This Integrative Graduate Education and Research Training (IGERT) award supports the establishment of an interdisciplinary graduate training program in Cognitive, Computational, and Systems Neuroscience at Washington University in Saint Louis. Understanding how the brain works under normal circumstances and how it fails are among the most important problems in science. The purpose of this program is to train a new generation of systems-level neuroscientists who will combine experimental and computational approaches from the fields of psychology, neurobiology, and engineering to study brain function in unique ways. Students will participate in a five-course core curriculum that provides a broad base of knowledge in each of the core disciplines, and culminates in a pair of highly integrative and interactive courses that emphasize critical thinking and analysis skills, as well as practical skills for developing interdisciplinary research projects. This program also includes workshops aimed at developing the personal and professional skills that students need to become successful independent investigators and educators, as well as outreach programs aimed at communicating the goals and promise of integrative neuroscience to the general public. This training program will be tightly coupled to a new research focus involving neuro-imaging in nonhuman primates. By building upon existing strengths at Washington University, this research and training initiative will provide critical new insights into how the non-invasive measurements of brain function that are available in humans (e.g. from functional MRI) are related to the underlying activity patterns in neuronal circuits of the brain. IGERT is an NSF-wide program intended to meet the challenges of educating U.S. Ph.D. scientists and engineers with the interdisciplinary background, deep knowledge in a chosen discipline, and the technical, professional, and personal skills needed for the career demands of the future. The program is intended to catalyze a cultural change in graduate education by establishing innovative new models for graduate education and training in a fertile environment for collaborative research that transcends traditional disciplinary boundaries.
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TEAM MEMBERS:
Kurt ThoroughmanGregory DeAngelisRandy BucknerSteven PetersenDora Angelaki
"Local Investigations of Natural Science (LIONS)" engages grade 5-8 students from University City schools, Missouri in structured out-of-school programs that provide depth and context for their regular classroom studies. The programs are led by district teachers. A balanced set of investigations engage students in environmental research, computer modeling, and advanced applications of mathematics. Throughout, the artificial boundary between classroom and community is bridged as students use the community for their studies and resources from local organizations are brought into school. Through these projects, students build interest and awareness of STEM-related career opportunities and the academic preparation needed for success.
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TEAM MEMBERS:
Robert CoulterEric KlopferJere Confrey
This research oriented project integrates the informal and formal science education sectors, bringing their combined resources to bear on the critical need for well-prepared and diverse urban science teachers. It represents a partnership among The City College of New York (CCNY), the New York Hall of Science (NYHOS), and the City University of New York Center for Advanced Study in Education (CUNY-CASE). It integrates the Science Career Ladder, a sustained program of informal science teaching training and employment at the NYHOS, with the CCNY science teacher preparation program. The longitudinal and comparative research study being conducted is designed to examine and document the effect of this integrated program on the production of urban science teachers. Outcomes from this study include a new body of research related to the impact of internships in science centers on improving classroom science teaching in urban high schools. Results are being disseminated to both the informal science education community (through the Association for Science and Technology Centers and the Center for Informal Learning in Schools, an NSF supported Center for Learning and Teaching situated at the San Francisco Exploratorium) and the formal education community (through the National Science Teachers Association and the American Educational Research Association).
The Science Career Ladder program engages undergraduates as inquiry-based interpreters (Explainers) for visitors to the NY Hall of Science. Integrating this experience with a formal teacher certification program enables participants to coordinate experiences in the science center, college science and education classes, and K-12 classrooms. Participants receive a license to teach science upon graduating. The approach has its theoretical underpinnings in the concept of situated learning as noted by Kirshner and Whitson (1997, Situated Cognition: Social, Semiotic and Psychological Perspectives, Mahwah, NJ: Erlbaum). Through apprenticeship experiences, situated learning recreates the complexity and ambiguity of situations that learners will face in the real world. Science centers provide a potentially ideal setting for situational learning by future teachers, allowing them to develop, exercise and refine their science teaching and learning skills as noted by Gardner (1991, The Unschooled Mind, New York: Basic Books).
There is a well-documented shortage of science teachers in urban school districts. The causes of this shortage relate to all phases of the teacher professional continuum, from recruitment through training and retention. At the same time, the demographic composition of American teachers is increasingly out of synch with the demographics of the student population, raising concerns that a critical shortage of role models may be at hand, contributing to a worsening situation in urban schools. In the face of these challenges many innovative teacher recruitment and teacher preparation programs have been developed to augment traditional pathways to teaching. These programs range from high school academies for students expressing an interest in teaching to the recruitment and training of individuals making mid-life career changes. The CLUSTER program described above represents a new alternative. There are more than 250 science centers in the United States. Many of these have extensive youth internship programs and collaborative relationships with local colleges. Therefore, the proposed model is widely applicable.
