Information visualization could be used to leverage the credibility of displayed scientific data. However, little was known about how display characteristics interact with individuals' predispositions to affect perception of data credibility. Using an experiment with 517 participants, we tested perceptions of data credibility by manipulating data visualizations related to the issue of nuclear fuel cycle based on three characteristics: graph format, graph interactivity, and source attribution. Results showed that viewers tend to rely on preexisting levels of trust and peripheral cues, such as
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TEAM MEMBERS:
Nan LiDominique BrossardDietram ScheufelePaul WilsonKathleen Rose
The Sustainability Teams Empower and Amplify Membership in STEM (S-TEAMS), an NSF INCLUDES Design and Development Launch Pilot project, will tackle the problem of persistent underrepresentation by low-income, minority, and women students in STEM disciplines and careers through transdisciplinary teamwork. As science is increasingly done in teams, collaborations bring diversity to research. Diverse interactions can support critical thinking, problem-solving, and is a priority among STEM disciplines. By exploring a set of individual contributors that can be effect change through collective impact, this project will explore alternative approaches to broadly enhance diversity in STEM, such as sense of community and perceived program benefit. The S-TEAMS project relies on the use of sustainability as the organizing frame for the deployment of learning communities (teams) that engage deeply with active learning. Studies on the issue of underrepresentation often cite a feeling of isolation and lack of academically supportive networks with other students like themselves as major reasons for a disinclination to pursue education and careers in STEM, even as the numbers of underrepresented groups are increasing in colleges and universities across the country. The growth of sustainability science provides an excellent opportunity to include students from underrepresented groups in supportive teams working together on problems that require expertise in multiple disciplines. Participating students will develop professional skills and strengthen STEM- and sustainability-specific skills through real-world experience in problem solving and team science. Ultimately this project is expected to help increase the number of qualified professionals in the field of sustainability and the number of minorities in the STEM professions.
While there is certainly a clear need to improve engagement and retention of underrepresented groups across the entire spectrum of STEM education - from K-12 through graduate education, and on through career choices - the explicit focus here is on the undergraduate piece of this critical issue. This approach to teamwork makes STEM socialization integral to the active learning process. Five-member transdisciplinary teams, from disciplines such as biology, chemistry, computer and information sciences, geography, geology, mathematics, physics, and sustainability science, will work together for ten weeks in summer 2018 on real-world projects with corporations, government organizations, and nongovernment organizations. Sustainability teams with low participation by underrepresented groups will be compared to those with high representation to gather insights regarding individual and collective engagement, productivity, and ongoing interest in STEM. Such insights will be used to scale up the effort through partnership with New Jersey Higher Education Partnership for Sustainability (NJHEPS).
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TEAM MEMBERS:
Amy TuiningaAshwani VasishthPankaj Lai
Physical science and engineering remain the least diverse of all STEM fields---with regard to women, underrepresented minorities, and persons with disabilities---across all levels of STEM education and training. SCI-STEPS is an NSF INCLUDES Design and Development Launch Pilot that will address this persistent challenge by developing a complete end-to-end pipeline (or system of pathways) from the beginning of college to the PhD, and then into the workforce. Many isolated efforts to broaden participation have shown promise, but they have not produced big enough impact. SCI-STEPS represents a concerted set of coordinated interventions---consciously facilitated, systemically linked, and purposefully disseminated. SCI-STEPS represents a broad regional network among major research universities, Historically Black Colleges and Universities, comprehensive universities, community colleges, national labs, and major scientific organizations. The goal of the network is to ensure that underrepresented individuals in the physical sciences and engineering can get from their starting point in STEM higher education---freshmen at 2-year or 4-year college---through the higher education pathways leading to an appropriate terminal degree and employment in the STEM workforce.
Women, underrepresented minorities, and persons with disabilities collectively represent the majority of college-age individuals entering higher education with an expressed interest in physical science and engineering. A growing body of research indicates that academic and social integration may be even more influential than academic abilities for retention of students. Thus, interventions aimed at stemming the losses of these individuals must ultimately be aimed at changing the system---including unwelcoming institutional climates, racial/ethnic/gender stereotyping, a lack of mentors with whom to identify, and evaluation methods that emphasize conformity over individual capabilities---rather than changing the individual. The SCI-STEPS pilot focuses effort on institutional readiness for implementation of best practice interventions at four key junctures: (i) college freshman to sophomore; (ii) undergraduate to graduate; (iii) PhD to postdoc; and (iv) postdoc to workforce.The pilot will proceed in three steps: (1) a planning phase, (2) development of an initial end-to-end pathways model with four Juncture Transition teams, and (3) scale-up of the SCI-STEPS "network of networks" with all initial partners. By addressing these objectives through a collective impact framework and embedded research, this pilot will demonstrate how best-practice interventions at each pathway juncture can be dovetailed and scaled up across a broad range of institutional types and across a large but distinct geographical area. Addressing these objectives will thus also serve to advance Broadening Participation efforts at a national scale, by suggesting the forms of institutional partnerships and best-practices that may inform other alliances in other STEM disciplines and/or different regional areas.
