Scaffolding for Access to Productive Struggle

This article begins by describing a class scenario in which a teacher gives her students the L problem (Watanabe 2008), which involves finding the area of a composite figure. Her students inappropriately extend the area formula for rectangles (A = L x W) to composite figures by multiplying all given...

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Veröffentlicht in:	Mathematics teaching in the middle school 2018-01, Vol.23 (4), p.202-207
Hauptverfasser:	Barlow, Angela T, Gerstenschlager, Natasha E, Strayer, Jeremy F, Lischka, Alyson E, Stephens, D. Christopher, Hartland, Kristin S, Willingham, J. Christopher
Format:	Artikel
Sprache:	eng
Schlagworte:	FEATURES Instructional scaffolding Learning Mathematical functions Mathematical models Mathematical problems Mathematics education Mathematics Instruction Mathematics teachers Middle School Students Middle schools Prior Learning Problem Solving Reasoning Rectangles Scaffolding Scaffolding (Teaching Technique) Scaffolds Teachers Teaching Methods Tutoring
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container_title	Mathematics teaching in the middle school
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creator	Barlow, Angela T Gerstenschlager, Natasha E Strayer, Jeremy F Lischka, Alyson E Stephens, D. Christopher Hartland, Kristin S Willingham, J. Christopher
description	This article begins by describing a class scenario in which a teacher gives her students the L problem (Watanabe 2008), which involves finding the area of a composite figure. Her students inappropriately extend the area formula for rectangles (A = L x W) to composite figures by multiplying all given dimensions. After class, the teacher concluded that although her students struggled, they did not struggle productively: they did not make sense of the mathematical ideas embedded within the task. She wondered what role might scaffolding have played before the task was assigned, to provide students with access to productive struggle. The purpose of this article is to introduce scaffolding as a way to provide access to productive struggle. Following a discussion of traditional views of scaffolding, the authors introduce a new function for scaffolding. Next, they return to the L problem to consider how this new function for scaffolding can be applied to support productive struggle. Finally, they conclude with strategies, such as eliciting prior knowledge, delaying the question, and introducing a simpler problem, for planning access to productive struggle.
doi_str_mv	10.5951/mathteacmiddscho.23.4.0202
format	Article
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subjects	FEATURES Instructional scaffolding Learning Mathematical functions Mathematical models Mathematical problems Mathematics education Mathematics Instruction Mathematics teachers Middle School Students Middle schools Prior Learning Problem Solving Reasoning Rectangles Scaffolding Scaffolding (Teaching Technique) Scaffolds Teachers Teaching Methods Tutoring
title	Scaffolding for Access to Productive Struggle
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