The most important consideration in evaluating chemistry outreach efforts is how to best use the evaluation to serve project needs. Evaluation should be about making programs more effective—at communicating ideas, changing attitudes, inspiring action, or reaching wider audiences, for example. A well-conducted evaluation typically contributes to the quality of a project by helping its leaders better define their goals, identify important milestones and indicators of success, and use evidence to support ongoing improvements. At its best, evaluation is an integral part of project design and
The National Research Council’s (NRC) Board on Chemical Sciences and Technology (BCST) and Board on Science Education (BOSE) received funding from the National Science Foundation (NSF) to develop a framework for effective chemistry communication, outreach, and education in informal settings, with the ultimate goal of increasing the effectiveness of such efforts in engaging the public with chemistry. BCST and BOSE are assembling a committee of experts to execute this work. To support their efforts, BCST and BOSE also commissioned this landscape study, which serves as background for the
The National Academies of Sciences' Board on Chemical Sciences and Technology (BCST) and Board on Science Education (BOSE) are collaborating on a three-year project to develop a framework for effective chemistry communications, outreach, and education in informal settings. The initiative will include a "landscape" study that will synthesize lessons learned from practice along with education and learning science research about chemistry learning and teaching in informal and formal settings. The overall process will define a set of principles for engaging the public with chemistry and embed these principles into a broad framework that chemists and informal science education professionals could use to identify a set of effective strategies for a given audience and a given educational or communication goal. The guidance and tools resulting from this activity, which is a chemistry-specific case study, should be more generally applicable to science and engineering communications, informal education and outreach. Findings are also likely to apply to aspects of formal education.
The mission of the New Mexico Informal Science Education Network (NM ISE Net) is to provide opportunities and resources for informal educators to work together to impact science teaching, science learning, and science awareness throughout the state of New Mexico. The NM Museum of Natural History and Science leads NM ISE Net with support from NM EPSCoR.
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TEAM MEMBERS:
New Mexico Museum of Natural HistorySelena ConnealyCharlie Walter
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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WGBH Educational FoundationPaula Apsell
CENTC's (Center for Enabling New Technologies Through Catalysis) outreach is focused on partnerships with science centers. Initially we worked with the Pacific Science Center (PSC) to train our students in effective communication of science concepts to public audiences. Later we developed a short-term exhibit, Chemist - Catalysts for Change in the Portal to Current Research space. As part of the CCI/AISL partnership program, we partnered with Liberty Science Center to create an activity on a multi-touch media table, "Molecule Magic." We are currently developing another exhibit with PSC.
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.
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.