This project will develop standardized, exportable and comparable assessment instruments and models for Women In Engineering (WIE) programs nationwide, thus allowing them to assess their program's activities and ultimately provide data for making well-informed evaluations.
To accomplish this goal, the principal investigators at the University of Missouri and Penn State University will work over a three-year period with their institutions' WIE programs and three cooperating programs at Rensselaer Polytechnic Institute, Georgia Tech, and University of Texas at Austin. With these five programs that collectively represent a variety of private and public, years of experience for WIE directors and student body characteristics, the investigators will pilot, revise, implement, conduct preliminary data analysis and disseminate easy-to-access, reliable and valid assessment instruments. The principles of formative evaluation will be applied to all instruments and products. All institutions will use the same set of instruments, thus allowing them to have access to powerful benchmarking data in addition to the data from each of their respective institutions.
A prior project, the Women's Experience in College Engineering Project (WECE) sought to characterize the factors that influence women students' experiences and decisions by studying college environments, events and support programs that affect women's satisfaction with their engineering major, and their decisions to persist or leave these majors. In contrast to WECE's macro-level and student focus, this proposal's target audience is WIE directors, with a focus on WIE programs, not students.
Women in Engineering programs around the United States are a crucial part of our country's response to the need for more women in engineering professions. There are about 50 WIE programs nationwide. Half have expressed interest in this effort. WIE directors will benefit by having ready-made assessment tools that will allow them to collect data on programs, evaluate these programs, and make decisions on how to revise programs and / or redistribute limited resources to maximize overall program effectiveness. Data from these instruments will also provide substantiated evidence for administrators, advisory boards and potential funding agencies. Finally, because these instruments will be available nationwide, programs will have the opportunity to take advantage of powerful benchmarking data for their decision-making processes.
This project provides the next logical step in the national movement to recruit and retain women in engineering.
The "Mentored Youth Building Employable Skills in Technology (MyBEST)" project, a collaboration of the Youth Science Center (YSC) and Learning Technology Center (LTC) at the Science Museum of Minnesota, is a three-year, youth-based proposal that seeks to engage 200 inner-city youngsters in learning experiences involving information and design technologies. The goal of the project is to develop participants' IT fluency coupled with work- and academic-related skills. The program will serve students in grades 7 through 12 with special emphasis on three underrepresented groups: girls, youngsters of color, and the economically disadvantaged. Project participants will receive 130 contact hours and 70% will receive at least 160 hours. Each project year, including summers, students participate in three seasons consisting of five two-week cycles. Project activities will center on an annual technology theme: design, engineering and invention; social and environmental systems; and networks and communication. The activities that constitute project seasons include guest presenter workshops; open labs facilitated by guest presenters, mentors and adult staff; presentations of student projects; career workshops and field trips. The project cycles feature programming (e.g., Logo computer language; Cricketalk), engineering and multi-media production (e.g., digital video; non-linear editing software). Each cycle will interface with an existing museum-related program (e.g., the NSF-funded traveling Cyborg exhibit). Mentors will work alongside participants in all technology-based activities. These mentors will be recruited from university, business, community partners and participant families. Leadership development is addressed through teamwork and in the form of internships and externships. Participants obtain work experience related to technology in the internship and externship component. The "MyBEST" project will serve as a prototype for the Museum to test the introduction of technology as central to the design and learning outcomes of its youth-based programs. An advisory board reflecting expertise in youth development, technology and informal science education will guide the program's development and plans for sustainability. Core elements of the "MyBEST" program will be integrated into the Museum's youth-based projects sponsored by the YSC and LTC departments. The Museum has a strong record of integrating prototype initiatives into long-standing programs.
