Within recent history, both science research and science education have been largely reductionist in perspective. While the reductionist approach has resulted in a significant increase in our knowledge of the natural world and in great technological advances, it is not sufficient for addressing global world challenges, such as sustainability, pollution, climate change, and poverty. We, as members of the Systems Thinking in Chemistry Education (STICE) project, argue that for science in general, and chemistry in specific, to continue to advance and for citizens to be prepared to participate knowledgeably and democratically in science-related policy decisions, the reductionist approaches that are commonly used in chemistry research and chemistry education must be complemented with a more holistic approach. Systems thinking is such an approach. This article discusses the historical development, describes the key characteristics, and presents some skills and competencies associated with systems thinking. Our intention is to provide chemical educators with enough basic information about systems thinking that they can consider why and how such an approach might be applied in the education of both future chemists and future global citizens.
Lymphedema assessment methods are concordant and reliable but not interchangeable.
Recently, there have been calls to integrate systems thinking approaches into chemistry education in order to strengthen students' conceptual understanding, build their problem-solving capabilities, and prepare them to make informed, ethical decisions about globally relevant issues, such as sustainability. Unfortunately, implementation of systems thinking approaches in chemistry classrooms currently poses challenges. Exemplar systems thinking materials with a STEM focus are limited, particularly at the tertiary level. Moreover, the science education community has yet to agree upon a systems thinking definition or develop a comprehensive list of systems thinking skills that students should develop. Thus, a current priority for the advancement of systems thinking in chemistry education is the development of resources for instructors and students alike. In the current project, we constructed a tool that provides an operational definition for systems thinking in chemistry education and serves as guide for the design, analysis, and optimization of systems thinking activities. The Characteristics Essential for designing or Modifying Instruction for a Systems Thinking approach (ChEMIST) table identifies five essential characteristics of a systems thinking approach, along with corresponding systems thinking skills through which students can demonstrate their engagement in each essential characteristic. Here, we describe the inspiration and development of the tool. We also provide examples of how the tool might be used to support chemistry teaching and learning from a systems thinking approach. Finally, we present some initial ideas about the relationship between systems thinking and other approaches to chemistry education reform.
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