This paper provides an interesting insight into how educators can support learners in coming to understand the nature of matter. Whilst the specific focus is on students’ implicit assumptions and reasoning strategies in a particular domain, the broader discussion exploring the differences between novice and expert thinking is relevant to all educators seeking to support learners to engage with new content.
This Pathways Project connects rural, underserved youth and families in Eastern Washington and Northern Idaho to STEM concepts important in sustainable building design. The project is a collaboration of the Palouse Discovery Science Center (Pullman, WA), Washington State University and University of Idaho, working in partnership with rural community organizations and businesses. The deliverables include: 1) interactive exhibit prototype activities, 2) a team cooperative learning problem-solving challenge, and (3) take-home materials to encourage participants to use what they have learned to investigate ways to make their homes more energy-efficient and sustainable. The project introduces youth and families to the traditionally difficult physics concept of thermal energy, particularly as it relates to sustainable building design. Participants explore how building materials and their properties can be used to control all three types of heat transfer: conduction, convection, and radiation. The interactive exhibit prototypes are coupled with an Energy Efficient Engineering Challenge in which participants, working in cooperative learning teams, use information learned from the exhibit prototype activities to retrofit a model house, improving its energy efficiency. The project components are piloted at the Palouse Discovery Science Center, and then travel to three underserved rural/tribal communities in Northern Idaho and Eastern Washington. Front-end and formative evaluation studies will demonstrate whether this model advances participant understanding of and interest in STEM topics and careers. The project will yield information about ways that other ISE practitioners can effectively incorporate cooperative learning strategies in informal settings to improve the transferability of knowledge gained from exhibits to real-world problem-solving challenges, especially for rural and underserved audiences. This project will also provide the ISE field with: 1) a model for increasing the capacity of small, rural science centers to form collaborative regional networks that draw on previously unused resources in their communities and provide more effective outreach to the underrepresented populations they serve, and 2) a model for coupling cooperative learning with outreach exhibits, providing richer experiences of active engagement.
The idea that there are models in existence for electricity and how to improve its generation and utilization is an important quest in light of our resources. This CRPA project will stimulate the target audience\'s thinking by describing the relationships between electricity, nanoscience, and superconductivity. An audience of 4th-8th graders, parents, and teachers will come away from watching the video with a new sense of science and its possibilities. This project is a collaboration between physics faculty, educators at the University of Kansas Natural History Museum, a communications professional, and the Bazillion Pictures of Kansas City, Missouri along with independent evaluators. An animated video of 8-10 minutes is intended to engage, entertain, and provoke thought on how electricity works and how it could be used/generated in nano-molecules to derive superconductivity. Most individuals turn on the electrical switch and use the result without the slightest understanding of how electricity arrived at the switch, how it was generated and what resources are needed for it to be there at the "flip of a switch." Further, most do not consider or have sufficient background knowledge to understand how the efficiency and use of this resource might be improved. This project could bridge this gap which if successful would be highly transformative in the public understanding of science.
The New York Hall of Science, in collaboration with the Tufts Center for Engineering Education, the Learning Games Network, and New York City departments of education and of parks and recreation, is creating and testing two innovative science games to support student learning about frictional force and linear motion. SciGames integrates rigorous, highly motivating, data collection activities conducted in museum and playground settings, with in-depth data analysis and additional scientific investigation in the classroom. The primary goals of the SciGames project are to increase student motivation and interest in science and improve student learning about core physical science concepts. This exploratory project targets underrepresented urban students and their teachers from 20 schools in New York City (NYC) and through its partnership with NYC department of parks and recreation has great potential for scale-up throughout NYC, as well as dissemination to other urban communities. The SciGames model creates experiences for students that build on the positive, fun, free-choice learning characteristics of informal settings; promotes learning through repeated game-like experimentation and play; and supports students' sustained interest and learning in science classrooms where core concepts are formalized. The project is based on four design principles: (1) SciGames turns students' informal experiences into a game, (2) SciGames makes science content an integral part of game play, (3) SciGames generates data for further analysis during game play, and (4) SciGames, through the use of digital apps, supports students inquiring into data back in their classrooms. Researchers are developing the games using rigorous, well constructed, iterative cycles of design, development, testing, evaluation, and revision with different groups of NYC students and teachers. Pre and post data on students\' science learning and affect are being used to inform the design cycles. Over a two-year period, SciGames will produce two science games and associated digital apps, and a portable kit that supports game implementation, data collection and analysis. SciGames is an important experiment, combining the informal, engaging aspects of play with more formal science investigation to encourage and sustain the interest, participation, and learning of underrepresented students in STEM. This project has the potential to transform how we think of and structure science learning for middle school students.
