of research activities, including focus group interviews, observation, and pre-post assessment of science content knowledge and dispositions.
By showcasing such role models and informing about related STEM content, this project will widen perspectives of audiences in informal learning settings, particularly adolescents from groups underrepresented in STEM fields. Research findings and methodologies will be shared widely in the informal STEM learning community, building the field's knowledge of effective ways to broaden participation in informal science learning, and thus increase broaden participation in and preparation for the STEM-based workforce.
This project is funded by the National Science Foundation's (NSF's) Advancing Informal STEM Learning (AISL) program, which supports innovative research, approaches, and resources for use in a variety of learning settings.
DATE:
-
TEAM MEMBERS:
Todd BoyetteJill HammJanice AndersonCrystal Harden
NASA's Universe of Learning provides resources and experiences that enable diverse audiences to explore fundamental questions in astronomy, experience how science is done, and discover the universe for themselves. Using its direct connection to science and science experts, NASA's Universe of Learning creates and delivers timely and authentic resources and experiences for youth, families, and lifelong learners. The goal is to strengthen science learning and literacy, and to enable learners to discover the universe for themselves in innovative, interactive ways that meet today's 21st century needs. The program includes astronomical data tools, multimedia resources, exhibits and community programs, and professional learning experiences for informal educators. It is developed through a unique partnership between the Space Telescope Science Institute, Caltech/IPAC, the Jet Propulsion Laboratory, the Smithsonian Astrophysical Observatory, and Sonoma State University.
DATE:
-
TEAM MEMBERS:
Denise SmithGordon SquiresKathy LestitionAnya BifernoLynn Cominsky
While there is extensive evidence that STEM careers can be important pathways for augmenting social mobility and for increasing individual prestige, many youth perceive a STEM trajectory as an unattractive option. In the US, women and members of historically marginalized racial and ethnic groups, continue to be underrepresented across STEM disciplines. One vehicle for generating and sustaining interest in STEM is providing youth long-term access to informal science education (ISE) institutions. Here, we incorporate triangulation methods, collecting and synthesizing both qualitative and
This exploratory learning research and design project will study how to use emerging technologies to help document practices in maker-based learning experiences. Despite its established potential for consolidating learning and sense-making, project documentation is often overlooked, not prioritized or seen as burdensome and therefore not integrated into the learning experiences. The project team seeks to understand and address with practice partners the barriers to documentation by systematically exploring how to physically embed and incorporate smart tools and documentation practices into learning environments, specifically creative hands-on learning spaces, like makerspaces. The goal is to understand how to scaffold learners to become more aware, reflective and attentive to their progress towards learning outcomes by embedding supportive tools physically in space as the actions unfold. Making and maker-based learning experiences offer tremendous opportunities to more fully engage diverse learners in STEM education and build a workforce prepared for innovation. Documentation of these learning experiences, both as an authentic practice that professionals engage in as well as an assessment practice for instruction, is often not supported. The project will create open source documentation for solutions and develop supporting case studies, web resources and guides to facilitate easy uptake and adoption of promising approaches.
This proposal will make significant research contributions in three ways: (1) develop and iteratively test a suite of embedded "smart" tools designed to scaffold, manage and trace process documentation practices; (2) study the integration of these tools in formal and informal activities and programs settings and characterize their influence on instruction and the assessment of learning outcomes; (3) establish a set of rubrics based on learner data streams to aid instruction and mark learner progress. Improving documentation practices and the assessment of learning outcomes will advance making as a core STEM educational activity. Through a better understanding of why and how to place networked documentation tools sensitive to space, time and context cues, the threshold for enactment and scaffolded usage can be lowered in a broader range of settings. Ultimately, this exploratory project will not only develop an integrated set of situated documentation tools, but also help us develop hypotheses for how documentation as a mediating process productively supports learning.
The Discovery Research K-12 program (DRK-12) seeks to significantly enhance the learning and teaching of science, technology, engineering and mathematics (STEM) by preK-12 students and teachers, through research and development of innovative resources, models and tools (RMTs). Projects in the DRK-12 program build on fundamental research in STEM education and prior research and development efforts that provide theoretical and empirical justification for proposed projects. The Multimedia Immersion (MI) project is will develop, pilot, and evaluate a nine-week STEM-rich multimedia production course for high school students. MI will make important contributions to the field through its efforts to design and evaluate the promises and challenges of a nine-week multimedia curriculum in multiple urban high schools. The MI course will engage teams of students to develop a personally and socially relevant storyline that guides their use of accessible audio and video technologies to create a five-minute animated video. To develop student STEM experience and provide technical support, the project will provide guidance and learning experiences in engineering (e.g., criteria, constraints, optimization, tradeoffs), science (e.g. sound, light, energy, mechanics) and multimedia technologies (e.g., computer based audio production, video editing and visualizations through animatics (i.e., shooting a succession of storyboards with a soundtrack). animatics).