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TEAM MEMBERS:
Keivan StassunNicole JosephKelly Holley-BockelmannWilliam RobinsonRoger Chalkley
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.
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TEAM MEMBERS:
Folashade Cromwell SolomonTracey WrightLawrence Pratt
A partnership between Carthage College and the Appalachian Mountain Club has delivered a successful public education and outreach program that merges natural environment topics and astronomy. Over the four years of activity, over 25,000 people have received programming. The effort has trained nature educators, permanent and seasonal AMC staff, and undergraduate physics and astronomy students to integrate diverse topical material and deliver high quality programming to the lay public. Unique to the program is the holistic nature of the material delivered - an 'atypical' astronomy program. Linking observable characteristics of the natural world with astronomical history and phenomena, and emphasizing the unique sequence of events that have led to human life on Earth, the program has changed attitudes and behaviors among the public participants. Successful interventions have included hands-on observing programs (day and night) that link nature content to the observed objects; table-talk presentations on nature/astronomy topics; dark skies preservation workshops; and hands-on activities developed for younger audiences, including schools, camps, and family groups. An extensive evaluation and assessment effort managed by a leading sociologist has demonstrated the effectiveness of the approach, and contributed to continuous improvement in the program content and methods.
Making Stuff Season Two is designed to build on the success of the first season of Making Stuff by expanding the series content to include a broader range of STEM topics, creating a larger outreach coalition model and a “community of practice,” and developing new outreach activities and digital resources. Specifically, this project created a national television 4-part miniseries, an educational outreach campaign, expanded digital content, promotion activities, station relations, and project evaluation. These project components help to achieve the following goals: 1. To increase public understanding that basic research leads to technological innovation; 2. To increase and sustain public awareness and excitement about innovation and its impact on society; and 3. To establish a community of practice that enhances the frequency and quality of collaboration among STEM researchers and informal educators. These goals were selected in order to address a wider societal issue, and an important element of the overall mission of NOVA: to inspire new generations of scientists, learners, and innovators. By creating novel and engaging STEM content, reaching out to new partners, and developing new outreach tools, the second season of Making Stuff is designed to reach new target audiences including underserved teens and college students crucial to building a more robust and diversified STEM workforce pipeline. Series Description: In this four-part special, technology columnist and best-selling author David Pogue takes a wild ride through the cutting-edge science that is powering a next wave of technological innovation. Pogue meets the scientists and engineers who are plunging to the bottom of the temperature scale, finding design inspiration in nature, and breaking every speed limit to make tomorrow's "stuff" "Colder," "Faster," "Safer," and "Wilder." Making Stuff Faster Ever since humans stood on two feet we have had the basic urge to go faster. But are there physical limits to how fast we can go? David Pogue wants to find out, and in "Making Stuff Faster," he’ll investigate everything from electric muscle cars and the America’s cup sailboat to bicycles that smash speed records. Along the way, he finds that speed is more than just getting us from point A to B, it's also about getting things done in less time. From boarding a 737 to pushing the speed light travels, Pogue's quest for ultimate speed limits takes him to unexpected places where he’ll come face-to-face with the final frontiers of speed. Making Stuff Wilder What happens when scientists open up nature's toolbox? In "Making Stuff Wilder," David Pogue explores bold new innovations inspired by the Earth's greatest inventor, life itself. From robotic "mules" and "cheetahs" for the military, to fabrics born out of fish slime, host David Pogue travels the globe to find the world’s wildest new inventions and technologies. It is a journey that sees today's microbes turned into tomorrow’s metallurgists, viruses building batteries, and ideas that change not just the stuff we make, but the way we make our stuff. As we develop our own new technologies, what can we learn from billions of years of nature’s research? Making Stuff Colder Cold is the new hot in this brave new world. For centuries we've fought it, shunned it, and huddled against it. Cold has always been the enemy of life, but now it may hold the key to a new generation of science and technology that will improve our lives. In "Making Stuff Colder," David Pogue explores the frontiers of cold science from saving the lives of severe trauma patients to ultracold physics, where bizarre new properties of matter are the norm and the basis of new technologies like levitating trains and quantum computers. Making Stuff Safer The world has always been a dangerous place, so how do we increase our odds of survival? In "Making Stuff Safer," David Pogue explores the cutting-edge research of scientists and engineers who want to keep us out of harm’s way. Some are countering the threat of natural disasters with new firefighting materials and safer buildings. Others are at work on technologies to thwart terrorist attacks. A next-generation vaccine will save millions from deadly disease. And innovations like smarter cars and better sports gear will reduce the risk of everyday activities. We’ll never eliminate danger—but science and technology are making stuff safer.