The Coalition for Science After School (CSAS) was established in 2004 in response to the growing need for more STEM (science, technology, engineering, and mathematics) learning opportunities in out-of-school time. CSAS sought to build this field by uniting STEM education goals with out-of-school time opportunities and a focus on youth development. Over a decade of work, CSAS Steering Committee members, staff and partners advocated for STEM in out-of-school-time settings, convened leaders, and created resources to support this work. CSAS leadership decided to conclude CSAS operations in 2014, as the STEM in out-of-school time movement had experienced tremendous growth of programming and attention to science-related out-of-school time opportunities on a national level. In its ten-year strategic plan, CSAS took as its vision the full integration of the STEM education and out-of-school time communities to ensure that quality out-of-school time STEM opportunities became prevalent and available to learners nationwide. Key CSAS activities included: (1) Setting and advancing a collective agenda by working with members to identify gaps in the field, organizing others to create solutions that meet the needs, identifying policy needs in the field and supporting advocates to advance them; (2) Developing and linking committed communities by providing opportunities for focused networking and learning through conferences, webinars, and other outreach activities; and (3) Identifying, collecting, capturing, and sharing information and available research and resources in the field. The leadership of the Coalition for Science After School is deeply grateful to the funders, partners, supporters, and constituents that worked together to advance STEM in out-of-school time during the last decade, and that make up today's rich and varied STEM in out-of-school time landscape. We have much to be proud of, but as a movement there is much more work to be done. As this work continues to expand and deepen, it is appropriate for the Coalition for Science After School to step down as the many other organizations that have emerged over the last decade take on leadership for the critical work that remains to be done. A timeline and summary of CSAS activities, products, and accomplishments is available for download on this page. All resources noted in the narrative are also available for download below.
This award is for a Science and Technology Center devoted to the emerging area of nanobiotechnology that involves a close synthesis of nano-microfabrication and biological systems. The Nanobiotechnology Center (NBTC) features a highly interdisciplinary, close collaboration between life scientists, physical scientists, and engineers from Cornell University, Princeton University, Oregon Health Sciences University, and Wadsworth Center of the New York State Health Department. The integrating vision of the NBTC is that nanobiotechnology will be the genesis of new insights into the function of biological systems, and lead to the design of new classes of nano- and microfabricated devices and systems. Biological systems present a particular challenge in that the diversity of materials and chemical systems for biological applications far exceeds those for silicon-based technology in the integrated-circuit industry. New fabrication processes appropriate for biological materials will require a substantial expansion in knowledge about the interface between organic and inorganic systems. The ability to structure materials and pattern surface chemistry at small dimensions ranging from the molecular to cellular scale are the fundamental technologies on which the research of the NBTC is based. Nanofabrication can also be used to form new analytical probes for interrogating biological systems with unprecedented spatial resolution and sensitivity. Three unifying technology platforms that foster advances in materials, processes, and tools underlie and support the research programs of the NBTC: Molecules of nanobiotechnology; Novel methods of patterning surfaces for attachment of molecules and cells to substrates; and Sensors and devices for nanobiotechnology. Newly developed fabrication capabilities will also be available through the extensive resources of the Cornell Nanofabrication Facility, a site of the NSF National Nanofabrication Users Network. The NBTC will be an integrated part of the educational missions of the participating institutions. NBTC faculty will develop a new cornerstone graduate course in nanobiotechnology featuring nanofabrication with an emphasis on biological applications. Graduate students who enter the NBTC from a background in engineering or biology will cross-train in the other field by engaging in a significant level of complementary course work. Participation in the NBTC will prepare them with the disciplinary depth and cross-disciplinary understanding to become next generation leaders in this emerging field. An undergraduate research experience program with a strong mentoring structure will be established, with emphasis on recruiting women and underrepresented minorities into the program. Educational outreach activities are planned to stimulate the interest of students of all ages. One such activity partnered with the Science center in Ithaca is a traveling exhibition for museum showings on the subject of nano scale size. National and federal laboratories and industrial and other partners will participate in various aspects of the NBTC such as by hosting interns, attendance at symposia and scientist exchanges. Partnering with the industrial affiliates will be emphasized to enhance knowledge transfer and student and postdoctoral training. This specific STC award is managed by the Directorate for Engineering in coordination with the Directorates for Biological Sciences, Mathematical and Physical Sciences, and Education and Human Resources.
