In this paper, we outline how science teachers might engage in the work of creating educational equity. While acknowledging the historical inherent inequities associated with issues of access, opportunities to engage in science learning for individuals of marginalized identities (e.g., BIPOC individuals and women), and achievement, we broaden this…

The "Framework for K-12 Science Education" (NRC; 2012) placed renewed emphasis on creating equitable science learning opportunities for all learners by engaging in three-dimensional learning experiences: disciplinary core ideas, crosscutting concepts, and science and engineering practices. Additionally, the "Framework" calls…

In this position paper, we draw from previous research and theoretical developments in the field to propose a set of affordances of engineering with English learners (ELs). Students learning both the language of instruction (e.g., English) and academic subject matter (e.g., engineering, mathematics, science) face the challenge of making sense of…

Problem solving in groups can be rich with tension for students. This tension may arise from conflicting approaches (conceptual and/or epistemological) and/or from conflict emerging in the social relations among group members. Drawing on video records of undergraduate students working collaboratively, we use three cases to illustrate the…

The purpose of this study is to present a conceptual framework that integrates science and language learning for all students, including English learners (ELs). This framework is grounded in the mutually supportive nature of science instructional shifts, spurred by "A Framework for K-12 Science Education" (National Research Council,…

For many decades, science educators have asked, "In what ways should learning the content of traditional subjects serve as the means to more general ends, such as understanding the nature of science or the processes of scientific inquiry?" Acceptance of these ends reduces the role of disciplinary context; the "Footprints Puzzle" and Oregon's…

This paper examines the framings that the fields of the social studies of science and science education use for each other. It is shown that the social studies of science frames science education as passive and timeless. Science education frames science studies as a set of representations to better capture how science works. The paper then…

Examines the mastery learning model as proposed by Carroll and Bloom in the context of science instruction, addressing issues related to classroom application. Discusses expected results of implementing mastery learning and its impact on students and teachers, recognizing the additional burden on teacher time required by mastery learning…

Addresses the importance of recognizing the prior knowledge and misconceptions of science educators. Provides perspectives on the nature of knowledge, conceptions of learning, nature of science and of teaching, and the relationship between general principles of learning and teaching. (ML)

Uses examples related to a head of cabbage to discuss: (1) sensory development in children; (2) the integration of sensory and cognitive involvement; and (3) a child's mode of exploring and discovering. Also discusses why science curricula need to be organized around a paradigm that is holistic. (JN)

This paper presents two perspectives that the author believes will contribute to an enhanced ability to describe and understand learning from museums. Arguably, a major strength of the past decade of research on learning from museums has been the description and investigation of many of the myriad factors that appear to influence learning from…

Suggests, by argument and example, that the views which children bring with them to science lessons are, to them, logical and coherent, and that these views have considerable influence on how and what children learn from their classroom experiences. (Author/SK)

Examines various types of problems that researchers have used to demonstrate problem solving. Focuses on genetics problems. Discusses classes of learning outcomes, conceptual knowledge gains, content-independent heuristics, content-specific procedures, understanding the nature of science and a typology of genetics problems. (CW)

The generative learning model is explored and linked to recent science education research findings. The implications of the model for the teaching and learning of science, the training of science teachers, and science educational research are discussed. (JN)

Argues that there is a strong nonrational component in conceptual change, analyzing aspects of the nonrational or aesthetic that are part of the conceptual change process. Shows that the results of Posner et. al. ("Science Education" 66: 211-27, 1982) support this thesis. (Author/JN)