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Exploring Undergraduate Organic Chemistry Students’ Strategies and Reasoning when Solving Organic Synthesis ProblemsBodé, Nicholas 24 September 2018 (has links)
Organic synthesis problems are a common assessment tool in organic chemistry courses, as they give instructors the opportunity to determine students’ ability to integrate and apply their knowledge of reactions and skills learned in the course. However, students often tend to be unsuccessful in solving them, even if they appear to have a strong grasp on other course material. We hypothesized that part of the reasoning behind this issue is because it can be challenging to integrate learning activities into the curriculum that give students the opportunity to apply their knowledge to synthetic problem solving, while still giving students the opportunity to master the underlying concepts (knowledge of organic reactions and reaction mechanisms). In addition, there is a gap in our understanding of the mental models students construct while solving these problems, as there is no evidence that they approach these problems in the same manner that experts do (i.e., retrosynthetic analysis). The research described in this thesis was performed to address these issues in two ways. First, we designed learning activities for students that were meant to help them develop more systematic approaches (whose benefits are supported by evidence) to solving synthesis problems, and determining if those learning activities could produce significant learning gains. The learning activities we designed were made available to students through out-of-class learning workshops, where learning gains were primarily measured through the analysis of students’ synthetic problem-solving abilities, assessed immediately before and after the workshops. Second, we sought to obtain a better understanding of students’ mental models when solving synthesis problems; specifically, we wanted to see if they had well-defined strategies for approaching these problems, and if they had a canonical understanding of how these strategies were meant to be applied. To do so, we invited students to participate in semi-structured think-aloud interviews, where participants were asked to solve synthesis problems. We investigated both of these topics using a constructivist paradigm for learning, which states that knowledge is constructed in the mind of the learner rather than passively imparted. The process of knowledge construction is heavily influenced by the prior knowledge and experiences of the learner, and meaningful understanding of new knowledge is unlikely to occur if new knowledge cannot be accommodated by existing knowledge structures. Results from these studies indicated that the workshop-style intervention did not have any effect on students’ ability to successfully solve synthesis problems, but we did observe proficiency in the ability to use expert-like strategies, suggesting that more practice over time could lead to the ability to solve synthesis problems more effectively. Our analysis of the interview data showed that some students can proficiently use strategies in situations that are familiar to them, but do not appear to be able to apply those strategies to predict outcomes in unfamiliar situations; further, we observed a strong reliance on the use of reasoning that was based on memorized rules. Future work could further explore the mental models that students construct for solving synthesis problems; we recommend the incorporation of specific instruction on the use of synthesis problem-solving strategies, and research could explore the relationship between students’ abilities, and how synthesis is taught, practiced, and assessed in the organic chemistry curriculum.
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Exploring Students’ Initial Interpretations of the Electron-Pushing Formalism ArrowsHuang, Denzel 11 August 2022 (has links)
Chemists use the electron-pushing formalism to rationalize, analyze, and explain how a chemical reaction occurs on an electronic level. The electron pushing formalism (EPF) is the curved arrows representing electron movement. Some research on undergraduate organic chemistry students’ understanding of the electron pushing formalism has presented evidence that some students do not find the electron-pushing formalism meaningful. Research at the University of Ottawa found that the EPF symbolism is meaningful to the participants because they interpret EPF arrows and use charges and mapping to problem-solve.
At the University of Ottawa, the organic chemistry curriculum was changed in 2012 to have students learn and interpret reactions based on similar reactivity patterns. The goal of the redesign was to give students the tools to analyze, predict, and explain how reactions occur instead of memorizing. An initial section of the curriculum is dedicated to teaching the electron-pushing formalism before any reaction. An exam analysis was conducted to see the new curriculum's effect by looking at students' drawn structures and EPF arrows. Students demonstrated minimal errors when drawing the EPF arrows and scored higher on familiar and unfamiliar reactions following the new curriculum, which suggests students found the EPF arrows meaningful. The following think-aloud interview study better captured student interpretations of the EPF arrows to determine what features students found relevant and whether the students who could explain a conceptual understanding of the EPF arrows could express a deeper understanding. The think-aloud interviews found that students do place meaning into organic chemistry representations as students were thinking about how to draw the EPF arrows based on prior knowledge. The data from the two previous studies were collected near the end of the course when students had a significant amount of experience, while students’ initial interpretations of the EPF arrows are needed.
