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.
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.
In several primarily Hispanic, low socio-economic school districts of the southwest in partnership with local institutions of higher learning, this 48-month project will develop programs and materials to attract parents of children of all grade levels and make them active supporters of a system that promotes good mathematical learning for their children. These programs and materials will help them become aware of what is happening in their children's classroom; offer them occasions to take on leadership roles in working with teachers, administrators, and other parents; and provide them opportunities for in-depth experiences with school mathematics. The materials will be initially developed and piloted in the Sunnyside School District. After revision from the pilot project, the project will be implemented in several other school districts.
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TEAM MEMBERS:
David GayMarta Civil
resourceprojectProfessional Development, Conferences, and Networks
The Center for Informal Learning and Schools (CILS) is a five-year collaborative effort between the Exploratorium in San Francisco, the University of California at Santa Cruz, and King's College London. The purpose of the Center is to study the intersection of informal science learning that takes place in museums and science centers and formal learning that takes place in schools, and to prepare leaders in informal science education. Through the efforts of the center, new doctoral level leaders will be prepared who understand how informal science learning takes place and how informal institutions can contribute to science education reform. A Ph.D. program will be offered to 16 individuals at King's College London (two cohorts of eight) and a post-doctoral program to six scientists interested in issues of learning and teaching in informal settings. A doctoral program is planned at the University of California at Santa Cruz for 24 students, 12 whose interests are primarily in education and 12 who come from the sciences. In addition to doctoral level training, there will be a certification program for existing informal science professionals to better enable them to support teachers, students and the general public. That program will provide 160 informal science educators 120 hours of professional development experiences, and an additional 24 informal science educators with a master's degree in informal science education at UC Santa Cruz. A Bay Area Institute will be developed to serve as a central focus for all CILS activities. It will bring together researchers and practitioners; it will offer courses and workshops for graduate students; and it will provide a central location for reporting research findings and methodologies that focus on how informal learning institutions can best contribute to science education reform.
Two 8 to 10 week modules, one focusing on cells and the other on reproduction and heredity, serve as the basis for the development of a comprehensive, assessment-driven, middle school science curriculum called "Science for Today and Tomorrow." A curriculum frramework is developed for Life and Physical Sciences to be taught in Grades 6 and 7 and Earth Science in Grade 8. The research-based materials assist students to develop a working knowledge of a core set of ideas that are fundamental to the discipline and ultimately to see how the concepts span the disciplines. The student materials and the teachers' guides are enhanced with classroom-tested assessments and web-based content resources, simulations and tools for gathering and interpreting data. On-line professional development materials allow teachers to gain content knowledge and pedagogical skills. The website also contains an area that provides information for administrators including strategies for supporting teachers and another area for community members to involve them in the students' science learning. The project builds upon the lessons learned in previous materials development projects at TERC.
This sixth through eighth grade comprehensive, project-based, science curriculum focuses on students acquiring deep understandings of the concepts, principles and habits of mind articulated in national science standards. The curriculum builds upon the experiences of the Center for Learning Technologies in Urban Schools developing the LeTUS modules for Chicago and Detroit Public Schools. The project brings together scientists and science educators from three universities, teachers and administrators from six school districts, curriculum speialists from Project 2061, educational researchers from EDC, and Kendall/Hunt publishers. The design principles, arising from research on teaching and learning, include alignment with standards, assessments, contextualization, sustained student inquiry, embedded learning technologies, collaboration, and scaffolds between and within modules. Phase 1 focuses on the development of two units: Structure of Matter and Diversity of Life and Evolution. Learning outcomes are identified, target understanding performances are specified and assessments are designed before the activities are developed. Everday authentic questions that students hold as important provide the basis for projects, contextualize the activities and give coherence to the curriculum. In addition to the student materials and teacher guides, the project develops materials to provide information to administrators and the community to understand and support the implementation of the modules. Issues of language, literacy, culture and diversity are addressed. Professional development materials address teacher attitudes and beliefs while educating the teachers about the new context and pedagogy.
Parent Partners in School Science (PPSS) is a partnership project between The Franklin Institute and the Philadelphia School District. This is a three and one-half year program which will provide a pivotal role for the informal science learning center to be a facilitator in parental support of K-4 school instruction in science. The PPSS program will involve teachers, families and children in grades K-2 the first year, grades 1-3 the next, and finally grades 2-4 in the third year. The incorporation of the national science standards and working with Home and School Associations (HSA) in the area schools, the program will impact over 3600 children, 5400 parents and 45 educators participating over the life of the project. There are several goals and elements in the program. This will certainly demonstrate how an informal science center supports learning and it is also hoped to become a model for effective parent-teacher and parent-child collaboration to support learning. There will be Exploration Cards developed, which are at-home schince challenges for families, Discovery Days that are museum-based days of science inquiry using the yearly theme, Parent/Teacher Workshops at the museum, and finally a Science Celebration which is a showcase of participants' year-long achievements via an exhibit to be displayed at The Franklin Institute for a month, then traveling the exhibit to participating schools. The project's structure, disseminination acitivites and products are designed for national application and as a model for use in both formal and informal education communities. It is hoped the program will offer new opportunities for science center methology and pratice to provide direct support for the school agenda in science.
