Cornell's Laboratory of Ornithology will develop the "Cornell Nest Box Network (CNN)". This is an educational/research project that will enable lay people to participate in scientific research and it builds on a successful NSF grant "National Science Experiments". For this project, CNN participants will build and place nest boxes in their communities and monitor the boxes gathering information on the breeding success of their occupants. Participants will summarize and analyze their data and then send it to the Lab for more comprehensive analysis. Lab biologists will analyze the compiled data and report results in a variety of media including scientific reports and popular newsletters. The CNN includes both an educational and research agenda. Participants will learn about birds while participating directly in the scientific process. The research questions, requiring huge, continent-wide databases, will focus on the effects of acid rain on bird populations, geographic variation in avian clutch size, effects of ectoparasites on nesting birds and population dispersal, among others. The protocol will encourage group participation and will be especially suitable for families. It will involve a corps of trained "ambassadors" who will help sustain the project a local levels. One of the goals of the project is to move participants up a ladder of science knowledge from projects involving minimal knowledge and skill to those requiring more. It also addresses national education standards that call for increased opportunities for students to engage in extended inquiry and authentic research activities. After the fourth development year, this research/education project will become self-sustaining.
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TEAM MEMBERS:
Andre DhondtRick BonneyJohn FitzpatrickDavid Winkler
During the 3 years of this project, 72 high school and middle school teachers and 36 students will work as members of atmospheric research teams studying each of ten airshed around the Portland, OR metropolitan area. Each summer's activities include a 4-week atmospheric interaction research course and a one-week air quality measurement campaign during a pollution episode. Transfer to the classroom is anticipated through action research projects during the academic year. An interactive webpage will enable all partners to access data, real time models of the atmosphere, and descriptions of the action research projects. A lead high school will serve as the Horizons-Air site for an airshed zone and will work collaboratively with four other middle/high schools, the Horizons-Met sites.
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TEAM MEMBERS:
Linda GeorgeDaniel JohnsonWilliam Becker
This Phase I SEPA proposal supports a consortium of science and education partners that will develop System Dynamics (SD) computer models to illustrate basic health science concepts. The consortium includes Oregon Health Sciences University (OHSU), Portland Public Schools (PPS), Saturday Academy, and the Portland VA Medical Center. SD is a computer modeling technique in which diagrams illustrate system structure and simulations illustrate system behavior. Desktop computers and commercial software packages allow SD to be applied with considerable success in K-12 education. NSF grants to Portland Public Schools have trained over 225 high school teachers in Portland and surrounding areas. Two magnet programs have been established with an emphasis on systems and at least five other schools offer significant systems curriculum. Major components of this project include (1) Annual summer research internships at OHSU for high school teachers and high school students, (2) Development of SD models relevant to each research project, (3) Ongoing interactions between high school science programs and OHSU research laboratories, (4) Development of curriculum materials to augment the use of the SD model in the high school classroom or laboratory setting, and (5) Development of video materials to support the classroom teacher. Content will focus on four fundamental models: linear input/exponential output, bi-molecular binding (association/dissociation), population dynamics, and homeostasis. Each of these models is very rich and may be extended to a broad variety of research problems. In addition these models may be combined, for example to illustrate the effect of drugs (binding model) on blood pressure (homeostasis model). System Dynamics is an exemplary tool for the development of materials consistent with National Science Education Standards. SD was specifically developed to emphasize interactions among system structure, organization, and behavior. Students use these material as part of inquiry-based science programs in which the teacher serves as a guide and facilitator rather than the primary source of all content information; technical writing by students is also encouraged. Finally, these SD materials will provide a coherent body of work to guide the ongoing professional development of the classroom science teacher.