Abstract
Visuospatial thinking is considered crucial for understanding of three-dimensional spatial concepts in STEM disciplines. Despite their importance, little is known about the underlying cognitive processing required to spatially reason and the varied strategies students may employ to solve visuospatial problems. This study seeks to identify and describe how and when students use imagistic or analytical reasoning when making pen-on-paper predictions about molecular geometry and if particular reasoning strategies are linked to greater accuracy of responses. Student reasoning was evidenced through pen-on-paper responses generated by high attaining, high school students (N = 10) studying Valence Shell Electron Pair Repulsion (VSEPR) Theory in their final year of chemistry. Through analysis and coding of students’ open-ended paper-based responses to an introductory task, results revealed that students employed multiple reasoning strategies, including analytical heuristics and the spontaneous construction of external diagrammatic representations to predict molecular geometry. Importantly, it was observed that despite being instructed on the use of VSEPR theory to find analytical solutions, some students exhibited preference for alternative reasoning strategies drawing on prior knowledge and imagistic reasoning; showing greater accuracy with 3D diagrammatic representations than students who used the algorithmic method of instruction. This has implications for both research and practice as use of specific reasoning strategies are not readily promoted as a pedagogical approach nor are they given credit for in national examinations at school level.
Highlights
Theoretical backgroundMuch attention has been given to the role of visuospatial ability for learning in science, technology, mathematics and engineering (STEM) disciplines spanning several decades (Guay and McDaniel, 1977; West, 1991; Hegarty, 2004; Lubinski, 2010; Stieff, 2011; Stieff et al, 2020)
This study explores visuospatial thinking through students’ use of imagistic, analytical, and diagrammatic reasoning when predicting molecular geometry
Results suggest that use of the taught Valence Shell Electron Pair Repulsion (VSEPR) Theory algorithm did not appear to influence the absolute accuracy as assessed by the textual and diagrammatic features within
Summary
Theoretical backgroundMuch attention has been given to the role of visuospatial ability for learning in science, technology, mathematics and engineering (STEM) disciplines spanning several decades (Guay and McDaniel, 1977; West, 1991; Hegarty, 2004; Lubinski, 2010; Stieff, 2011; Stieff et al, 2020). Understanding how visuospatial thinking can enable STEM learners to construct and organise their subject knowledge through varied reasoning strategies is key to developing new and improved student learning support materials, digital teaching tools and widening access to the STEM disciplines. Imagistic reasoning refers to the process of spatial visualisation which involves generating and manipulating perceived analog image-like mental representations and perspective taking for spatial thinking; its role is taken as self-evident to STEM problem solving (West, 1991; Hegarty, 2004; Stieff, 2011). In particular have for some time employed imagistic reasoning when visualising and representing submicroscopic 3D structures and processes from illustrated, two-dimensional representations in textbooks (Bodner and Guay, 1997). An organic chemist may approach drug design by first imagining how well a molecule would fit into the active site of a specific protein molecule (Stieff, 2011)
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