Because the curriculum situates engineering and science learning in the context of multimedia production, there are natural synergies with several existing high school courses including engineering design, audio/video media production, and multimedia technology. Although these courses are typically electives in high school, developing a 5-minute animated short on a topic of interest may encourage girls and students from underrepresented groups to select this course over other electives. MI will impact 10 teachers and approximately 250 high school students per year. The project will result in the following resources: nine-week curricular unit (multimedia, science, engineering); assessments to monitor student learning of science, engineering and technology (design logs); and research on changes in student knowledge, interest, and a nine-week curricular unit (multimedia, science, engineering). Project resources will be disseminated to teachers, researchers, and curriculum and professional development providers via conference presentations, publications, and online webinars.
The MI project builds on student familiarity and interest in music, video and technology to promote an: (1) understanding of engineering design and physics and an (2) an appreciation of the fundamental role of STEM in popular culture. Project evaluation will be conducted using student surveys and an examination of work products in conjunction with implementation challenges and successes to generate evidence for the feasibility and utility of a high school multimedia course that explicitly addresses science and engineering learning. Project evaluation will use student design logs as a window into student design processes and conceptual understanding. Student design logs are an essential feature of MI curriculum design. With an appropriate structure, these design logs can inform teaching, afford an opportunity for students to reflect on their own work, and provide evidence of student thinking and learning for assessment purposes. Using student design logs as a window into students? design process and conceptual understanding is an important contribution to the engineering education community which has few options for measuring student knowledge in ways that are consistent with the hands-on, iterative nature of the design process.
The Space and Earth Informal STEM Education (SEISE) project, led by the Arizona State University with partners Science Museum of Minnesota, Museum of Science, Boston, and the University of California Berkeley’s Lawrence Hall of Science and Space Sciences Laboratory, is raising the capacity of museums and informal science educators to engage the public in Heliophysics, Earth Science, Planetary Science, and Astrophysics, and their social dimensions through the National Informal STEM Education Network (NISE Net). SEISE will also partner on a network-to-network basis with other existing coalitions and professional associations dedicated to informal and lifelong STEM learning, including the Afterschool Alliance, National Girls Collaborative Project, NASA Museum Alliance, STAR_Net, and members of the Association of Children’s Museums and Association of Science-Technology Centers. The goals for this project include engaging multiple and diverse public audiences in STEM, improving the knowledge and skills of informal educators, and encouraging local partnerships.
In collaboration with the NASA Science Mission Directorate (SMD), SEISE is leveraging NASA subject matter experts (SMEs), SMD assets and data, and existing educational products and online portals to create compelling learning experiences that will be widely use to share the story, science, and adventure of NASA’s scientific explorations of planet Earth, our solar system, and the universe beyond. Collaborative goals include enabling STEM education, improving U.S. scientific literacy, advancing national educational goals, and leveraging science activities through partnerships. Efforts will focus on providing opportunities for learners explore and build skills in the core science and engineering content, skills, and processes related to Earth and space sciences. SEISE is creating hands-on activity toolkits (250-350 toolkits per year over four years), small footprint exhibitions (50 identical copies), and professional development opportunities (including online workshops).
Evaluation for the project will include front-end and formative data to inform the development of products and help with project decision gates, as well as summative data that will allow stakeholders to understand the project’s reach and outcomes.
