This article describes how two inquiry games promoted student science skills in a museum setting while minimizing demands on teachers, fostering collaboration, and incorporating chaperones. Students who played these games engaged in more scientific inquiry behaviors than did students in control groups.
In order to broaden the conceptualizations of argument in science education, Bricker and Bell draw from diverse fields: the sociology of science, the learning sciences, and cognitive science to help practitioners think of new ways to bring argumentation into learning spaces while expanding what counts as scientific argument.
This paper describes a model developed by education researchers seeking to bridge the gap between formal and informal learning contexts. The model matches organisational, cognitive, affective, and social-environmental aspects of learning with four key design principles to create 16 practical steps to help formal and informal educators communicate and cooperate more effectively.
In this study, researchers investigated levels of awareness of and responsibility for global climate change in two groups of children. The researchers argue that understanding the nature of beliefs, and how they may be modified by particular influences, is important if educators are to challenge the status quo, in which “the majority of individuals do not believe that they are responsible for or can engage in any actions which will be environmentally efficacious” (Uzzell, 2000, p. 314).
Despite increasing interest in the educational potential of outdoor learning experiences, limited research has focused on assessing and identifying “good” outdoor education practice. In this paper, the authors propose a theoretically based practical framework for assessing field trips in nature parks and other outdoor settings. The framework was developed and refined during the course of observations of 22 field trips and interviews with 41 students.
Argumentation in science involves the development, justification, and defence of evidence-based claims, together with the reasoned dispute of counterclaims. This process is the foundation for all scientific endeavours. Supporting the development of argumentation skills, therefore, is a key part of science education. Laboratory work is also as an essential part of science. Combining these two activities, therefore, would seem to be worthwhile. In this study, researchers explored the impact of three different lab-based tasks on the nature and quality of any subsequent argumentation.
In this review paper, Oliver calls for greater cross-pollination between neuroscience research and educational practice. She asks, “What can educators learn from an understanding of educational neuroscience?”
This article discusses intellectual activities in African American culture that privilege mathematical thinking. It is a helpful reference for educators and researchers who want to shift from deficit-oriented perspectives about non-dominant or marginalized groups’ performance to additive perspectives that build on out-of-school cultural knowledge and practices to support student learning in school. The authors suggest how educators might value forms of mathematical thinking that are usually not recognized in school. This recognition can support diverse students’ participation and achievement
In 2009, NSF funded development of Model My Watershed (MMW), a place-based, watershed cyber-modeling tool for middle and high school students and teachers. The online learning tool encourages students to investigate their neighborhoods and use scientific reasoning with real-world decision-making models similar to those used by STEM professionals to simulate systems and analyze processes. The project also sought to increase youth interest in possible opportunities in the STEM workforce and to aid in development of knowledge about earth science. This summary represents the first of a two-phase
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TEAM MEMBERS:
Stroud Water Research CenterJohn Fraser
How People Learn: Bridging Research and Practice provides a broad overview of research on learners and learning and on teachers and teaching. It expands on the 1999 National Research Council publication How People Learn: Brain, Mind, Experience, and School, Expanded Edition that analyzed the science of learning in infants, educators, experts, and more. In How People Learn: Bridging Research and Practice, the Committee on Learning Research and Educational Practice asks how the insights from research can be incorporated into classroom practice and suggests a research and development agenda that
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TEAM MEMBERS:
M. Suzanne DonovanJohn BransfordJames Pellegrino
This chapter discusses variation in the organization of children’s involvement in cultural activities. In particular, we examine three widespread cultural traditions that organize children’s learning and participation in cultural activities: intent community participation, assembly-line instruction, and guided repetition. We argue that investigating the organization of children’s participation in routine activities offers a way to address the dynamic nature of repertoires of cultural practices—the formats of (inter)action with which individuals have experience and may take up, resist, and
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Barbara RogoffLeslie MooreBehnosh NajafiAmy DexterMarciela Correa-ChavezJocelyn Solis
The Computer Clubhouse aims to help inner-city youth gain that type of technological fluency. The Computer Clubhouse is designed to provide inner-city youth with access to new technologies. But access alone is not enough. The Clubhouse is based not only on new technology, but on new ideas about learning and community. It represents a new type of learning community—where young people and adult mentors work together on projects, using new technologies to explore and experiment in new ways.
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TEAM MEMBERS:
Mitchel ResnickNatalie RuskStina Cooke