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.
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TEAM MEMBERS:
Todd BoyetteJill HammJanice AndersonCrystal Harden
Casual games are everywhere. People play them throughout life to pass the time, to engage in social interactions, and to learn. However, their simplicity and use in distraction-heavy environments can attenuate their potential for learning. This experimental study explored the effects playing an online, casual game has on awareness of human biological systems. Two hundred and forty-two children were given pretests at a Museum and posttests at home after playing either a treatment or control game. Also, 41 children were interviewed to explore deeper meanings behind the test results. Results show
Supported by the National Science Foundation, the Global Soundscapes! Big Data, Big Screens, Open Ears project employs a variety of informal learning experiences to present the physics of sound and the new science of soundscape ecology. The interdisciplinary science of soundscape ecology analyzes sounds over time in different ecosystems around the world. The major components of the Global Soundscapes project are an educator-led interactive giant-screen theater show, group activities, and websites. All components are designed with both sighted and visually impaired students in mind. Multimedia
The project team is developing and testing a prototype of a computer science game-based intervention intended for Grade 1 students. The prototype will include physical robots that will be designed and controlled on a game board by students through a blue-tooth enabled smartphone app. The product will include teacher resources and suggestions to facilitate classroom integration. In the Phase I pilot research with 5 classrooms and 150 students, the researchers will examine whether the prototype functions as planned, if teachers are able to implement it with small groups of students, and whether
This article presents some of the challenges faced in developing an interactive exhibit on nanoscience and nanotechnology in Brazil. Presenting a scientific-technological area which is still in formation and which is little known by the population leads to a (re)consideration of the role of museums and science centers in the conformation and consolidation of scientific practice itself. Museographically, the exhibit deals with the challenge of making matter visible in an expression which is distant from the human perception. Some reflections are presented here on the option of musealization
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Sandra MurrielloDjana ContierMarcelo Knobel
This pathways project would refine and test a game based on the Kinect technology gaming tool to teach seismology concepts in an informal education setting and how they apply to phenomenon in other STEM fields. The game will be developed as a companion tool to the "Quake Catcher Network" a low-cost network of seismic sensors in schools, homes and offices world-wide and tie-ins with seismology programs such as the great California ShakeOut with a participant base of 8.6 million. The project design would select three new learning modules, chosen by a group of scientists and educators, to incorporate into the game and evaluate player experience and knowledge gain. The activities will be conducted at a partner test site, an aquarium, frequented by area youth 8 - 12 years old. The focus of the effort is to add to the knowledge of how gaming can be used effectively in informal learning environments The game places the player as a scientist, allowing the player to make decisions about seismic station deployment strategies following an earthquake, installing the sensors and monitoring incoming data. The game has levels of difficulty and players accrue points by acting swiftly and correctly. Learning goals for the project include making abstract math concepts understandable; involve participants in data collection and the process of scientific investigation, plus demonstrate how scientists and mathematicians use tools of their fields to address real-world issues.
In partnership with the University of Pennsylvania's Graduate School of Education, The Franklin Institute Science Museum will develop, test, and pilot an exportable and replicable cyberlearning exhibit using two cutting edge technologies: Augmented Reality (AR) and Virtual Reality (VR). The exhibit's conceptualization is anchored in the learning research vision of the NSF-funded workshop Cyberinfrastructure for Education and Learning for the Future (Computing Research Association, 2005). The incorporation of VR and AR technologies into the Franklin Institute's electricity and Earth science exhibits is an innovation of traditional approaches to hands-on learning and will improve the quality of the learning experience for the primary audience of families with children and elementary school groups. The project has implications for future exhibit development and more broadly, will provide new research on learning on how to incorporate cyberlearning efforts into traditional exhibits. Fifteen participating exhibit developers across the ISE field will assist in the evaluation of the new exhibit; receive training on the design and development of VR and AR exhibits for their institutions; and receive full access to the exhibit's new software for implementation at their informal learning sites. The technology applications will be developed by Carnegie Mellon University's Entertainment Technology Center--leaders in the field in Virtual Reality design and development. Front-end and formative evaluation will be overseen internally by the Franklin Institute. The Institute for Learning Innovation will conduct the summative evaluation. Research will be conducted by the University of Pennsylvania's Graduate School of Education on the effects of AR and VR technologies on exhibit learning.
A two stage summative evaluation was conducted following the launch of the Mystic Seaport for Educators website, the final output resulting from the IMLS National Leadership grant entitled Mystic E-Port Digital Classroom project. The results of four focus groups, conducted in two phases, found consistent results suggesting that the project was successful at achieving all four goals as outlined in the original grant proposal. Appendix includes focus group protocol.
In the many studies of games and young people's use of them, little has been written about an overall "ecology" of gaming, game design and play—mapping the ways that all the various elements, from coding to social practices to aesthetics, coexist in the game world. This volume looks at games as systems in which young users participate, as gamers, producers, and learners. The Ecology of Games (edited by Rules of Play author Katie Salen) aims to expand upon and add nuance to the debate over the value of games—which so far has been vociferous but overly polemical and surprisingly shallow. Game
This article draws from the literature on self-determination and Universal Design for Learning principles to set forth the theory that students identified as having learning disabilities may be environmentally disadvantaged and their learning difficulties exasperated by the traditional classroom learning environment. Alternatively, the digital learning environment found in simulation video games is designed so participants can be autonomous, self-directed, goal-oriented and successful. These are, coincidentally, the salient features of a technology-enhanced learning environment designed with
This paper examines the benefits and obstacles to young people's open-ended and unrestricted access to technological environments. While children and youth are frequently seen as threatened or threatening in this realm, their playful engagements suggest that they are self-possessed social actors, able to negotiate most of its challenges effectively. Whether it is proprietary software, the business practices of some technology providers, or the separation of play, work, and learning in most classrooms, the spatial-temporality of young people's access to and use of technology is often configured