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. The subject of physics and all of its sub-disciplines are becoming more prevalent in the public press as the research results appear to be quite interesting and important. While the physics discipline has made a Nation-wide effort to acquaint the public with physics knowledge through informal education learning experiences for years, it has not been as successful as the community desires. Thus, this project is aimed to gather all of the informal and outreach physics education efforts that have been attempted in the hope of finding the best practices for learning physics concepts and practices. A compendium will be published to inform future opportunities on how to educate the public through informal and outreach mechanisms. This project is a collaboration between Michigan State University and the University of Colorado. The physics community has a long history of engaging audiences in informal education activities. Physics institutions that facilitate informal programs include university departments, national laboratories and centers, and professional societies and organizations. There is, however, no systemic understanding of how these programs are facilitated, nor an assessment of the collective impact that these programs have on participants. This project will address numerous research questions in the broad areas of Activity Detail, Structural Aspects, and Assessment. Further, their efforts will determine the "who, what, why, where and how" of informal physics offerings, focusing on their facilitation, impact on participants, and the academic and discipline-specific cultures from which these programs originate. The study has several definite research outcomes that will emerge from this methodology: 1) They will produce a survey of the informal efforts of university physics departments, national physics labs and national physics organizations, 2) They will develop a taxonomy of informal physics programs from which we can characterize the landscape of programs, and 3) by investigating both "successful" as well as "failed" or terminated programs, they will develop an understanding of the culture and resources needed to support outreach from these research findings. In addition, they will produce published works that can be utilized by informal practitioners and administrators in physics to examine current programs and guide the development of new programs. With regards to the research questions and framework, the overarching and driving question for this research project is: "What is the landscape of informal physics learning, specifically, of those programs in the United States facilitated by physicists and physics students at academic institutions, national labs and by national physics organizations?" This study will provide a robust understanding of the state of informal physics programs and outreach by physicists in the United States today. Findings will inform practitioners and administrators as to how best to support and design informal physics programming. The results will also have broad implications for other discipline-specific informal STEM programming. The primary data collection methods will be a nationwide survey and interviews with a large sample of informal practitioners from the physics community. Site visits will be conducted with a subset of these programs in order to observe programs in action and to glean insights from university participants, community partners, public, and K-12 audiences.
A collaboration of TERC, MIT, The Woods Hole Oceanographic Institution and community-based dance centers in Boston, this exploratory project seeks to address two main issues in informal science learning: 1) broadening participation in science by exploring how to expand science access to African-American and Latino youth and 2) augmenting science learning in informal contexts, specifically learning physics in community-based dance sites. Building on the growing field of "embodied learning," the project is an outgrowth in part of activities over the past decade at TERC and MIT that have investigated approaches to linking science, human movement and dance. Research in embodied learning investigates how the whole body, not just the brain, contributes to learning. Such research is exploring the potential impacts on learning in school settings and, in this case, in out of school environments. This project is comprised of two parts, the first being an exploration of how African-American and Latino high school students experience learning in the context of robust informal arts-based learning environments such as community dance studios. In the second phase, the collaborative team will then identify and pilot an intervention that includes principles for embodied learning of science, specifically in physics. This phase will begin with MIT undergraduate and graduate students developing the course before transitioning to the community dance studios. This project is funded by the Advancing Informal STEM Learning (AISL) program, which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. 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 goal of this pilot feasibility study is to build resources for science learning environments in which African-American and Latino students can develop identities as people who practice and are engaged in scientific inquiry. Youth will work with choreographers, physicists and educators to embody carefully selected physics topics. The guiding hypothesis is that authentic inquiries into scientific topics and methods through embodied learning approaches can provide rich opportunities for African-American and Latino high school-aged youth to learn key ideas in physics and to strengthen confidence in their ability to become scientists. A design- based research approach will be used, with data being derived from surveys, interviews, observational field notes, video documentation, a case study, and physical artifacts produced by participants. The study will provide the groundwork for producing a set of potential design principles for future projects relating to informal learning contexts, art and science education with African American and Latino youth.
DATE:
-
TEAM MEMBERS:
Folashade Cromwell SolomonTracey WrightLawrence Pratt
Well-designed educational games represent a promising technology for increasing students interest in and learning of STEM topics such as physics. This project will research how to optimally combine and embed dynamic assessment and adaptive learning supports within an engaging game design to build effective educational games. The project will add enhancements to a physics game called Physics Playground. The general goal of this research is to test a valid methodology that can be used in the design of next-generation learning games. The enhancement of Physics Playground will leverage the popularity of video games to capture and sustain student attention and teach physics to a much broader audience than is currently the case in traditional physics classrooms. To be most effective, this new genre of learning games needs to not only be highly engaging as a game but also to provide real-time assessment and feedback to students; support understanding of science content (i.e.,Newtonian physics); be accessible to beginners; accommodate a range of proficiencies and interests; and support equity. The research will have particular relevance to designers developing other science games and simulation by providing information about the kinds of learning supports and feedback to students are most effective in promoting engagement and learning. The project is supported by the Cyberlearning and Future Learning Technologies Program, which funds efforts that will help envision the next generation of learning technologies and advance what we know about how people learn in technology-rich environments. Cyberlearning Exploration (EXP) Projects explore the viability of new kinds of learning technologies by designing and building new kinds of learning technologies and studying their possibilities for fostering learning and challenges to using them effectively.