The University of Massachusetts Lowell and Machine Science Inc. propose to develop and to design an on-line learning system that enables schools and community centers to support IT-intensive engineering design programs for students in grades 7 to 12. The Internet Community of Design Engineers (iCODE) incorporates step-by-step design plans for IT-intensive, computer-controlled projects, on-line tools for programming microcontrollers, resources to facilitate on-line mentoring by university students and IT professionals, forums for sharing project ideas and engaging in collaborative troubleshooting, and tools for creating web-based project portfolios. The iCODE system will serve more than 175 students from Boston and Lowell over a three-year period. Each participating student attends 25 weekly after-school sessions, two career events, two design exhibitions/competitions, and a week-long summer camp on a University of Massachusetts campus in Boston or Lowell. Throughout the year, students have opportunities to engage in IT-intensive, hands-on activities, using microcontroller kits that have been developed and classroom-tested by University of Massachusetts-Lowell and Machine Science, Inc. About one-third of the participants stay involved for two years, with a small group returning for all three years. One main component for this project is the Handy Cricket which is a microcontroller kit that can be used for sensing, control, data collection, and automation. Programmed in Logo, the Handy Cricket provides an introduction to microcontroller-based projects, suitable for students in grades 7 to 9. Machine Science offers more advanced kits, where students build electronic circuits from their basic components and then write microcontroller code in the C programming language. Machine Science offers more advanced kits, which challenge students to build electronic circuits from their basic components and then write microcontroller code in the C programming language. Machine Science's kits are intended for students in grades 9 to 12. Microcontroller technology is an unseen but pervasive part of everyday life, integrated into virtually all automobiles, home appliances, and electronic devices. Since microcontroller projects result in physical creations, they provide an engaging context for students to develop design and programming skills. Moreover, these projects foster abilities that are critical for success in IT careers, requiring creativity, analytical thinking, and teamwork-not just basic IT skills.
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TEAM MEMBERS:
Fred MartinDouglas PrimeMichelle Scribner-MacLeanSamuel Christy
The Learning and Youth Research and Evaluation Center (LYREC) is a collaboration of the Exploratorium, Harvard University, Kings College London, SRI International and UC Santa Cruz. LYREC provides technical assistance to NSF AYS projects, collects and synthesizes their impact data, and oversees dissemination of progress and results. This center builds on the Center for Informal Learning in Schools (CILS) that has developed a theoretical approach that takes into account the particular strengths and affordances of both Out of School Teaching (OST) and school environments. This foundation will permit strengthening the potential of the NSF AYS projects to develop strong local models that can generate valid and reliable data that can guide future investment, design and research aimed at creating coherence across OST and school settings. The overarching questions for the work are: 1. How can OST programs support K-8 engagement and learning in science, and in particular how can they contribute to student engagement with K-8 school science and beyond? 2. What is the range of science learning outcomes OST programs can promote, particularly when in collaboration with schools, IHE's, businesses, and other community partners? 3. How can classroom teachers and schools build on children's OST experiences to strengthen children's participation and achievement in K-12 school science Additionally, the data analysis will reveal: 1. How OST programs may be positioned to support, in particular, high-poverty, female and/or minority children traditionally excluded from STEM academic and career paths; and 2. The structural/organizational challenges and constraints that exist to complicate or confound efforts to provide OST experiences that support school science engagement, and conversely, the new possibilities which are created by collaboration across organizational fields. Data will be gathered from surveys, interviews, focus groups, evaluation reports, and classroom and school data.
This research study involves collaboration between researchers at the University of Maryland, College Park and Bowie State University, an HBCU, to examine a multi-component pre-service model for preparing minority students to teach upper elementary and middle level science. The treatment consists of (1) focused recruitment efforts by the collaborating universities; (2) a pre-service science content course emphasizing inquiry and the mathematics of data management; (3) an internship in an after school program serving minority students; (4) field placements in Prince Georges County minority-serving professional development schools; and (5) mentoring support during the induction year. The research agenda will examine each aspect of the intervention using quantitative and qualitative methods and a small number of case studies.
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TEAM MEMBERS:
James McginnisSpencer BensonScott Dantley
This Nanoscale Science and Engineering Center (NSEC) is a collaboration among Harvard University, the Massachusetts Institute of Technology, the University of California—Santa Barbara, and the Museum of Science—Boston with participation by Delft University of Technology (Netherlands), the University of Basel (Switzerland), the University of Tokyo (Japan), and the Brookhaven, Oak Ridge, and the Sandia National Laboratories. The NSEC combines "top down" and "bottom up" approaches to construct novel electronic and magnetic devices with nanoscale sizes and understand their behavior, including quantum phenomena. Through a close integration of research, education, and public outreach, the Center encourages and promotes the training of a diverse group of people to be leaders in this new interdisciplinary field.
