Archaeology education activities in informal science learning settings are an underutilized, but effective strategy for teaching science inquiry skills in socially and culturally relevant contexts. This project investigated the potential for archaeological content and inquiry strategies to help informal science learning institutions increase learning with diverse ISE audiences. The project was based on foundational research for the development of a national research framework for archaeology education and a plan for developing high-quality science learning opportunities for under-represented
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TEAM MEMBERS:
Michael BrodyJohn FisherJeanne MoeHelen Keremedjiev
In the United States, African Americans are underrepresented in science careers and underserved in pre-collegiate science education. This project engaged African American elementary students in culturally relevant science education through archaeology and thereby increased positive dispositions toward science. While imagining what the lives of their ancestors were like, students practiced scientific inquiry and used natural sciences to analyze archaeological sites. The project helped to improve science literacy among African American elementary students through archaeological inquiry and
Recognizing that the Maker movement embodies aspects of science, technology, engineering, and mathematics (STEM) learning that are the hallmarks of effective education — deep engagement with content, critical thinking, problem solving, collaboration, learning to learn, and more — NYSCI, in collaboration with Dale Dougherty and Tom Kalil, approached the National Science Foundation to sponsor a two-day workshop. Over 80 leaders in education, science, technology and the arts came together at NYSCI to consider how the Maker movement can help stimulate innovation in formal and informal education
This review conducted by the National Institute on Out-of-School Time (NIOST) explores the current discussion and research findings on STEM (Science, Technology, Engineering, and Math) in out-of-school time and reflects on the ways the INSPIRE program model (see Appendix A) incorporates research-based practice in implementing STEM education experiences in out-of-school time. The purpose of the literature review and analysis project is to inform the INSPIRE program managers during the planning and implementation stage of INSPIRE.
Based on the premise that one component of NASA's pre-college education program is intended to support and enact school reform, the Committee for the Evaluation and Review of NASA's Pre-College Education Program requested an analysis of how the NASA Explorer School (NES) Model aligns with other national models of school-wide improvement and reform. The purpose and focus of this paper is to summarize key elements of major school improvement and reform models as well as specific content reform models from the literature, and to analyze the extent to which there is alignment between these models
This paper presents a summary of each of 10 evaluations conducted of NASA educational programs. The paper begins with a table outlining the titles of the evaluations and who conducted them, the date of the report, the evaluation questions, the evaluation design or methods and brief comments on the quality of each report. After the table each report is considered in more depth through an overview of what the evaluation included as well as a critique of the evaluation questions, methods and findings. The paper concludes with an overall commentary on the set of evaluations.
The purpose of this paper is to explore and discuss the role of practical work in the teaching and learning of science at school level. It emphasizes practical work as a means for students to learn about the nature of science.
Reports from the NSF, NRC, AAAS, and others urge over and over that we must teach "science as science is done," that "science is a way of knowing," that our goal should be to impart "scientific habits of mind," and that learning must be learner-centered and oriented toward process. Fine. But what does this really mean for science education, and especially laboratory education?
The purpose of this paper is to examine the role of laboratory-based science from a perspective that synthesizes developments in (1) science studies, e.g., history, philosophy and sociology of science and (2) the learning sciences, e.g., cognitive science, philosophy of mind, educational psychology, social psychology, computer sciences, linguistics, and (3) educational research focusing on the design of learning environments that promote dynamic assessments. Taken together these three domains have reshaped our thinking about the role inquiry, and in turn the laboratory, has in science
The purpose of this paper is to review what is known about informal science learning and to recommend areas for further research. The review is intended to support an examination of how children's science learning experiences in designed informal environments like science museums and zoos relate to science learning activities in K-8 schools.
This paper lays out a theory of (re-)generative learning to explain how families and communities socialize young learners into thinking like scientists and mathematicians. Cultural communities and their families orient their young in varied ways toward the language, behaviors, and self-theories about the future presupposed in the learning of science and mathematics. Certain socialization processes and norms correspond closely with those that scientists and artists use in laboratories, studios, and rehearsals. Certain norms of politeness and patterns of language differ significantly from habits
What makes “making”—the next generation of inventing and do-it-yourself—worth paying attention to? In this report, we explore the three categories of makers, the ecosystem growing around those categories, the role technology plays in this ecosystem, and, finally, how business can take advantage of the opportunities this movement represents.
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TEAM MEMBERS:
John HagelJohn Seely BrownDleesha Kulasooriya