The primary focus of this thesis is to understand how students initially interpret the electron-pushing formalism arrows and look further into previous findings, which include electron movement, bond-forming and breaking processes, mapping, charges, stepwise reasoning, and transplanting electrons. Twelve students were recruited from Organic Chemistry I and interviewed over three weeks after being taught the electron-pushing formalism. The interviews were conducted using a think-aloud procedure to capture students’ thoughts, and each interview lasted approximately 1 hour. The instrument consisted of six organic chemistry questions, specifically chosen, as students would not encounter them in the class and would have to interpret the representations. The transcripts were analyzed with respect to the previous studies' findings and compared among participants to explore students’ interpretations and use of the EPF arrows.
The findings from this study suggest participants found the EPF arrows meaningful because participants interpreted the representations as electron-movement, bond-forming, and bond-breaking processes which contrasts some prior research that reported students do not find the EPF arrows meaningful (Bhattacharyya and Bodner, 2005; Graulich, 2015). Participants connected the EPF arrows to electron movement, bond-forming, and bond-breaking processes. Participants compared surface features to determine how to draw the EPF arrows. Participants’ visualization and how they approached the reactions differed. Participants’ visualizations of the organic chemistry reaction were divided between a stepwise or concerted visualization. Most participants approached the EPF arrows stepwise as a problem-solving tool as it was easier for them to understand. Participants correctly interpreted most bond-breaking EPF arrows, but some participants relocated the electron pair onto a different atom instead of forming a bond. Participants mainly mapped the carbon atoms with numeric labels and found implicit atom-type questions challenging. Participants interpreted charges as an important surface feature and used charges to help them solve the question. Participants viewed charges as a reactive location where bonds break and form and compared the number of charges between reactants and products to check whether their answers were correct. The results suggest the participants in the study found the EPF arrows and made meaningful connections at the submicroscopic level with minimal experience.
Mastering the EPF arrows at the beginning of the course appears beneficial to student learning because participants interpreted the EPF arrows as a meaningful representation suggesting that the EPF arrows are less of a barrier when learning and mastering organic chemistry, under the University Of Ottawa’s organic chemistry curriculum as intended. Since the EPF arrows are less of a barrier, students can focus on other organic chemistry concepts and can be more successful which is seen in the first exam analysis where minimal errors were seen. The first exam analysis observed minor pentavalent atoms and errors with the EPF arrows (Flynn and Featherstone, 2017). The following interview study found students described mapping, charges, stepwise, and chemistry reasoning when discussing electron movement (Galloway et al., 2017). The findings from this work demonstrated the EPF arrows as a representation are meaningful to participants as they interpreted the EPF arrows after being recently taught. Similar findings at a different institution using a revised curriculum that focuses on the EPF at the beginning of the course found students were more likely to use the EPF arrows and were more likely to provide the correct answer than their counterparts (Crandell et al., 2018; Houchlei et al., 2021). Research at institutions adopting the functional group curriculum reported that students did not find the EPF meaningful (Bhattacharyya and Bodner, 2005; Ferguson and Bodner, 2008; Grove, Cooper, and Rush, 2012). The findings suggest that the time spent mastering the EPF arrows at the beginning of the course is beneficial when learning organic chemistry because the symbols are less likely to be a hindrance through misinterpretation, and students can focus on mastering organic chemistry concepts.
Implications for teaching and learning include providing clarity on interpreting the EPF arrows and using the transplanting processes to demonstrate other chemical possibilities. Participants demonstrated comparing reactants and products when problem-solving. When students face difficulty, they should compare the products of chemical processes (bond-forming, bond-breaking, or electrons moving). The correct process has the EPF arrow starting from electrons and point to an atom or bond, maintains the conservation of atoms, and electrons stay with one of the originating atoms. The other processes will not follow one of the above principles, thus making them illogical.
Future work could further explore if students interpret the EPF arrows as a whole or if they interpret the arrowhead and arrow tail. Why do some students face difficulty keeping electrons on an originating atom? Why do some students face difficulty conserving atoms, electrons, and charges throughout a reaction? Whether the findings are generalizable by expanding the sample size.
