Empirical interdisciplinary research has explored the role of spatial ability in STEM learning and achievement. While most of this research indicates that fostering spatial thinking in educational contexts has the potential to positively impact students’ enrollment and performance in STEM subjects, there is less agreement on the best approach to do so. This article provides an overview of various types of effective spatial interventions and practices in formal or informal educational contexts, including targeted training of STEM-relevant spatial skills, spatialized curricula embedded in schools, integrated STEM practices addressing students’ use of spatial skills, and spatial activities in informal STEM education. Gender and socio-economic status of students – two variables that have been found to moderate the relationship between students’ spatial ability and their STEM performance – are also discussed in this article. Drawing on a wide spectrum of perspectives on situating spatial ability research in STEM education contexts, this article underscores the need for further inquiry into opportunities for developing K-12 students’ spatial ability through integrated and informal STEM practices. This article proposes a conjecture that the relationship between developing students’ spatial ability and enhancing their abilities to solve spatially complex STEM problems is bidirectional. Recommendations for future research are made on lingering questions about the effect of interventions, untapped resources for spatial ability training in formal and informal STEM education, and educational strategies for developing students’ spatial ability in authentic learning environments.
Encoding intangible data variables with visual, spatial, and physical properties demands a high level of spatial reasoning. The ability to reason spatially is widely deemed critical to science, technology, engineering, arts, and mathematics (STEAM) learning. While much research has explored the relationship between learning with visualizations and spatial skills development, little is known about how children use their spatial reasoning in constructing tangible visualizations. This work-in-progress investigates how data physicalization activities, organized within a Design module in primary classrooms in the Netherlands, provide a window to understanding children's spatial reasoning about data. Based on preliminary analysis, we identify six indicators of children's spatial reasoning as observed in their constructing processes and artifacts. Most children in the study used tangible materials of varied sizes, curated meaningful spatial arrangements, and employed different unitizing methods to encode numerical data with spatial properties. Some children adjusted the sizes, units, or spatial arrangement to refine their tangible visualizations, considered the pros and cons of twoand three-dimensional forms of presentation, and made creative use of spatial shapes. In summary, this case study offers insights into children's use of spatial reasoning in data physicalization creation and practical implications for situating data physicalization activities in formal learning environments.
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