The objective of this youth media project is to provide 14-24 year olds with training and hands-on experience in engineering, and the physical and biological sciences. The project is designed around core practices that engage youth in original research and inquiry through experimentation, development, and creative use of new technologies and tools to communicate STEM to the public. Youth Radio project participants in Oakland, CA, Atlanta, GA and Washington, DC include 540 youth, 80% of whom are low-income and/or youth of color, plus another 400 youth via off-site outreach in schools and community centers. Core deliverables include: (1) "Brains and Beakers," eight live events per year where a visiting STEM researcher brings his/her work out of the lab and onto the stage at Youth Radio facilities, demonstrating key principles and discoveries and interacting with youth participants; (2) "Youth Radio Investigates," an annual 6-part multimedia series, where youth partner with university and industry-based researchers to explore the veracity of scientific claims applied to products and services and they use every day; (3) The "Application Development Lab," where youth develop, create and disseminate online embeddable and downloadable applications (12 annually) that serve real needs in youth communities. The digital media produced by the youth will be broadcast by National Public Radio and distributed online through various sites including iTunes and BoingBoing.net, one of the most frequently visited technology-focused sites on the web. Project advisors include STEM researchers in universities as well as highly experienced and successful new media technology developers. Project partners include National Public Radio, KQED, the California Academy of Sciences, and the Oakland Unified School District. This project builds on the successful prior work (NSF #0610272) that initiated a Science and Technology program within the Youth Radio organization. The summative evaluation by Rockman et al will measure how the program affects students' science and technology knowledge, skills, and attitudes. It will build on the evaluation from the prior NSF funded project (#0610272) that highlighted the organizational and staff growth processes as Youth Radio discovered how to design and implement successful, sustainable STEM programs. Rockman will evaluate the new programs (Youth Investigates, Brains and Beakers, and the Application Lab), measuring the following STEM-related student outcomes/impacts: perceptions of selves as producers/creators of science or technology; attitudes toward science and perceptions of scientists; understanding the process of scientific inquiry and research and/or technology skills development; and understanding or interest in careers in science or technology (based on National Research Council report, 2009). Data will be collected from the youth at the Oakland site and from the other Youth Radio bureaus to determine which aspects of the program transfer to multiple sites and which ones are unique to a specific location or set of circumstances. Methods include surveys of student attitudes, participant focus groups, interim assessments, objective skills assessments, and interviews. This project provides an innovative new model for collaborations between STEM researchers and under-represented youth resulting in digital media that impacts the youth as well as the public's understanding and engagement in science.
