It’s a simple idea. Introduce a kid to a scientist, and let the child ask questions—whatever they wonder about. Then ask the child to reflect a little on the conversation when it’s over by drawing a picture or writing a few words. This is the gist of Science Storytellers, a program founded by freelance science writer Jennifer Cutraro. At the ACS national meeting in Boston last month, C&EN partnered with Science Storytellers to bring this program to the ACS Kids Zone event held at the Boston Children’s Museum. Modeled after the approach professional journlists use in their work, Science
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
The project team is developing a prototype of a web-based game utilizing the illustrations of chemical elements and science terms created by Simon Basher in his three books, The Periodic Table: Elements with Style!, Chemistry: Getting a Big Reaction!, and Physics: Why Matter Matters! The game will incorporate augmented reality (person-to-person gameplay with the support of the software) to teach grade 4 to 6 students science concepts, including an introduction to chemistry. The game will include curriculum support materials. Pilot research in Phase I will seek to demonstrate that the software prototype functions as planned, teachers are able to integrate it within the classroom environment, and students are engaged with the prototype.
Purpose: This project will develop and test Happy Atoms, a physical modeling set and an interactive iPad app for use in high school chemistry classrooms. Happy Atoms is designed to facilitate student learning of atomic modeling, a difficult topic for chemistry high school students to master. Standard instructional practice in this area typically includes teachers using slides, static ball and stick models, or computer-simulation software to present diagrams on a whiteboard. However, these methods do not adequately depict atomic interactions effectively, thus obscuring complex knowledge and understanding of their formulas and characteristics.
Project Activities: During Phase I (completed in 2014), the team developed a prototype of a physical modeling set including a computerized ball and stick molecular models representing the first 17 elements on the periodic table and an iPad app that identifies and generates information about atoms. A pilot study at the end of Phase I tested the prototype with 187 high school students in 12 chemistry classes. Researchers found that the prototype functioned as intended. Results showed that 88% of students enjoyed using the prototype, and that 79% indicated that it helped learning. In Phase II, the team will develop additional models and will strengthen functionality for effective integration into instructional practice. After development is complete, a larger pilot study will assess the usability and feasibility, fidelity of implementation, and promise of Happy Atoms to improve learning. The study will include 30 grade 11 chemistry classrooms, with half randomly assigned to use Happy Atoms and half who will continue with business as usual procedures. Analyses will compare pre-and-post scores of student's chemistry learning, including atomic modeling.
Product: Happy Atoms will include a set of physical models paired with an iPad app to cover high school chemistry topics in atomic modeling. The modeling set will include individual plastic balls representing the elements of the periodic table. Students will use an iPad app to take a picture of models they create. Using computer-generated algorithms, the app will then identify the model and generate information about its physical and chemical properties and uses. The app will also inform students if a model that is created does not exist. Happy Atoms will replace or supplement lesson plans to enhance chemistry teaching. The app will include teacher resources suggesting how to incorporate games and activities to reinforce lesson plans and learning.
This poster was presented at the 2014 AISL PI Meeting in Washington DC. It describes the CLUES project that provides STEM education opportunities to families.
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TEAM MEMBERS:
New Jersey Academy for Aquatic SciencesBarbara Kelly
This poster, presented at the 2014 AISL PI Meeting, shows the impact of an afterschool program that brought hands-on, inquiry-based science to ELL students in a low SES area of Southern California. Data sources included observation of lessons, interviews with students, and collection of student work Results demonstrate a shift in student thinking around students' internalization of becoming a scientist and who is capable of being a scientist.
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TEAM MEMBERS:
University of California, IrvineLauren Shea
Participants in Kitchen Science Investigators, an afterschool program for middle school students, learn science through cooking, baking, and experimenting with recipes. In-depth case studies analyzed how and why girls begin to scientize, or see their worlds through a scientific lens, and how the program structure supported this shift.
This poster was presented at the 2014 AISL PI Meeting in Washington, DC. It describes an EAGER project that conducts ongoing experiments on the chemical precursors to life as exhibit experiences in partner venues.
A team from Michigan State University, in partnership with six science, art-science, and art museum venues around the country and with the assistance of researchers at Georgia Institute of Technology, is implementing an EAGER project to conduct ongoing experiments on the chemical precursors to life as exhibit experiences for visitors to these venues. The experiments, to be run over the course of several months as the exhibit travels around the country, expand on the 1950s' work of Stanley Miller and Harold Urey, which continues to stimulate new investigations and publications, including experiments being conducted on the International Space Station. The experiments/exhibits share key features across the three different kinds of venues, allowing the team to study and compare the impacts on the various publics of engaging them in real-time science experiments. Two major goals are (1) to explore new ways to attract public interest in science by performing in public settings previously untried experiments on the chemical precursors to life, and (2) to investigate how the context of different kinds of venues and their visitor characteristics affect how visitors interpret the experience and what they learn. The team is also exploring how various data visualization representations can be designed to foster public interest and understanding. The intent is to develop an approach that has potential applications to other STEM content domains and expanding the reach to broader public audiences.
