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.
This monograph has been created by the TEAMS (Traveling Exhibits At Museums of Science) Collaborative, a group of seven small U.S. science centers, to share experiences, observations, and lessons learned with the broader science museum field. Our intention is to help others who might be interested in forming a collaborative to work though some key issues, most of which have to do with the relationships between collaborative members, rather than more technical matters. We hope that this will provide a vision for others as to how collaboration among science centers can work. The monograph looks
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TEAM MEMBERS:
Charles TrautmannMark St. JohnDavid Goudy
This summative evaluation of the exhibition Robots & Us was designed to investigate how visitor audiences used and experienced this exhibition in relation to the project’s objectives and challenges. Visitors’ expectations and perceptions in relation to the project’s content goals prompted the summative evaluation to focus on specific challenges including: attitudes and perceptions about technology, connections between robots and people, appeal to a broad audience, and reactions to specific exhibits.
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TEAM MEMBERS:
Jeff HaywardJolene HartScience Museum of Minnesota
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
Falk and Dierking’s Contextual Model of Learning was used as a theoretical construct for investigating learning within a free-choice setting. A review of previous research identified key variables fundamental to free-choice science learning. The study sought to answer two questions: (1) How do specific independent variables individually contribute to learning outcomes when not studied in isolation? and (2) Does the Contextual Model of Learning provide a useful framework for understanding learning from museums? A repeated measure design including interviews and observational and behavioral
Interactive museum exhibits have increasingly placed replicated and virtual objects alongside exhibited authentic objects. Yet little is known about how these three categories of objects impact learning. This study of family learning in a botanical garden specifically focuses on how 12 parent-child family units used explanations as they engaged with three plant types: living, model, and virtual. Family conversations were videotaped, transcribed, and coded. Findings suggested that: 1) explanations of biological processes were more frequent than other types; 2) model and virtual plants supported
This article provides an overview of current understandings of the science learning that occurs as a consequence of visiting a free-choice learning setting like a science museum. The best available evidence indicates that if you want to understand learning at the level of individuals within the real world, learning does functionally differ depending upon the conditions, i.e., the context, under which it occurs. Hence, learning in museums is different than learning in any other setting. The contextual model of learning provides a way to organize the myriad specifics and details that give
Education is a lifelong endeavor; the public learns in many places and contexts, for a diversity of reasons, throughout their lives. During the past couple of decades, there has been a growing awareness that free‐choice learning experiences – learning experiences where the learner exercises a large degree of choice and control over the what, when and why of learning – play a major role in lifelong learning. Worldwide, most environmental learning is not acquired in school, but outside of school through free‐choice learning experiences. Included in this article are brief overviews of
This article is a response to Harris Shettel's commentary which appeared in Curator (48/2, April 2005) on two of four articles which appeared in Curator (47/2), the subject of which was interactives in museums.
The science museum field has made tremendous advances in understanding museum learning, but little has been done to consolidate and synthesize these findings to encourage widespread improvements in practice. By clearly presenting the most current knowledge of museum learning, In Principle, In Practice aims to promote effective programs and exhibitions, identify promising approaches for future research, and develop strategies for implementing and sustaining connections between research and practice in the museum community.
Genetics was developed by The Tech staff in collaboration with Stanford University and was funded by the National Institutes of Health Science Education Partnership Award (SEPA) program. The evaluation documents the impact and effectiveness of the exhibition using timing and tracking observations and exit interviews. It also examines the partnership between The Tech and Stanford University through interviews with graduate students, who conduct programs in the exhibition, and their supervisor (results are not included in this summary).
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TEAM MEMBERS:
Randi KornThe Tech Museum of Innovation
The California Academy of Sciences will develop, evaluate and disseminate exhibits and programs designed to communicate to public audiences the results of research including a biotic inventory of the amphibians and reptiles of Myanmar. Using innovative trading cards for kids, updates to current research exhibits, a poster highlighting research, a pocket guide to venomous snakes of Myanmar and a posting of research -related materials on the CAS website, the project will inform the public about biotic inventory research and conservation in Myanmar. Designed specifically for target audiences of children and adults, the exhibits and programs will serve several hundred thousand CAS visitors annually.