This study explored the nature of the relationship between a fifth-grade teacher and an informal science educator as they planned and implemented a life science unit in the classroom, and sought to define this relationship in order to gain insight into the roles of each educator. In addition, student learning as a result of instruction was assessed. Prior research has predominately examined relationships and roles of groups of teachers and informal educators in the museum setting (Tal et al. in Sci Educ 89:920–935, 2005 ; Tal and Steiner in Can J Sci Math Technol Educ 6:25–46, 2006 ; Tran 2007
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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TEAM MEMBERS:
Debra ZinicolaRoberta Devlin-Scherer
Many of the biggest problems facing the United States and the world require engineering expertise to solve: climate change, feeding a growing population, energy independence, access to clean water, crumbling infrastructure, and others. And with global economic competitiveness inextricably linked to innovation, employers across a wide range of engineering and non-engineering fields such as health care, management, and marketing are seeking employees with engineering knowledge and related skills. These skills include the ability to creatively and systematically solve ill-defined problems
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Community for Advancing Discovery Research in Education (CADRE)
When it comes to STEM education, the nation’s K–12 public schools cannot do it all. The nature of 21st century proficiency in science, technology, engineering, and mathematics is too complex for any single institution. The good news is that schools do not have to do it alone. Museums, zoos, nature centers, aquariums, and planetariums are among the several thousand informal science institutions in the United States that regularly engage young people in observing, learning, and using STEM knowledge and skills. Providing a richness of resources unavailable in any classroom, informal science
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Community for Advancing Discovery Research in Education (CADRE)
Resources are available to help educators teach nanotechnology topics and find curriculum materials for their classes, including published journal articles, video lectures, laboratory experiment procedures and in-person workshops. Educational materials shared by individual scientists and educators, nanotechnology research centers and professional organizations cover many fields of nanotechnology and all levels of education, both formal and informal. This article reviews these resources with the purpose of increasing their visibility and encouraging their use.
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Kurt WinkelmannLeonard BernasMahmoud Saleh
Bang, Warren, Rosebery, and Medin explore empirical work with students from non-dominant communities to support teaching science as a practice of inquiry and understanding, not as a “settled” set of ideas and skills to learn.
The adoption of the Next Generation Science Standards means that many educators who adhere to model-based reasoning styles of science will have to adapt their programs and curricula. In addition, all practitioners will have to teach modeling, and model-based reasoning is a useful way to do so. This brief offers perspectives drawn from Lehrer and Schauble, two early theorists in model-based reasoning.
Assessing science learning in informal environments involves a series of challenges that are difficult to address using traditional assessment practices (National Research Council, 2009). Some of the assessment challenges inherent in informal and afterschool environments include: (a) interactions in these environments are diverse in terms of duration, type of activity, number of people involved; (b) they usually include emerging behavior due to unpredictable interactions with other participants (e.g., peers, family members, and facilitators); and (c) these environments are characterized by a
Cross-national assessments of student learning in mathematics, science, reading, computer technology, and civics have been successfully conducted since the 1960’s. Each subject required professional researchers and educators from different cultural backgrounds to reach agreement on a common definition of the content areas and measurement techniques for formal schooling. Two international organizations, the International Association for the Evaluation of Educational Achievement (IEA) and the Organization for Economic and Cooperation and Development (OECD) are now continuously conducting
This background paper is intended to support consideration of assessments "in improving program quality and student learning outcomes in the field of informal science education." This includes three questions: (a) What definitions of engagement, interest, curiosity, and motivation might be used in evaluations of informal and after-school science learning programs and activities? (b) Given the diversity of learning experiences, what are the prospects for developing common definitions of engagement, interest, curiosity, and motivation? And, (c) Given the diversity of types of informal and after
The NRC Framework for K – 12 Science Education (2012) lists five major ideas that are essential to the design of assessments and learning environments: 1) limited number of core ideas of science, 2) cross-cutting concepts, 3) engaging students in scientific and engineering practices, 4) building integrated understanding as a developmental process, and 5) the coupling of scientific ideas and scientific and engineering practices to develop integrated understanding. What implications do these major ideas have for assessment in informal science setting? This paper will discuss each of these ideas
Educational researchers, scholars, theoreticians, and practitioners define, interpret, and study out-of school science education in various ways. Some use the term informal, while others prefer free-choice, outdoor education, everyday learning or lifelong learning. Preferences reflect theory, settings and practice, but regardless of the terminology, all researchers who are engaged in learning that occurs outside of schools are convinced that a wide range of environments—structured and unstructured—afford various types of engagement and learning. Learning science in such environments has