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TEAM MEMBERS:
WGBH Educational FoundationPaula Apsell
The Magnet Lab has a strong commitment to education. Through the Center for Integrating Research & Learning, the lab supports educational programming at all academic levels: K-12, technical, undergraduate, graduate and postdoctoral. Please explore the links listed to the left to find out more about the depth of our educational resources for the community, for teachers and for students as well as our unique research offerings. Our programs are designed to excite and educate students, teachers and the general public about science, technology and the world around them. All of our programs are developed in close collaboration with research scientists and educators. Housed at and partly funded by the MagLab, the Center is uniquely positioned to take advantage of the excellent resources, connections, world-class facilities and cutting-edge science the lab has to offer. We also receive generous support from the National Science Foundation and the State of Florida. The Center maintains a rigorous research agenda designed to investigate how Center programs and materials affect teachers and students. Our Mission Statement is to expand scientific literacy and to encourage interest in and the pursuit of scientific studies among educators and students of all ages through connections between the National High Magnetic Field Laboratory and the National Science Foundation, the community of Tallahassee, the State of Florida and the nation.
The goal of this outreach program was for Chemistry at the Space-Time (CaSTL) limit to partner with the Boys and Girls Club (BGC) of Santa Ana, CA to increase their participants' interest, enthusiasm and learning outcomes in Science Technology Engineering and Math (STEM) fields, through the development of science and chemistry hands-on lessons. The Boys and Girls Club of Santa Ana serves nearly 2,700 participants each day at six sites. Ninety percent of their participants identify as Hispanic/Latino and 93% are on free or reduced lunch. Although the Boys and Girls Club offers limited STEM activities, they agreed to partner with CaSTL, a UC-Irvine NSF-funded Center for Chemical Innovation, to expand their STEM ISE activities. CaSTL, in close collaboration with both the California Science Project of Irvine (CSPI), developed 24 science lesson plans that engage participants in high-level, hands-on, and interactive lessons that expose program participants to the visualization of chemistry and physics, based on CaSTL's mission. All lessons align with the California Science Standards, are highly interactive, and do not mimic the school day. These lessons compliment the state standards, but go much further in providing the participants experimental, hands-on activities that they often do not receive in their schools, due to budget, space and time restrictions. CaSTL faculty and graduate students ensured that the lens through which CaSTL research occurs was clearly represented in the lessons. CaSTL graduate students developed one of the lessons and kit and taught the spectroscopy lesson at the club.
The importance of reporting current science to the general public is more important now than ever before. The best way to ensure enthusiastic support for science is to engage the general public as directly as possible. Unlike schooling, learning in a museum is self-motivated, self-directed, and can be lifelong. The partnership between Columbia University's MRSEC (Materials Research Science and Engineering Center) and the New York Hall of Science will do this in an exciting manner by development of innovative 'rolling exhibits' (Discovery Carts) that are visually attractive, intellectually stimulating and demonstrate current research. This project will unite a dynamic University research faculty, dedicated graduate students, and high school teachers from one of the largest and best known teacher research experience programs in the country. NY Hall of Science, specialists in public science education, have developed exhibitions, over the past 20 years, for school and family group visitors in biology, chemistry and physics. Most recently, the Hall opened an 800-foot biochemistry discovery lab featuring ten experiments that teach visitors about the role of molecules in everyday life. The lab is facilitated by an explainer, and hundreds of families use the lab throughout the year. All exhibits and programs have rigorous science presented in an engaging manner in an educationally non-threatening environment. Columbia University is one of the premier research institutions in the country. Columbia's MRSEC is engaged in multi-faceted educational outreach activities in the New York metropolitan area, including a close working relationship with Columbia's 16 year old RET program. Together these institutions are well situated to involve the research community in public education activities that will inform the public about the current advances in science. Teachers and graduate students who have worked in MRSEC labs will assist in bringing new skills and ideas to the development of museum programming and exhibits. The teachers have experienced both the research projects first-hand and have had the experience in translating the research into meaningful classroom activities for their students. The graduate students have worked alongside the teachers, assisting them in making the research meaningful to high school students. Broader Impact: Highly skilled educators who can improve a young person's chances for success are like gold for the nation's schools, which are under pressure for tough accountability standards. Teachers will influence over a thousand students during the course of their careers. The Hall's Explainers are of high school and college age. These two groups will have positive impacts on our society for years to come. They will benefit from participation, and the tens of thousands of visitors to the museum will learn about cutting edge research.
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.