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Ellin O'Leary
resourceprojectProfessional Development, Conferences, and Networks
The proposed CAREER study uses a comprehensive mixed-methods design to develop measures of motivational beliefs and family supports for Spanish and English speaking Mexican-origin youth in high school physical science. The research examines a three-part model which may provide a deeper understanding of how Mexican families support youth through their general education strategies, beliefs about physical science, and science specific behaviors. This approach incorporates motivation and ecodevelopmental theories while pursuing an innovative line of research that examines how the contributions of older siblings and relatives complement or supplement parental support. The study has four aims which are to (1) to develop reliable, valid measures of Mexican-origin adolescent motivational beliefs and family supports in relation to high school chemistry and physics, (2) to test whether family supports predict motivational beliefs and course enrollment, (3) to test how indicators in Aim 2 vary based on gender, culture, English language skills and relationship quality, and (4) to examine how family supports strengthen or weaken the relationship between school-based interactions (teachers and peer support) and the pursuit of physical science studies. Spanish and English-speaking Mexican-origin youth will participate in focus groups to inform the development of a survey instrument which will be used in a statistical measurement equivalence study of 300 high school students in fulfillment of Aim 1. One hundred and fifty Mexican high school students and their families will participate in a longitudinal study while students progress through grades 9-12 to examine Aims 2- 4. Data to be collected includes information on science coursework, adolescent motivational beliefs, supports by mothers and older youth in the family, and family interactions. All materials will be in English and Spanish. The educational and research integration plan uses a three pronged approach which includes mentoring of doctoral students, teacher outreach, and the evaluation of the ASU Biodesign high school summer internship program using measures resulting from the research. It is anticipated that the study findings will provide research-based solutions to some of the specific behaviors that influence youth motivation in physical sciences. Specifically, the study will identify youth that might be most affected by an intervention and the age of maximum benefit, as well as valid, reliable measures of youths' motivation that can used in interventions to measure outcomes. The study will also identify family behaviors that may be influenced, including education strategies for school preparation, beliefs about physical science, and sciece-specific strategies such as engaging in science activities outside school. The findings will be broadly disseminated to science teachers, scholars, and families of Mexican-origin youth. This multi-tiered approach will advance current scholarship and practice concerning Mexican-origin adolescents' pursuit of physical science.
This research project, from The University of Central Florida, and the Museum of Science and Industry, investigates a three-cycle research and development process where middle school student learners will be immersed in a mixed reality environment while interacting with functional metaphors to determine the effects of conceptual change, motivation and scientific habits of mind while engaged in learning physics content. The project is guided by the following research questions: How does the opportunity to embody elements of an immersive simulation affect a learner's propensity to experience conceptual change and develop scientific habits of mind? What design features of missed reality environments best support metaphors? What metrics are most effective for assessing learning through body-based metaphors? What are the practical considerations to creating immersive metaphor-based learning experiences in ISE institutions such as a Science Center? The investigators will use a between subjects mixed method approach with middle school students (N = 360) involving three research cycles that are performed in controlled conditions. The multiple iterations will allow modifications to the study's design to dig deeper into the data and afford more careful analysis, revisions and modifications to simulation content, protocol and data collection instruments and the technology installation. Middle school students will be recruited from local schools and the Museum of Science and Industry visitors. The evaluation plan includes the assessment of perceived values of using whole-body metaphors within mixed reality environments to learn physics. Professional audiences, educators and ISE practitioners will assess the impact, design and content associated with research on learning, mixed reality design, science and physics education. Research on understanding the process of using whole-body interactions in a mixed reality environments will help educational researchers and practitioners in the field understand the effectiveness of metaphor based learning of scientific concepts with whole body interactions. This project contributes knowledge about how people learn within informal settings. This theory-driven design approach has the potential for broad implementation in both formal and informal environments.
