The Task Navigator Following the STRAKNAP Concept: Development, Application, and Evaluation of a New Scaffold to Support Nonmajor Chemistry Students while Solving Tasks in Organic Chemistry

Hermanns, Jolanda

doi:10.1021/acs.jchemed.0c01162

Cited by 6 publications

(21 citation statements)

References 40 publications

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“…A variety of studies address students’ understanding of leaving groups in organic chemistry. Students often use leaving groups to categorize reactions and can correctly identify leaving groups when provided with mechanistic steps; ,, however, students can struggle to identify “hidden” leaving groups in other reaction types (e.g., acetal reactions) . Many students refer to leaving groups as “good” without providing explanation, suggesting that students might be using surface features to memorize leaving group ability rather than using chemical reasoning. ,, Similarly, students’ reasoning about leaving group departure steps is often teleological rather than causal; for example, students often focus on creating good leaving groups rather than reasoning based on chemical properties. ,, However, some students invoke the octet rule, charge to size ratio, and electronegativity to reason about leaving group ability and leaving group departure steps. ,, …”

Section: Discussionmentioning

confidence: 99%

“…A variety of studies address students' understanding of leaving groups in organic chemistry. Students often use leaving groups to categorize reactions and can correctly identify leaving groups when provided with mechanistic steps; 40,87,107 however, students can struggle to identify "hidden" leaving groups in other reaction types (e.g., acetal reactions). 89 Many students refer to leaving groups as "good" without providing explanation, suggesting that students might be using surface features to memorize leaving group ability rather than using chemical reasoning.…”

Section: Leaving Groupsmentioning

confidence: 99%

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Mechanistic Reasoning in Organic Chemistry: A Scoping Review of How Students Describe and Explain Mechanisms in the Chemistry Education Research Literature

Dood

Watts

2022

J. Chem. Educ.

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Organic chemistry reaction mechanisms are central to the discipline of organic chemistry but challenging for students to learn and for instructors to teach. Due to the unique challenges surrounding the topic, reaction mechanisms have been the focal point of many studies within organic chemistry education research. This article provides a scoping review of the existing research on students' descriptions and explanations of organic chemistry reaction mechanisms and synthesizes the results and implications of the body of literature. The first half of the article provides an overview of the various reasoning frameworks researchers use to characterize students' reasoning with reaction mechanisms, including synthesizing the literature on students' approach to reaction mechanisms using a range of teleological, anthropomorphic, mechanistic, and causal reasoning. The second half of the article synthesizes the findings in the literature regarding students' explanations of features and concepts common across reaction mechanisms (i.e., the electron-pushing formalism, nucleophiles and electrophiles, acid−base theories, resonance, leaving groups, and carbocations). Findings across the literature regarding approaches for supporting students' reasoning with each feature and concept are described within each section. The review concludes with a synthesis of the implications for instruction and provides an overview of directions for future research.

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Section: Discussionmentioning

confidence: 99%

Section: Leaving Groupsmentioning

confidence: 99%

Mechanistic Reasoning in Organic Chemistry: A Scoping Review of How Students Describe and Explain Mechanisms in the Chemistry Education Research Literature

Dood

Watts

2022

J. Chem. Educ.

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“…Another challenge often faced by students is the need to consider and translate between the multiple representations of molecular structures and processes (e.g., IUPAC names, Newman projections, bond-line, EPF mechanisms, reaction coordinate diagrams), which can impact success in organic chemistry problem solving. ,,,, For instance, students in one study were more likely to arrive at the correct solution to organic chemistry problems (e.g., outline a synthesis, draw all possible isomers) when they drew more representations, including mechanisms . Despite the importance of multiple representations in organic chemistry, many studies show that it is challenging for students to translate between them (e.g., between different structural representations or between verbal and symbolic representations). ,, However, encouraging students to use models, especially physical models, can support their ability to translate between different structural representations (e.g., between Newman projections and bond-line structures). − A variety of studies focus specifically on how students consider reaction coordinate diagrams (RCDs) when solving mechanism problems. ,− Findings indicate that students often think that only the major reactants, intermediates, or products of mechanisms are depicted on RCDs .…”

Section: Discussionmentioning

confidence: 99%

Students’ Strategies, Struggles, and Successes with Mechanism Problem Solving in Organic Chemistry: A Scoping Review of the Research Literature

