Richard Pennington scite author profile

Spatial reasoning is defined as the ability to generate, retain, and manipulate abstract visual images. In chemistry, spatial reasoning skills are typically taught using 2-D paper-based models, 3-D handheld models, and computerized models. These models are designed to aid student learning by integrating information from the macroscopic, microscopic, and symbolic domains of chemistry. Research has shown that increased spatial reasoning abilities translate directly to improved content knowledge. The recent explosion in the popularity of smartphones and the development of augmented reality apps for them provide, a yet to be explored, way of teaching spatial reasoning skills to chemistry students. Augmented reality apps can use the camera on a smartphone to turn 2-D paper-based molecular models into 3-D models the user can manipulate. This paper will discuss the development, implementation, and assessment of an augmented reality app that transforms 2-D molecular representations into interactive 3-D structures. AbstractSpatial reasoning is defined as the ability to generate, retain, and manipulate abstract visual images. In chemistry, spatial reasoning skills are typically taught using 2-D paper-based models, 3-D handheld models, and computerized models. These models are designed to aid student learning by integrating information from the macroscopic, microscopic, and symbolic domains of chemistry. Research has shown that increased spatial reasoning abilities translate directly to improved content knowledge. The recent explosion in the popularity of smartphones and the development of augmented reality apps for them provide, a yet to be explored, way of teaching spatial reasoning skills to chemistry students. Augmented reality apps can use the camera on a smartphone to turn 2-D paper-based molecular models into 3-D models the user can manipulate. This paper will discuss the development, implementation, and assessment of an augmented reality app that transforms 2-D molecular representations into interactive 3-D structures.

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Insights and Initiatives While Teaching Organic Chemistry I and II with Laboratory Courses in the Time of COVID-19

Anzovino

Mallia

Morton

et al. 2020

J. Chem. Educ.

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As the COVID-19 pandemic posed a great deal of challenge to the higher education community, the curricula for online instruction had to be developed in a very short time period. Adaptations for Organic Chemistry I and II with Laboratory courses have been made for the online transition in response to the pandemic, and the insights gained through individual and collaborative efforts are presented by Georgia Gwinnett College (GGC) Organic Chemistry faculty. Herein, course specific information with a distinction between lecture and lab and the analysis of student assessment and withdrawal provide insights into the virtual instruction. The initiative of instructors played a crucial role during the transition and for maintaining student engagement, and the insights will add valuable resources for further virtual or hybrid instruction.

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Maximizing Student Engagement Outside the Classroom with Organic Synthesis Videos

et al. 2019

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A series of organic chemistry synthesis problem sets were provided to students. Potential solution pathways and strategies were recorded on video by the instructor and provided to students electronically via YouTube. Performance on the end-of-semester synthesis exam showed significant gains, with the average increasing by 13% after the introduction of the synthesis videos. Further studies were conducted to determine if students would benefit from video access through the augmented reality app Aurasma (HP Reveal) in comparison with access through the learning management system (LMS), but no significant increases in viewing habits or performance were found.

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N-Hydroxy sulfonimidamides as new nitroxyl (HNO) donors

Pennington

Sha

King

2005

Bioorganic & Medicinal Chemistry Letters

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