The Nanoscale Science and Engineering Center entitled New England Nanomanufacturing Center for Enabling Tools is a partnership between Northeastern University, the University of Massachusetts Lowell, the University of New Hampshire, and Michigan State University. The NSEC unites 34 investigators from 9 departments. The NSEC is likely to impact solutions to three critical and fundamental technical problems in nanomanufacturing: (1) Control of the assembly of 3D heterogeneous systems, including the alignment, registration, and interconnection at three dimensions and with multiple functionalities, (2) Processing of nanoscale structures in a high-rate/high-volume manner, without compromising the beneficial nanoscale properties, (3) Testing the long-term reliability of nano components, and detect, remove, or prevent defects and contamination. Novel tools and processes will enable high-rate/high-volume bottom-up, precise, parallel assembly of nanoelements (such as carbon nanotubes, nanorods, and proteins) and polymer nanostructures. This Center will contribute a fundamental understanding of the interfacial behavior and forces required to assemble, detach, and transfer nanoelements, required for guided self-assembly at high rates and over large areas. The Center is expected to have broader impacts by bridging the gap between scientific research and the creation of commercial products by established and emerging industries, such as electronic, medical, and automotive. Long-standing ties with industry will also facilitate technology transfer. The Center builds on an already existing network of partnerships among industry, universities, and K-12 teachers and students to deliver the much-needed education in nanomanufacturing, including its environmental, economic, and societal implications, to the current and emerging workforce. The collaboration of a private and two public universities from two states, all within a one hour commute, will lead to a new center model, with extensive interaction and education for students, faculty, and outreach partners. The proposed partnership between NENCET and the Museum of Science (Boston) will foster in the general public the understanding that is required for the acceptance and growth of nanomanufacturing. The Center will study the societal implications of nanotechnology, including conducting environmental assessments of the impact of nanomanufacturing during process development. In addition, the Center will evaluate the economic viability in light of environmental and public health findings, and the ethical and regulatory policy issues related to developmental technology.
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TEAM MEMBERS:
Ahmed BusnainaNicol McGruerGlen MillerCarol BarryJoey Mead
The goal of this engineering education project entitled EXTRAORDINARY WOMEN ENGINEERS (EWE) is to encourage more academically prepared high school girls to consider engineering as an attractive option for post-secondary education and subsequent careers in order to increase the number of women who make up the engineering workforce. Specific project objectives are to: 1) mobilize America's more than one million engineers to reach out to educators, school counselors, and high school girls with tested messages tailored to encourage participation in engineering education and careers; 2) help high school counselors and science, math, and technology teachers to better understand the nature of engineering, the academic background needed to pursue engineering, and the career paths available in engineering; 3) equip high school counselors and teachers to share this information with students, especially girls; and 4) reach out to girls directly with messages that accurately reflect the field of engineering and will inspire girls to choose engineering. The WGBH Educational Foundation has partnered with the American Association of Engineering Societies (AAES), American Society of Civil Engineers (ASCE), and a coalition of more than 50 of the country's engineering associations, colleges, and universities to fundamentally shift the way the engineering and educational communities portray engineering. Based on a needs assessment performed in 2004, the EWE coalition embraces a communication strategy that focuses on the societal value and rewards of being an engineer, as opposed to the traditional emphasis on the process and challenges of becoming an engineer. This project represents a nationwide outreach effort that includes training opportunities for engineers; targeted Web-based and print resources for students, school counselors and teachers, and engineers; and a range of outreach and marketing activities.
