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.
The Education and Outreach (EO) program is an essential part of the CRISP MRSEC located at Yale and SCSU. CRISP offers activities that promote the interdisciplinary and innovative aspects of materials science to a diverse group of participants. The objective of the program is to enhance the education of future scientists, science teachers, K-12 students, parents, and the general public. CRISP’s primary informal science activities include public lectures, family science nights, New Haven Science Fair and museum partnerships.
The LTER Network is an innovative platform for training the next generation of natural scientists in collaborative, integrative, long-term research in ecology. An important objective of the network is to share knowledge with other communities. The LTER Network Office addresses this objective by managing a Communication and Outreach program that targets key communities—scientists, policy makers, educators and students, and the mass media as a proxy of the rest of the non-specific audiences—and maintain strategic partnerships and collaborations that provide improved access to these communities.
The National Science Foundation and other funding agencies are increasingly requiring broader impacts in grant applications to encourage US scientists to contribute to science education and society. Concurrently, national science education standards are using more inquiry-based learning (IBL) to increase students’ capacity for abstract, conceptual thinking applicable to real-world problems. Scientists are particularly well suited to engage in broader impacts via science inquiry outreach, because scientific research is inherently an inquiry-based process. We provide a practical guide to help
DATE:
TEAM MEMBERS:
Lisa KomoroskeSarah HameedAmber SzoboszlaiAmanda NewsomSusan Williams
The C-DEBI education program works with audiences at all levels (K-12, general public, undergraduate, graduate and beyond) in formal and informal settings (courses, public lectures, etc.). Sub-programs focus on community college research internships and professional development for graduate students and postdocs.
The Saint Louis Science Center (SLSC) project Bridging Earth and Mars (BEAM) will engage the general public and children from schools and community groups with the National Aeronautical and Space Administration’s (NASA’s) exploration of Mars through exhibits simulating control of robotic rovers on the surface of Mars as well as related educational programming. This front-end evaluation for BEAM youth programs provides information to the BEAM project team about the levels of knowledge, attitudes, and skills among low-income and minority young people who are part of the field trip workshop
DATE:
TEAM MEMBERS:
Saint Louis Science CenterCarey Tisdal
Connected learning is an educational approach designed to make learning relevant to students, creating a deeper form of learning and understanding that will help students become life-long learners who will grow and thrive in school, work and life. Afterschool programs have long been implementing this approach that ties together students interests, peer networks and academic pursuits. This report explores the benefits of using a connected learning approach, the variety of ways afterschool programs are offering connected learning opportunities to engage students in learning, and shares ideas on
There can be a mistaken impression that the new vision for K-12 science education is only relevant to classroom science instruction. But youth frequently engage in powerful science and engineering activities that take place after or outside-of-school. They learn STEM content, engage in STEM practices, and develop an understanding of how STEM is used in the world. To capitalize on those assets, educators and other stakeholders should learn about, leverage, and broker connections for youth across the STEM learning experiences available in and out of school.
Our Center works with students from kindergarten through graduate school and beyond. We work with teachers and scientists and combine our knowledge to inspire students to pursue careers in neural engineering and neuroscience. Program activities include summer research programs, curriculum development, school visits, teacher/student workshops, science festivals, and international student exchanges.
DATE:
-
TEAM MEMBERS:
University of WashingtonEric Chudler
The project will develop and study the impact of science simulations, referred to as sims, on middle school childrens' understanding of science and the scientific process. The project will investigate: 1) how characteristics of simulation design (e.g., interface design, visual representations, dynamic feedback, and the implicit scaffolding within the simulation) influence engagement and learning and how responses to these design features vary across grade-level and diverse populations; 2) how various models of instructional integration of a simulation affect how students interact with the simulation, what they learn, and their preparation for future learning; 3) how these interactions vary across grade-level and diverse populations; and 4) what critical instructional features, particularly in the type and level of scaffolding, are needed. Working with teachers, the team will select 25 existing sims for study. Teachers and students will be interviewed to test for usability, engagement, interpretation, and learning across content areas. The goal will be to identify successful design alternatives and to formulate generalized design guidelines. In parallel, pull-out and classroom-based studies will investigate a variety of use models and their impact on learning. Ten new simulations will then be developed to test these guidelines. Products will include the 35 sims with related support materials available for free from a website; new technologies to collect real-time data on student use of sims; and guidelines for the development of sims for this age population. The team will also publish research on how students learn from sims.
DATE:
-
TEAM MEMBERS:
Katherine PerkinsDaniel SchwartzMichael DubsonNoah Podolefsky
This project will study two emerging and innovative technologies: interactive, dynamic simulations and touch-based tablet devices. The use of touch-based tablet technology (e.g., iPads) in the classroom is rapidly increasing, though little research has been done to understand effective implementation for learning science. Interactive simulations are now in use across K-16 levels of education, though what impact tablet devices have on the effective implementation of science simulations is not yet known. This project will explore this new frontier in education, over a range of contexts, providing new insight into effective interactive simulation design, classroom facilitation techniques, and the effects of tablet-based simulation use on underrepresented populations in STEM courses. Together, Dr. Emily Moore (PhET, UCB), a leader in interactive simulation design and classroom use, and Dr. Roy Tasker of the University of Western Sydney (UWS), a leader in chemistry education research, science visualizations, and teaching with technology, will research on the new technology frontier in science education - laying the groundwork for future investigations of foundational questions in technology use for learning science. This work has great potential to transform the future of science learning, making it both more engaging and more effective for diverse populations. The research findings will immediately impact 1) the design of new and existing PhET simulations - reaching millions of students and teachers using PhET simulations worldwide - and 2) the development of best practices guidelines for teachers using tablet technology to increase student learning, engagement, and participation in STEM disciplines.
This project develops an interdisciplinary and transformative in- and out of-school science education and technology program that engages high school aged youth and their teachers in 1) the production of food using hydroponics, and 2) the use of green energy technologies (solar, and wind) to power hydroponic systems. This distinctive program integrates food production, a novel model of parental outreach, a focus on green career development, and an authentic reason (growing their own produce for selling at a market) for learning how and why to use alternative energy technologies. The project creates an approach to sustainability in which students not only give back to their community, but are in a position to provide a continuous revenue stream to the school in order to operate their indoor urban garden indefinitely. The partnership with the Boston Youth Environmental Network provides youth opportunities for summer internships with green energy companies. The project builds upon a learning progressions model in which youth gradually learn about complex scientific systems and economic principles throughout their years in the program. Rather than a onetime experience, youth are engaged in a long-term experience building their knowledge and skills regarding science, economics, and college preparedness. This project has the potential to impact thousands of students informally and over 2000 students (in classrooms) directly with a minimum of 60 students receiving focused and in depth learning experiences during the summer and on weekends during the school year. With the passage of laws encouraging local schools to partner with local farms, the need for locally grown produce will increase; in that context, the program brings the farm to the school in a way that allows food to be grown year round. Thus, a model is developed that any school or informal learning center could adopt to grow their own food while simultaneously creating a living and learning laboratory for youth in their own program.
DATE:
-
TEAM MEMBERS:
George BarnettEric StraussDavid BlusteinCatherine WongElizabeth Bagnani