In this full-scale research and development project, Oregon State University (OSU), Oregon Sea Grant (OSG) and the Hatfield Marine Science Center Visitors Center (HMSCVC) is designing, developing, implementing, researching and evaluating a cyberlaboratory in a museum setting. The cyberlaboratory will provide three earth and marine science learning experiences with research and evaluation interwoven with visitor experiences. The research platform will focus on: 1) a climate change exhibit that will enable research on identity, values and opinion; 2) a wave tank exhibit that will enable research on group dynamics and problem solving in interactive engineering challenges; and 3) remote sensing exhibits that will enable research on visitor interactions through the use of real data and simulations. This project will provide the informal science educaton community with a suite of tools to evaluate learning experiences with emerging technologies using an iterative process. The team will also make available to the informal science community their answers to the following research questions: For the climate change exhibit, "To what extent does customizing content delivery based on real-time visitor input promote learning?" For the wave tank exhibit, "To what extent do opportunities to reflect on and share experiences promote STEM reasoning processes at a build-and-test exhibit?" For the data-sensing exhibit, "Can visitors' abilities to explain or use visualizations be improved by shaping their visual searches of images?" Mixed-methods using interviews, surveys, behavioral instruments, and participant observations will be used to evaluate the overall program. Approximately 60-100 informal science education professionals will discuss and test the viability of the exhibit's evaluation tools. More than 150,000 visitors, along with community members and local middle and high school students, will have the opportunity to participate in the learning experiences at the HMSCVC. This work contributes to the fields of cyberlearning and informal science education. This project provides the informal science education field with important knowledge about learning, customized content delivery and evaluation tools that are used in informal science settings.
The Nexus of Energy, Water, and Climate: From Understanding to Action (Café +) project will develop and test two interactive board game concepts focused on energy, water, and climate with youth and adults from four highly diverse communities in New Mexico. The four primary goals of the project are to: (a) develop, play test, and implement two board, card, or other non-electronic games grounded in energy, water, and climate content at four project sites, (b) identify the key characteristics of the games that maximize problem solving while stimulating interest, engagement, and learning, (c) explore the implications of game playing on dialog, learning, and Café+ satisfaction for youth and adult participants, and (d) evaluate the viability of this model for full scale implementation throughout the existing Café Scientifique program, from which this project is based. Los Alamos National Laboratory, Sandia National Laboratory, PNM Resources, Scott Balaban Games Design, the Los Alamos County Utilities Department, and a host of advisors and consultants from a broad range of organizations and institutions will collaborate to develop, test, and implement the Café+ games model. The primary deliverables include: (a) two non-electronic multiage commercial quality games focused on energy, water, and climate content, (b) a comprehensive pilot study examining the impact, effectiveness, and viability of the Café+ model with the target audiences, and (c) formative and summative evaluations of the games implementation model. A significant outcome of Café+ is that New Mexico youth and adults, from diverse backgrounds, will learn relevant science content through the development and testing of engaging, innovative commercial quality games. Over 250 youth and adults will benefit directly from their participation in the pilot study. They will not only learn important science content while working collaboratively in groups (youth only and youth/adult groups), but they will also participate in an authentic scientific process experience as playtesters. In this role, youth and adults will experience critical science concepts such as trial and error and refinement. Further, the games will be made publicly available and implemented across the entire Café Scientifique program (n=960 youth). The evaluation study will employ a mixed methods approach to examine project implementation, effectiveness, and impacts. Focus groups, observations, and surveys will be employed to assess a number of variables such as (but not limited to): content knowledge and learning, interest, engagement, game features, game play processes, gaming obstacles and challenges, participant interactions, and motivation. Embedded assessment opportunities will also examine participants\' decision making abilities, analytical skills, and ability to transfer knowledge gained to real world situations as they navigate through the games. Data collected at the youth-only pilot test sites will be used in a comparative analysis of similar variables tracked at the youth and adult sites. Formative approaches will provide iterative, ongoing opportunities for programmatic and game refinement and adjustments. The formative and summative evaluations will endeavor to document critical data and findings needed to assess the viability of Café+ as a full scale development project, with additional games and project sites across the country. The Café+ project would add to the limited literature base on learning and science engagement of youth within Science Café settings in the 21st century. More critically, this pilot study could contribute to the dearth of current research on the impact of non-electronic game play can have on youth only groups and youth/adult groups working collaboratively to make important scientific decisions within Science Café settings. This comparative data could prove significant for other program models interested in implementing similar youth and adult game based program. Further, the relevance of the content could potentially spark youths' interest not only in pursuing courses and careers in STEM, but it could also motivate youth and adult participants to become more involved in civic engagement activities occurring within and beyond their local communities.