Dood

Watts

2022

J. Chem. Educ.

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Solving problems in organic chemistry often requires the consideration of reaction mechanisms. As such, much research has been devoted to the examination of how students consider mechanisms when solving various types of organic chemistry problems, such as predicting the products of a reaction or proposing a synthesis. This article provides a scoping review of this body of research, with a focus on the key themes in the research literature regarding students’ problem solving with organic reaction mechanisms. We first review the literature focused on how students approach mechanism problems in organic chemistry and the common challenges students face with using the electron-pushing formalism. We then identify and synthesize the research findings related to four themes prevalent in the literature about students’ mechanistic problem solving. The first two themes are concerned with common difficulties students demonstrate when solving mechanism problems: (1) solving problems with a product-oriented, rather than process-oriented, approach and (2) focusing on surface features rather than implicit properties of chemical structures and mechanisms. The second two themes involve the particularly challenging aspects of problem solving with reaction mechanisms: the need to (1) consider multiple representations and (2) reason with multiple variables. After discussing these themes, we review the research on how mechanistic problem solving develops through undergraduate and graduate school and then review the literature focused on using and developing authentic problem types to support students’ learning. We conclude by synthesizing implications for teaching and supporting students’ development of problem solving with organic reaction mechanisms.

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“…Since the students rated those materials as helpful, − we wanted to integrate them in our online course. Because task navigators proved to be especially helpful, new task navigators for the tasks were developed and used (for an example see Appendix 2). The task navigators take over the role of the tutors in the seminars, who normally support students, for example by explaining the content.…”

Section: Design Of the Online Coursementioning

confidence: 99%

“…We observed before that students struggle with such tasks and tackled the problem by providing task navigators for selected tasks (for an example see Appendix 2) and solutions with detailed comments concerning problem solving strategy. The task navigators 12 provide the students with three different categories of tips: strategic tips, tips on the knowledge required, and application tips where this knowledge should be applied. The students could download the tasks with the accompanying script for the week at hand.…”

Section: Tasksmentioning

confidence: 99%

Online Teaching in the Course “Organic Chemistry” for Nonmajor Chemistry Students: From Necessity to Opportunity

et al. 2020

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In this communication the development of an online course on the topic “organic chemistry” for nonmajor chemistry students is described and discussed. For this online course, the existing classroom course was further developed. New elements such as podcasts, task navigators, and a forum for discussing the solving of tasks or problems with the content were added. This new online course was evaluated. Therefore, a questionnaire was developed. This consists of questions with regard to the longtime learning behavior of the students and to the online learning. The results of this evaluation show that a preference for online learning and a preference for classroom teaching can be measured separately in two scales. Students’ values on the scale representing a preference for online learning correlate positively and significantly with confidence in the choice of the study subject, enthusiasm about the subject, and the ability to organize their learning, learning environment, and time management. They correlate also with the satisfaction concerning the materials provided. Students’ values for one of those teaching methods also correlate with their rating with regard to their exam preparation. Values representing a preference for online teaching correlate positively with students’ better feeling of exam preparation. Values representing a preference for classroom teaching show negative correlations with the values representing students’ similar or even better preparation for the exams as a result of online teaching. It is therefore not surprising that the ratings for the two scales correlate with the wish for a combination of online teaching and classroom teaching in the future. As a solution, a new course concept for the time after the corona virus crisis that suits all students is outlined in the outlook.

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The Task Navigator Following the STRAKNAP Concept: Development, Application, and Evaluation of a New Scaffold to Support Nonmajor Chemistry Students while Solving Tasks in Organic Chemistry

Cited by 6 publications

References 40 publications

Mechanistic Reasoning in Organic Chemistry: A Scoping Review of How Students Describe and Explain Mechanisms in the Chemistry Education Research Literature

Mechanistic Reasoning in Organic Chemistry: A Scoping Review of How Students Describe and Explain Mechanisms in the Chemistry Education Research Literature

Students’ Strategies, Struggles, and Successes with Mechanism Problem Solving in Organic Chemistry: A Scoping Review of the Research Literature

Online Teaching in the Course “Organic Chemistry” for Nonmajor Chemistry Students: From Necessity to Opportunity

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