The project will systematically develop, test, and evaluate ways to integrate engaging, dynamic learning supports in Physics Playground to teach formal conceptual physics competencies. More generally, the project aims to advance the learning sciences, particularly in the fields of adaptivity and assessment in educational technology. Using a design-based research approach spanning three years, the research team will: (1) develop and test the effectiveness of various learning support features included in the game in Year 1; (2) develop and test an adaptive algorithm to manage the progression of difficulty in game levels in Year 2; and (3) test learning supports and adaptive sequencing in a controlled evaluation study. This research will provide evidence of the instructional effectiveness of an educational game designed using principles of instructional, game, and assessment design. It will advance understanding of the contributions of different kinds of learning supports (e.g., visualizations and explanations) and adaptivity to game-based learning and contribute to the design of next-generation learning games that successfully blur the distinction between assessment and learning. The project will generate research findings that can be incorporated into other types of STEM learning games.
DATE:
-
TEAM MEMBERS:
Valerie ShuteRussell AlmondFengfeng Ke
The Orlando Science Center (OSC) in partnership with BASE Camp Children's Cancer Foundation and the University of Central Florida (UCF) will engage chronically ill children (cancer, sickle-cell, HIV/AIDS, etc.) and other Orlando area youth ages 10-18 who face the greatest educational disparities in NASA-themed Aeronautics, Space Exploration, and Space Science exhibits through a STEM engagement and educator professional development project entitled STEM Satellites: A Mobile Mathematics and Science Initiative for Orlando Metropolitan Area Children's Hospitals. OSC will partner with educational researchers, evaluators, and planetary scientists from the University of Central Florida to create three mobile exhibits for each of the three children's hospitals in the Orlando metropolitan area. Two additional sets of the three mobile carts will be used at OSC and UCF. The three mobile exhibits will be based on the planned NASA missions that the UCF planetary scientists are leading including a Mars-themed exhibit focusing on space exploration, an asteroid-themed exhibit, and an exhibit on microgravity. Each cart will include multiple STEM activities that incorporate NASA data and artifacts from prior NASA missions, UCF planetary science collections, and Kennedy Space Center. OSC will provide professional development and training to BASE Camp volunteers who will supervise the use of the mobile exhibits in the hospitals. These exhibits will provide authentic experiences that mirror current and planned NASA missions at a level that the children can understand. These hands-on and engaging exhibits will not only help motivate children to pursue STEM careers but will also help educate the general public about the exciting and important work that NASA carries out. Providing this level of engaging and authentic STEM activities through the mobile exhibits to this historically underrepresented population is unprecedented.
DATE:
-
TEAM MEMBERS:
JoAnn NewmanJosh ColwellBrandan LanmanMegan Nickels
Discover NASA is the Discovery Museum’s endeavor to engage students in grades K through 12 as well as members of the general public in innovative space science and STEM-focused learning through the implementation of two modules: upgrades to the Challenger Learning Center, and the creation of K through 12 amateur rocketry and spacecraft design programming. The programming will be piloted at the Discovery Museum and Planetarium, and at the Inter-district Discovery Magnet School and the Fairchild-Wheeler Multi-Magnet High School, with an additional strategic partnership with the University of Bridgeport, which will provide faculty mentors to high school seniors participating in the rocketry program. Through these two modules, the Discovery Museum and Planetarium aims to foster an early interest in STEM, increase public awareness about NASA, promote workforce development, and stimulate an interest in the future of human space exploration. Both modules emphasize design methodologies and integration of more advanced space science into the STEM curriculum currently offered by Discovery Museum to visitors and public schools. The Challenger Learning Center upgrades will enable the Museum to deliver simulated human exploration experiences related to exploration of the space environment in Low Earth Orbit and simulated human exploration of Moon, Mars, and beyond, which will increase public and student awareness about NASA and the future of human space exploration. The development of an amateur rocketry and spacecraft development incubator for education, the general public, and commercial space will stimulate the development of key STEM concepts.
The UMN MRSEC conducts an ambitious and multi-faceted education and outreach program to extend the impact of the Center beyond the university, providing undergraduates, college faculty, high school teachers, and K-12 students with opportunities that augment their traditional curriculum and increase their appreciation of materials science and engineering (MS&E). Our summer research program provides high-quality research and educational experiences in MS&E to students and faculty, drawn primarily from undergraduate institutions with limited research opportunities, while placing a strong emphasis on inclusion of women and members of underrepresented groups.