In our efforts to sustain U.S. productivity and economic strength, underrepresented minorities (URM) (for the purpose of this paper defined as persons of African American, Hispanic American, and Native American racial/ethnic descent), provide an untapped reservoir of talent that could be used to fill technical jobs. Over the past 25 years, educational diversity programs have encouraged and supported URM pursuing STEM degrees. Yet, their representation in STEM still lags far behind that of White, non-Hispanic men.
To understand the reasons why this is occurring, the American Association for
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TEAM MEMBERS:
Yolanda S. GeorgeVirginia Van HorneShirley M. Malcom
This article describes a partnership between Seton Hall University and the Liberty Science Center to engage preservice teachers in teaching and learning science. The partnership program offered preservice teachers the opportunity to interact with displays and demonstrations, teach and interact with the public, participate in professional development activities, and communicate with diverse groups.
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Debra ZinicolaRoberta Devlin-Scherer
In this chapter we explore how people build new theories in the context of collaborative scientific thinking. As illustrated by many of the chapters in this volume, our default notion of "scientific thinking" has changed from that of the lone scientist or student toiling away on a magnum opus or in the laboratory, to that of people working as part of collaborative groups who negotiate goals for the task, co-construct knowledge, and benefit from the diverse prior knowledge that each collaborator brings to the table. In some ways, conceptualizing scientific thinking as fundamentally
When designing programs for science learning, it is important to consider that children's experiences with science begin years before they encounter science in the classroom. Children's developing understanding of science begins in their everyday activities and conversations about the natural and technical world. Children develop "scientific literacy" as they begin to learn the language of science (e.g., concepts such as "gravity" or "metamorphosis"), the kind of causal explanations that are used in scientific theories (e.g., the day-night cycle results from the rotation of the earth), and the
For children to achieve an understanding of science and of the ways of doing science, and for them to be motivated to use these ways in coping with, understanding, and enjoying the physical, biological, and social world around them, it is not enough that they believe that science is practically important. They must also be curious. Curiosity calls attention to interesting, odd, and sometimes important items in the drama that is revealed to us through our senses. Idle or purposeful, curiosity is the motor that interests children in science; it is also the principal motor that energizes and
This interpretive study of learning environments involved two groups of Israeli science teachers who participated in courses and implemented field trips as part of science‐technology‐society (STS) education and under the framework of general system theory. The different groups of preservice and experienced teachers were selected in order to provide diverse perspectives on learning environments associated with the enactment of field trips as enrichment for the science classroom. The article describes the field trip programs and provides examples of how teachers in different stages of their
The current world research agenda is comprehensive. The results of many studies and experiments in which scientists are currently engaged will undoubtedly have profound impacts on the lives of citizens in developed and developing nations. Yet few people even know what research is being conducted, much less understand why it is being done and what the potential implications may be. This is a critical shortcoming of our public information system. Given the frenetic pace of science research in multi-disciplinary fields, it is increasingly vital that the public be made aware of new findings in a
Indigenous science relates to both the science knowledge of long-resident, usually oral culture peoples, as well as the science knowledge of all peoples who as participants in culture are affected by the worldview and relativist interests of their home communities. This article explores aspects of multicultural science and pedagogy and describes a rich and well-documented branch of indigenous science known to biologists and ecologists as traditional ecological knowledge (TEK). Although TEK has been generally inaccessible, educators can now use a burgeoning science-based TEK literature that
This article takes an anti-essentialist approach to the gendered construction of the science curriculum and its exclusivity. Drawing on post-structuralist theory, it examines the student subject positions that are generated within the dominant discourses and practices of curriculum science. A critical discourse analysis of student interview talk demonstrates the importance of both gender and ethnicity in the production of, or rejection of, scientist identities. While hegemonic masculinity can provide comfortable scientist identities for some males, femininity is less compatible with physical
This volume explores the integration of recent research on everyday, classroom, and professional scientific thinking. It brings together an international group of researchers to present core findings from each context; discuss connections between contexts, and explore structures; technologies, and environments to facilitate the development and practice of scientific thinking. The chapters focus on: * situations from young children visiting museums, * middle-school students collaborating in classrooms, * undergraduates learning about research methods, and * professional scientists engaged in
The New Mexico Museum of Natural History and Science proposed to develop an outreach science and mathematics program with a parent involvement and teacher enhancement professional development component. The goals of the project are as follows: (1) to involve parents in their children's education; (2) to promote a positive attitude on behalf of parents and students toward science and mathematics; (3) to increase teachers' level of comfort in teaching science; and (4) to enhance teacher's confidence in the hands-on approach as an effective method for teaching science. The objectives for the parent component of this project are: acquaint parents with the national and state science education goals and standards; introduce parents to activities that can be done at home with children; and provide families with materials and activity sheets that can be used at home. The objectives for the teacher component of this project are: (1) to provide teachers with opportunities for increased communication with parents about science literacy for children; (2) provide professional development for teachers on the use of hands-on science activities in the classroom; and (3) to providing bilingual activity guides and kits containing materials to encourage science learning. The methods for implementing this project will be varied according to the needs of the target audiences. Parents and children will be engaged through parent workshops and multi-aged children's activities conducted at the museum by experienced science educators. The professional development for teachers' component of this project will include an extensive summer workshop, on-going training/ planning sessions during the school calendar year and session on the uses of the bilingual teaching manuals. The cost sharing for this NSF award is 46.7% of the total project cost.
The New York City Board of Education Community School District #18 requests $862,790 to design a Parent Involvement in Science, Mathematics, and Technology Program. The program is designed to stimulate parents to become informed, active proponents for high quality and more universally available science, mathematics, and technology education for their children. The SMART Parents project team would design and disseminate strategies to enable parents to support their children's science, mathematics, and technology education. Innovative materials and strategies will be developed that will actively engage over 6,000 parents/families over the thirty-eight (38) months duration of the project. Almost 20,000 families will become involved in the leadership-training component of this project. The initiative will assist parents in supporting their children's education in science, mathematics, and technology education. Ultimately, the project will enhance parents' knowledge and understanding of Informal Science Education.