Small Matters is a scientific storytelling project in response to a supplemental funding opportunity designed to pair an NSF Center for Chemical Innovation with an Informal Science Education organization. Meisa Salaita, Director for Education & Outreach for the Center for Chemical Evolution, and Ari Daniel, independent radio and multimedia producer and science journalist, collaborated on this project designed to increase chemical literacy in the general public and promote partnerships between scientists and informal science educators. In the tradition of folklore, educators have used storytelling to stimulate students’ critical thinking skills across and within disciplines, demonstrating an improvement in comprehension and logical thinking, enhancing memory, and creating a motivation and enthusiasm for learning. Within science, storytelling allows learners to experience the how of scientific inquiry, including the intellectual and human struggles of the scientists who are making discoveries. Accordingly, our project uses multimedia and live performance to engage the public in learning about chemistry through storytelling. We have developed a series audio pieces entitled Small Matters aimed at enriching public science literacy, namely within the chemical sciences. The format of these pieces includes standard public radio narrative style, short scientist-narrated nuggets, and imaginative sonic explorations of key chemistry concepts. The stories have been disseminated through a variety of broadcast media connections, including "Living on Earth" and local Atlanta public radio station WABE. In addition to the audio-based science journalism pieces that we have been producing, we have taken the stories we uncovered and brought them to live audiences, integrating chemistry, journalism, and the arts to create a human connection between our scientists and the public. The radio pieces were woven in with performances of poetry, comedy and satire in collaboration with literary performing arts group The Encyclopedia Show to create a live variety show (May 2013). In addition, scientists identified through our production of Small Matters were trained in storytelling techniques and brought together for an evening of live storytelling in Atlanta with The Story Collider (March 2014).
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TEAM MEMBERS:
NSF/NASA Center for Chemical EvolutionMeisa Salaita
In this paper we report on teachers' and students' participation in authentic science research in out of school time science clubs at elementary schools. In the program four to five teachers worked alongside practicing scientists as part of their research groups. Each teacher facilitated a club with 10-15 students who, by extension, were members of the scientists' research groups. Over the 3 years of the project nearly 30 teachers and over 500 children participated in the clubs. In this paper we present a case study of teachers and children who worked with an analytic chemist at a major
This award continues funding of a Center to conduct research and education on the interactions of nanomaterials with living systems and with the abiotic environment. The goals of this Center are to develop a predictive understanding of biological and ecological toxicology for nanomaterials, and of their transport and transformation in the environment. This Center engages a highly interdisciplinary, multi-institutional team in an integrated research program to determine how the physical and chemical properties of nanomaterials determine their environmental impacts from the cellular scale to that of entire ecosystems. The research approach promises to be transformative to the science of ecotoxicology by combining high throughput screening assays with computational and physiological modeling to predict impacts at higher levels of biological organization. The Center will unite the fields of engineering, chemistry, physics, materials science, cell biology, ecology, toxicology, computer modeling, and risk assessment to establish the foundations of a new scientific discipline: environmental nanotoxicology. Research on nanomaterials and development of nanotechnology is expanding rapidly and producing discoveries that promise to benefit the nation?s economy, and improve our ability to live sustainably on earth. There is now a critical need to reduce uncertainty about the possible negative consequences of nanomaterials in the environment, while at the same time providing guidelines for their safe design to prevent environmental and toxicological hazards. This Center addresses this societal need by developing a scientific framework of risk prediction that is paradigm-shifting in its potential to keep pace with the commercial expansion of nanotechnology. Another impact of the Center will be development of human resources for the academic community, industry and government by training the next generation of nano-scale scientists, engineers, and regulators to anticipate and mitigate potential future environmental hazards of nanotechnology. Partnerships with other centers will act as powerful portals for the dissemination and integration of research findings to the scientific, educational, and industrial communities, both nationally and internationally. This Center will contribute to a network of nanotechnology centers that serve the national needs and expand representation and access to this research and knowledge network through programs directed at California colleges serving underrepresented groups. Outreach activities, including a journalist-scientist communication program, will serve to inform both experts and the public at large about the safety issues surrounding nanotechnology and how to safely produce, use, and dispose of nanomaterials.
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TEAM MEMBERS:
Andre NelYoram CohenHilary GodwinArturo KellerPatricia Holden