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 National Center for Earth-surface Dynamics (NCED) is a Science and Technology Center focused on understanding the processes that shape the Earth's surface, and on communicating that understanding with a broad range of stakeholders. NCED's work will support a larger, community-based effort to develop a suite of quantitative models of the Earth's surface: a Community Sediment Model (CSM). Results of the NCED-CSM collaboration will be used for both short-term prediction of surface response to natural and anthropogenic change and long-term interpretation of how past conditions are recorded in landscapes and sedimentary strata. This will in turn help solve pressing societal problems such as estimation and mitigation of landscape-related risk; responsible management of landscape resources including forests, agricultural, and recreational areas; forecasting landscape response to possible climatic and other changes; and wise development of resources like groundwater and hydrocarbons that are hosted in buried sediments. NCED education and knowledge transfer programs include exhibits and educational programs at the Science Museum of Minnesota, internships and programs for students from tribal colleges and other underrepresented populations, and research opportunities for participants from outside core NCED institutions. The Earth's surface is the dynamic interface among the lithosphere, hydrosphere, biosphere, and atmosphere. It is intimately interwoven with the life that inhabits it. Surface processes span environments ranging from high mountains to the deep ocean and time scales from fractions of a second to millions of years. Because of this range in forms, processes, and scales, the study of surface dynamics has involved many disciplines and approaches. A major goal of NCED is to foster the development of a unified, quantitative science of Earth-surface dynamics that combines efforts in geomorphology, civil engineering, biology, sedimentary geology, oceanography, and geophysics. Our research program has four major themes: (1) landscape evolution, (2) basin evolution, (3) biological sediment dynamics, and (4) integration of morphodynamic processes across environments and scales. Each theme area provides opportunities for exchange of information and ideas with a wide range of stakeholders, including teachers and learners at all levels; researchers, managers, and policy makers in both the commercial and public sectors; and the general public.
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TEAM MEMBERS:
Efi Foufoula-GeorgiouChristopher PaolaGary Parker
The National Nanotechnology Infrastructure Network (NNIN) is a partnership of 13 institutions (Cornell University, Georgia Institute of Technology, Harvard University, Howard University, North Carolina State University (affiliate), Pennsylvania State University, Stanford University, University of California at Santa Barbara, University of Michigan, University of Minnesota, University of New Mexico, University of Texas at Austin, and University of Washington) that provides multi-faceted, interdisciplinary, and broadly-accessible infrastructure supporting both near-term and long-term needs identified in the National Nanotechnology Initiative. The partnering facilities are open laboratories providing outstanding service to the external user, comprehensive training and staff support, and support of interdisciplinary and emerging areas of research, with openness to new materials, techniques, and applications.
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TEAM MEMBERS:
Sandip TiwariDaniel RalphRoger Howe
resourceprojectProfessional Development, Conferences, and Networks
The Nanoscale Science and Engineering Education (NSEE) Center for Learning and Teaching (NCLT) would focus on the research and development of nano-science instructional resources for grades 7-16, related professional development opportunities for 7-12 teachers, and programs infused with nano-science content for education doctoral students. The Center would bring together educators and scientists from several areas of nano-science and engineering research to collaborate with science teachers and doctoral candidates in education on both the development of the resources and research on their efficacy. The PI has prior experience as director of the Materials World Modules project, an NSF-funded curriculum currently in use in several secondary schools across the country. Lead partners in the proposed Center are Northwestern University, Purdue University, University of Michigan, University of Illinois at Chicago and University of Illinois at Urbana-Champaign. Additional partners include Argonne National Laboratory, West Point Military Academy, Alabama A & M University, Fisk University, Hampton University, Morehouse College and University of Texas at El Paso. The additional partners will widen the geographic range of the project, expanding opportunities to reach a diverse and currently underrepresented population of graduate students, teachers and ultimately students. STEM and Education faculty and researchers from the partner institutions would participate in interdisciplinary teams to address the Center's mission: Provide national education leadership and resources for advancing NSEE Create and implement professional development programs in NSEE Use innovative ideas in learning to design instructional materials for grades 7-16 Conduct research relating to integration of NSEE into science, technology, engineering and mathematics (STEM) education.
