The American Chemical Society General Chemistry Performance Expectations Project: From Task Force to Distributed Process for Implementing Multidimensional Learning

This contribution reports the process and outcomes of a multiyear effort that supported institutions in reforming general chemistry using multidimensional learning approaches in the form of performance expectations. Performance expectations are based on evidence-centered assessment design principles...

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Veröffentlicht in:	Journal of chemical education 2021-04, Vol.98 (4), p.1112-1123
Hauptverfasser:	Pazicni, Samuel, Wink, Donald J, Donovan, Ashley, Conrad, John A, Darr, Joshua P, Morgan Theall, Rachel A, Richter-Egger, Dana L, Villalta-Cerdas, Adrian, Walker, Deborah Rush
Format:	Artikel
Sprache:	eng
Schlagworte:	Chemistry College Science Cross cutting Education Educational activities Educational Change Elementary Secondary Education Evidence Based Practice Expectation Force distribution Higher education Institutions Instructional Design Learning Learning Activities Organic Chemistry Reforming Science Education Science Instruction Stress concentration Teaching methods Workshops
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container_title	Journal of chemical education
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creator	Pazicni, Samuel Wink, Donald J Donovan, Ashley Conrad, John A Darr, Joshua P Morgan Theall, Rachel A Richter-Egger, Dana L Villalta-Cerdas, Adrian Walker, Deborah Rush
description	This contribution reports the process and outcomes of a multiyear effort that supported institutions in reforming general chemistry using multidimensional learning approaches in the form of performance expectations. Performance expectations are based on evidence-centered assessment design principles and describe what learners should be able to do with their knowledge, a subtle (but profound) shift from traditional course learning goals. The effort grew from the recommendations of a task force appointed in 2015 by the American Chemical Society’s Division of Chemical Education and Society Committee on Education. This task force recommended a participatory process for creating general chemistry performance expectations that was distributed over, and also coordinated across, multiple institutions. With support from the ACS Education Division, this recommendation was enacted through workshops which supported faculty in developing activities and assessments that integrated content, science and engineering practices, and cross-cutting conceptsa three-dimensional structure based on the National Research Council report A Framework for K-12 Education. From these workshops, a group of faculty committed to implementing three-dimensional performance expectations in their courses evolved. In practice, these faculty found that their institutional work resulted in designing learning performances that, while also three-dimensional, were of narrower content focus than is typical of performance expectations. This development process also led faculty to use the structures of evidence-centered design and multidimensional learning to document learning activity designs in new ways, generating a consensus activity structure. As examples of how faculty used this consensus activity structure as a new way to examine student learning and performances, development artifacts from four of the participating institutions is presented.
doi_str_mv	10.1021/acs.jchemed.0c00986
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With support from the ACS Education Division, this recommendation was enacted through workshops which supported faculty in developing activities and assessments that integrated content, science and engineering practices, and cross-cutting conceptsa three-dimensional structure based on the National Research Council report A Framework for K-12 Education. From these workshops, a group of faculty committed to implementing three-dimensional performance expectations in their courses evolved. In practice, these faculty found that their institutional work resulted in designing learning performances that, while also three-dimensional, were of narrower content focus than is typical of performance expectations. This development process also led faculty to use the structures of evidence-centered design and multidimensional learning to document learning activity designs in new ways, generating a consensus activity structure. 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subjects	Chemistry College Science Cross cutting Education Educational activities Educational Change Elementary Secondary Education Evidence Based Practice Expectation Force distribution Higher education Institutions Instructional Design Learning Learning Activities Organic Chemistry Reforming Science Education Science Instruction Stress concentration Teaching methods Workshops
title	The American Chemical Society General Chemistry Performance Expectations Project: From Task Force to Distributed Process for Implementing Multidimensional Learning
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