Family Science: Expanding Community Support for Inquiry-based Science is the University of Washington's innovative five-year plan for reaching youth and families in the Seattle school district. This program represents an enhancement of the NSF-funded Family Science program targeting grades K-5 and expansion of this successful program to include middle and high school students. The proposed activities, Science Explorations, Inquiry Science Conferences and Community Celebrations, are designed to help parents understand inquiry-based science instruction while heightening students' confidence in their ability to understand science processes. The hands-on activities also support and complement Seattle's Local Systemic Change project by enlisting teachers, parents and community members to champion science education outside of the formal school setting. The implementation strategy includes workshops to train Family Science Lead Teachers and Parent/Community Leaders to coordinate Family Science programs. Subsequent partnerships between teachers and community organizations are designed to establish regional clusters of community networks to support programmatic activities during and beyond the funding period. It is estimated that Family Science will result in the presentation of nearly 300 school and community-based events impacting 10,000 individuals.
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TEAM MEMBERS:
Leroy HoodEthan AllenDana RileyPatrick Ehrman
resourceprojectProfessional Development, Conferences, and Networks
The purpose of this project is to enhance African American parental involvement with high school student children by developing skills and strategies for effectively managing the educational careers of their children. It would create a capacity for collaborations with the schools that service African American children by developing the social and organizational infrastructure for continued parental involvement in educational careers. It seeks to increase enrollment and success of Black students in higher-level mathematics and science courses to diminish the race gap in math and science track placements. It uses a quasi-experimental design to implement a series of community workshops designed to enhance knowledge, skills, and strategies for managing placements of children in science and math tracks. The research would create an intervention designed to change the outcome of students. It would conduct ethnographic work to map successful pathways to enrollment in higher-level math courses. It would use findings from these studies to implement workships within the Black communities, and conduct statistical analysis of the growth in achievement as a result of the reduction in course taking.
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TEAM MEMBERS:
Roslyn MickelsonLinwood Cousins
resourceprojectProfessional Development, Conferences, and Networks
This CAREER grant interweaves research and teaching focused on understanding how social groups construct meaning during scientific conversations across different learning contexts, such as classrooms, museums and the home. This work will be translated into formal educational settings and used to inform teaching practices within pre-service University and in-service school district settings. The research and educational emphasis will be on creating conceptual links between social learning in diverse settings and the creation of corridors of opportunity between formal and informal learning institutions. To date there has been little research with families from cultural and linguistic minority populations, such as Latino families, at informal learning settings and virtually none that integrates formal and informal learning, or impacts teaching. The five-year project will: 1. Conduct Study 1, aimed at making fundamental cross-cultural comparisons of family conversational meaning making at the Monterey Bay Aquarium and linking this work with family interviews, reflective conversations and visits to family homes; 2. Review the theoretical framework and conduct Study 2, which will incorporate lessons learned from Study 1, and linking this research to formal classrooms; and 3. Use the findings (at each stage) to inform teaching practice with UCSC undergraduate (Science majors) and graduate (Science credential, MA and Ph.D.) students, and, in collaboration with teacher research groups for new and experienced teacher in schools that serve predominantly Latino students. This research plan provides an opportunity for viewing several inter-connected mechanisms, including family interactions and conversations, compelling science content, naturalistic learning in museum settings, and, finally, analyzing these factors in order to inform teaching practices that promote bilingual minority students to the rank of scientists.
This project develops an 8-week middle-school mathematics module that introduces cryptography, the science of sending secret messages, while teaching and reinforcing the learning of related mathematical concepts. The topics range from the classical encryption systems and the historic context in which they were used through powerful modern encryption systems that provide secrecy in electronic messages today. The module also covers passwords and codes that correct errors in the transmission of information. Public awareness of the importance of cryptography is growing, as is the need to understand the issues involved. The study of cryptography provides an interesting context for students to apply traditional mathematical skills and concepts. Mathematical topics covered include percents, probability, functions, prime numbers, decimals, inverses and modular arithmetic. The main product is a middle-school student book, with accompanying teacher materials. A web site is being developed that supports the activities in this book. Abbreviated modules for Grades 3, 4 and 5 are also being developed, as well as an instructor's guide for adapting the materials for use in informal educational settings such as museums and after-school programs. The development of the module involves piloting and field-testing by experienced classroom teachers from diverse school communities and instructors of informal educational programs. Evaluation includes review by mathematicians and educators, as well as an investigation into the level of students' understanding of the topics studied.
The long-running and highly successful National Public Radio series "Science Friday" is venturing in new directions. Given that basic research underlies all of the technological advances influencing our world and that tax dollars pay for that research, the public needs to be informed about the basics of research. To address this need for public education, "Science Friday" will examine the importance of research as a theme underlying all science and technology changes by: Finding the research roots at the bottom of each story; Exploring the cooperation among corporations, private institutions, and research foundations and illuminating how each plays a role in the research process; Following the research "bumps" along the road to illustrate that research success depends upon failures -- not all research produces positive results; Illuminating the barriers to successful research; Helping listeners understand the thought process of researchers; Scaling the "ivory tower" by enabling listeners to question and talk directly with researchers; and Helping listeners understand the role of basic research in policy-making. Ira Flatow, the host, will take "Science Friday" on the road and produce programs in Oklahoma, Iowa, Michigan, Massachusetts, Arizona and other locations. He also will visit schools and universities and will speak at public events. NPR also will reactivate the "Science Friday Kids Connection" which will take each week's program and its guest scientists directly into classrooms across the country.