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TEAM MEMBERS:
Julie BenyoPatrick NataleF. Suzanne Jenniches
This collaborative project aims to establish a national computational resource to move the research community much closer to the realization of the goal of the Tree of Life initiative, namely, to reconstruct the evolutionary history of all organisms. This goal is the computational Grand Challenge of evolutionary biology. Current methods are limited to problems several orders of magnitude smaller, and they fail to provide sufficient accuracy at the high end of their range. The planned resource will be designed as an incubator to promote the development of new ideas for this enormously challenging computational task; it will create a forum for experimentalists, computational biologists, and computer scientists to share data, compare methods, and analyze results, thereby speeding up tool development while also sustaining current biological research projects. The resource will be composed of a large computational platform, a collection of interoperable high-performance software for phylogenetic analysis, and a large database of datasets, both real and simulated, and their analyses; it will be accessible through any Web browser by developers, researchers, and educators. The software, freely available in source form, will be usable on scales varying from laptops to high-performance, Grid-enabled, compute engines such as this project's platform, and will be packaged to be compatible with current popular tools. In order to build this resource, this collaborative project will support research programs in phyloinformatics (databases to store multilevel data with detailed annotations and to support complex, tree-oriented queries), in optimization algorithms, Bayesian inference, and symbolic manipulation for phylogeny reconstruction, and in simulation of branching evolution at the genomic level, all within the context of a virtual collaborative center. Biology, and phylogeny in particular, have been almost completely redefined by modern information technology, both in terms of data acquisition and in terms of analysis. Phylogeneticists have formulated specific models and questions that can now be addressed using recent advances in database technology and optimization algorithms. The time is thus exactly right for a close collaboration of biologists and computer scientists to address the IT issues in phylogenetics, many of which call for novel approaches, due to a combination of combinatorial difficulty and overall scale. The project research team includes computer scientists working in databases, algorithm design, algorithm engineering, and high-performance computing, evolutionary biologists and systematists, bioinformaticians, and biostatisticians, with a history of successful collaboration and a record of fundamental contributions, to provide the required breadth and depth. This project will bring together researchers from many areas and foster new types of collaborations and new styles of research in computational biology; moreover, the interaction of algorithms, databases, modeling, and biology will give new impetus and new directions in each area. It will help create the computational infrastructure that the research community will use over the next decades, as more whole genomes are sequenced and enough data are collected to attempt the inference of the Tree of Life. The project will help evolutionary biologists understand the mechanisms of evolution, the relationships among evolution, structure, and function of biomolecules, and a host of other research problems in biology, eventually leading to major progress in ecology, pharmaceutics, forensics, and security. The project will publicize evolution, genomics, and bioinformatics through informal education programs at museum partners of the collaborating institutions. It also will motivate high-school students and college undergraduates to pursue careers in bioinformatics. The project provides an extraordinary opportunity to train students, both undergraduate and graduate, as well as postdoctoral researchers, in one of the most exciting interdisciplinary areas in science. The collaborating institutions serve a large number of underrepresented groups and are committed to increasing their participation in research.
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TEAM MEMBERS:
Tandy WarnowDavid HillisLauren MeyersDaniel MirankerWarren Hunt, Jr.
The "Salmon Research Team: A Native American Technology, Research and Science Career Exposure Program" is a three-year, youth-based ITEST project submitted by the Oregon Museum of Science and Industry. The project seeks to provide advanced information technology and natural science career exposure and training to 180 middle level and high school students. Mostly first-generation college-bound students, the target audience represents the Native American community and those with Native American affiliations in reservation, rural and urban areas. Students will investigate computer modeling of complex ecological, hydrological and geological problems associated with salmon recovery efforts. Field experiences will be provided in three states: Oregon, Washington and northern California. The participation of elders and tribal researchers will serve as a bridge between advanced scientific technology and traditional ecological knowledge to explore sustainable land management strategies. Students will work closely with Native American and other scientists and resource managers throughout the Northwest who use advanced technologies in salmon recovery efforts. Student participation in IT-dependent science enrichment and research activities involving natural science fields of investigation will occur year round. Middle school students are expected to receive at least 330 contact hours including a one-week summer research experience, a one-week spring break program, and seven weekends of residential programs during the school year. The high school component consists of 460 contact hours reflecting one additional week for the summer research experience. In addition to watershed and salmon recovery related research, students will be involved in other ancillary research projects. A vast array of partners are positioned to support the field research experience including, for example, the U.S. Department of the Interior, Redwood National State Park, College of Natural Resources and Sciences at Humboldt State University, Confederated Tribes of the Warm Springs, University of Oregon Institute of Marine Biology, University of Washington Columbia Basin Research project, the Northwest Center for Sustainable Resources at Chemeketa Community College and the Integrated Natural Resource Technology program at Mt. Hood Community College. The project is intended to serve as a model for IT-based youth science programs that address national and state education standards and are relevant to the cultural experience of Native American students. Two mentors will provide continued support to students: an academic mentor at the student's schools and a professional mentor from a local university or natural resource agency. Incentives will be provided for student participation including stipends and internships. Career exposure and work-related skills are integrated throughout the project activities and every program component. Creative strategies are used to encourage family involvement including, for example, salmon bakes and museum discounts.
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TEAM MEMBERS:
Travis Southworth-NeumeyerDaniel Calvert
The X-Tech program will bring together the Exploratorium and staff at five Beacon Centers to create an innovative technology program using STEM and IT activities previously tested at the Exploratorium. At each X-Tech Club, two Beacon Center staff and two Exploratorium Youth Facilitators will work with 20 middle school students each year for a total of 300 participants. Youth Facilitators are alumni of the Exploratorium's successful Explainer program and will receive 120 hours of training in preparation for peer mentoring. Each site will use the X-Tech hands-on curriculum that will focus on small technological devices to explore natural phenomenon, in addition to digital imaging, visual perception and the physiology of eyes. Parental involvement will be fostered through opportunities to participate in lectures, field trips and open houses, while staff at Beacon Centers will participate in 20 hours of professional development each year.
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TEAM MEMBERS:
Vivian AltmannDarlene LibreroVirginia WittMichael Funk