The Fusion Science Theater National Training and Dissemination Program builds on the success of the Fusion Science Theater (FST) planning grant (DRL 07-32142). Madison Area Technical College, in collaboration with the Institute for Chemical Education at the University of Wisconsin-Madison, the American Chemical Society (ACS) and area science centers and museums will create a national program to disseminate the FST model which directly engages children in playful, participatory, and inquiry-based science learning of chemistry and physics topics. The primary target audience is children aged 4-11, while undergraduate chemistry students, faculty, and formal and informal educators comprise the secondary professional audience. The project will result in the development of a robust, creative, and highly visible national dissemination program. The National Training and Dissemination Program includes three deliverables. First, a Distance Performance Training Program will be developed to teach groups of undergraduate students, faculty, and educators how to perform FST Science Investigation (SI) Shows. The Training Program includes a Performance Training Package and a 3-day Performance Training Workshop. The Performance Training Package will be comprised of training videos, performances videos, scripts, rehearsal schedules, and training exercises. These materials will be pilot tested while training representatives of five groups from around the country to perform SI Shows during the Performance Training Workshop at Madison Area Technical College in summer 2012. Participants will be selected from ACS undergraduate groups, outreach specialists, and museum professionals. Workshop participants then return to their home institutions and lead their groups through the improved Performance Training Package delivered via Moodle, with support from FST team members and social networking tools. The second deliverable is the FST Methods Workshop. The Methods Workshop is designed to teach formal and informal educators to use selected methods (Investigation Question, Embedded Assessment, and Act-It-Out) in their outreach efforts and classroom teaching. Four workshops will be presented at national meetings and at the invitation of colleges, universities, and science centers. Follow-up with workshop participants will be mediated through an online forum to encourage experimentation, modification, and dissemination of a second generation of FST activities. The final project deliverable is the development and implementation of a Promotion and Recruitment Plan to connect professional audiences with FST. The Distance Performance Training Program and workshops will be evaluated using mixed methods, while embedded assessment will be utilized to measure the impact on youth participants attending SI shows to determine the overall effectiveness the Distance Performance Training. This project is designed to have important impacts on STEM education and society. The proposed dissemination program brings innovative models and methods into the hands of informal science education practitioners who can use them to engage local audiences and enhance their own teaching and communication practices. Finally the project offers likely benefits for society through the creation and dissemination of innovative practices to combat science illiteracy, diminishing pools of scientists and engineers, lack of understanding about the nature of science, and the achievement gap that exacerbates these problems. This project could be transformative in informal science education as SI Shows use theater to engage audiences in multiple aspects of science learning. It is anticipated that this project will reach up to 2,500 individuals in public and professional audiences.
Some of the most intriguing science museum exhibits start with a counter-intuitive outcome, a result that runs counter to visitors' expectations. Although counter-intuitive events often succeed in captivating visitors, they rarely lead to visitor-driven inquiry. The author argues that this is primarily due to two factors: first, for the counter-intuitive effect to be presented reliably and repeatedly, the visitor's interaction must be limited to a narrow set of options. Without multiple options for visitors to explore, extended inquiry is nearly impossible. Second, counter-intuitive outcomes
LIGO's Science Education Center is in charge of Education and Public Outreach Component for the LIGO Livingston Observatory. The three prime efforts are: (1) Professional development for teachers utilizing lab facilities and cross-institute collaborations. (2) Outreach to students K-16 (targeting 5- 9th grade), with on-site field trips to the LIGO Lab and Science Education Center, as well as off-site visits & presentations. (3) Outreach to the general public and community groups with on-site tours and Science Education Center Experience, as well as off=site visits and presentations. LIGO's Science Education Center is located at the LIGO Observatory, and has an auditorium, a classroom and a 5000 square foot exhibit hall with interactive exhibits at its disposal to complete its mission. In addition LIGO-SEC staff serve to help press and documentary film makers complete their missions in telling the "LIGO story" and encouraging budding scientists.