In the context of the new curriculum, it appears students' have acquired a better understanding of the EPF. The results are promising because participants with minimal experience interpreted the EPF arrows and found them meaningful as a symbolic representation aligned with the curriculum's intentions.
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Investigating Students’ Intelligence Mindset in the Chemistry Laboratory: Assessing Students’ Beliefs about Effort, Ability, and Success in the Undergraduate Chemistry LaboratoryFullington, Sarah Ann 31 March 2022 (has links)
No description available.
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A Change in Structure: Meaningful Learning and Cognitive Development in a Spiral, Organic Chemistry CurriculumGrove, Nathaniel P. 01 May 2008 (has links)
No description available.
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Investigation and Evaluation of Scientific Reasoning Development in the College Chemistry ClassroomCarmel, Justin H. 21 July 2015 (has links)
No description available.
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STUDENTS’ UNDERSTANDING OF MICHAELIS-MENTEN KINETICS AND ENZYME INHIBITIONJon-Marc G Rodriguez (6420809) 10 June 2019 (has links)
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<p>Currently there is a need for research that explores students’ understanding of advanced topics in
order to improve teaching and learning beyond the context of introductory-level courses. This
work investigates students’ reasoning about graphs used in enzyme kinetics. Using semi-structured
interviews and a think aloud-protocol, 14 second-year students enrolled in a biochemistry course
were provided two graphs to prompt their reasoning, a typical Michaelis-Menten graph and a
Michaelis-Menten graph involving enzyme inhibition. Student responses were coded using a
combination of inductive and deductive analysis, influenced by the resource-based model of
cognition. Results involve a discussion regarding how students utilized mathematical resources to
reason about chemical kinetics and enzyme kinetics, such as engaging in the use of
symbolic/graphical forms and focusing on surface-level features of the equations/graphs. This
work also addresses student conceptions of the particulate-level mechanism associated with
competitive, noncompetitive, and uncompetitive enzyme inhibition. Based on the findings of this
study, suggestions are made regarding the teaching and learning of enzyme kinetics.
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A change in structure meaningful learning and cognitive development in a spiral, organic chemistry curriculum /Grove, Nathaniel P. January 2008 (has links)
Thesis (Ph. D.)--Miami University, Dept. of Chemistry and Biochemistry, 2008. / Title from first page of PDF document. Includes bibliographical references (p. 121-127).
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Investigating General Chemistry and Physical Chemistry Students' Understanding of Solutions Chemistry: The Development of the Enthalpy and Entropy in Dissolution and Precipitation InventoryAbell, Timothy Noah 15 April 2019 (has links)
No description available.
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STUDENTS’ UNDERSTANDINGS OF ACID-BASE REACTIONS INVESTIGATED THROUGH THEIR CLASSIFICATION SCHEMES AND THE ACID-BASE REACTIONS CONCEPT INVENTORYJensen, Jana D. 22 April 2013 (has links)
No description available.
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Incorporating Argumentation Into a General Chemistry Non-majors CourseJessica Ahn Callus (13157271) 26 July 2022 (has links)
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<p>Over the years it has become more common for practitioners to use the NGSS scientific practices to inform curricula at the undergraduate level. One of these practices is argumentation, the process of engaging in argument from evidence. Argumentation is an important part of the scientific process because scientists must make claims about their research and then provide justification using evidence to support those claims. While being able to argue your claim based on evidence is a common occurrence for scientists, it is rarely something students engage with in general level courses. In order to incorporate argumentation in the classroom the Claim, Evidence, Reasoning (CER) framework was adopted to develop the argumentation materials. </p>
<p>In this study, aspects of the CER framework have been adapted and incorporated into the existing curriculum of a second-semester general chemistry non-majors course. The changes include lecture discussions, worksheets, and exam questions to help scaffold and facilitate students’ argumentation development. In the spring 2020 and 2021 semesters, 80 students in each course were tracked through their CER assessments to gain insight into how students construct arguments. The arguments were analyzed based on completeness, correctness, and complexity. The results show support for the effectiveness of the curriculum intervention and were used to make recommendations for instructors using the CER framework and identify future areas of research.</p>
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