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TEAM MEMBERS:
R. P. H. ChangThomas MasonNcholas GiordanoJoseph Krajcik
The Educational Develpoment Center (EDC) and National Institute on Out-of-School Time (NIOST), in collaboration with science centers in AZ, MA, TX, NY, NC and CA, will develop and implement a science curriculum for informal audiences targeting children ages 8-12. Each science center will work with six community centers that serve youth in after-school programs. Science center staff will train after-school program leaders from the 36 community centers at monthly sessions, in addition to holding monthly events for families. Curriculum development will use interesting topics aligned with national standards and structure investigations as games using simple materials. The units will enable children to work in teams, and include follow-up, discussion and extended investigations using websites. It is anticipated that each child will complete 4-6 related investigations. While the six science centers will provide the content expertise, EDC and NIOST will develop the training and assessment program and provide additional technical support for the community centers. The result will be a model to support out-of-school programs that combines science centers and community resource people, centered around an activity-based curriculum focused on inquiry. Up to 1,000 children will be involved in field tests each summer. This proposal builds on "Design It!" (ESI 98-14765), which created an informal science curriculum focused on engineering principles.
Over a three year period, the Museum of Science, Boston will develop a national traveling exhibition and associated programs that will support the goals and standards for technological literacy that were recently articulated in reports by the National Academy of Engineering and the International Technology Education Association. Intellectual Merit. The exhibit will take advantage of the widely known characters and images of future technology from the Star Wars movies to attract visitors and to engage them in learning about potential technologies that may impact our lives. It incorporates new and adapted interactive devices that will involve visitors in inquiry-based learning about technologies related to frictionless land vehicles, robotic mobility mechanisms, and habitats for living underwater and in space. Broader Impact. The exhibition will reach a large national audience by traveling to the members of the Science Museum Exhibit Collaborative as well as other institutions. Use of popular culture, science fiction and futuristic technology will help attract those who may not be traditional science center visitors. Educational impact will be extended through programming for the public and school groups, including materials for institutions that do not host the exhibition, along with a website.
The Pittsburgh Children's Museum (PCM) is developing a 2,700 sq ft traveling exhibition, "How People Make Things," in collaboration with Family Communications, the producers of "Mister Rogers' Neighborhood." The exhibition will use the factory visit segments from this popular television program, the longest running on PBS, as a jumping off point for engaging children in the processes by which familiar objects are manufactured. PCM is building on its prior success with "Design It!," an after-school program funded by a prior NSF grant. This project extends that work to expose children to the hidden science and technology that form the basis for manufacturing. The exhibition will include the Neighborhood Factory orientation area and sections on Making Things: Designing Things, Forming Things (Additive, Subtractive, Deformational), and Assembling Things. Project collaborators include members of the Carnegie Mellon University Industrial and Engineering Design program and the University of Pittsburgh Learning Research and Development Center UPCLOSE. Broader Impact: The exhibition is projected to reach at least 750,000 visitors in nine museum venues through its nationwide tour; the target audience is families with children ages 3 to 10. Promotion and dissemination will be enhanced by the connection with PBS, which continues to air the "Mister Roger's Neighborhood" program. Partnerships with the AFL-CIO, Catalyst Communications, and Society of Manufacturing Engineers will extend the outreach effort. Special efforts will be made to target girls and underserved audiences.
Cornell University, through Main Street Science (the education program of its Nanobiotechnology Center), proposes to create a 3,500 sq. ft. traveling exhibition on nanoscale science and engineering in partnership with Sciencenter of Ithaca, New York. Intellectual Merit: The exhibition will address two questions: How do we see things too small to see, and how do we make things too small to see? In sections titled Small, Smaller, Nano; Seeing Nano Structures; Making Nano Stuff; and Nano and Me, hands-on activities and experiences will present the tools, processes and applications of nanoscale science and engineering for children ages 8 to 13 and adults. Broader Impact: This traveling exhibition is projected to reach some three million visitors in at least six sites as part of its national tour. It will then become a permanent exhibition at Sciencenter. Dissemination will be supported by a web site, take-home materials, a children's book and activities to carry out at home, along with links to formal education.