This article explores the effectiveness of intervention discussion sections for a college general chemistry course designed to apply research on student preconceptions, knowledge integration, and student explanation. Two interventions, on bond energy and spontaneity, were tested and intervention student performance was compared with that of a control group that did not use the experimental pedagogy. Results indicate that this instruction, which identifies students' initial conceptions and integrates those ideas into class discussion, leads to enhanced conceptual understanding. The intervention group outperformed the control group on a written course midterm, the thermodynamics portion of a standardized American Chemical Society examination, and an in‐depth interview. In interviews, the intervention group students explained the energetics of bond breaking and formation at a more sophisticated level than did the control students. In contrast, control students were more tenuous in their thinking, tended to contradict themselves more when discussing bond energy, and harbored more misconceptions about spontaneity. © 2002 Wiley Periodicals, Inc. J Res Sci Teach 39: 464–496, 2002
This study examined similarities and differences in study approaches reported by general chemistry students performing at different achievement levels. The study population consisted of freshmen enrolled in a required year-long general chemistry course at the U.S. Naval Academy. Students in the first and second semesters of the course were surveyed using a modified version of the published Approaches and Study Skills Inventory for Students (ASSIST) referred to as the M-ASSIST (Modified Approaches and Study Skills Inventory). Responses to items associated with using deep or surface approaches to studying were examined for students of three achievement levels (A/B, C, and D/F course grades) using both ANOVA and Structured Means Modeling to look for differences in study approaches between achievement levels. Results show that, with only 12 items, the M-ASSIST can be used to measure differences in reported use of deep and surface approaches by students in different achievement groups; that Structured Means Modeling can uncover significant differences that are not apparent with an ANOVA analysis of the same data; and that A/B and D/F students can be classified as reporting using either using primarily deep (A/B students) or primarily surface (D/F) study approaches. C students reported study approaches characteristic of both the A/B and D/F groups, leading to the interpretation that C students may be in an intermediate and possibly transitional state between the higher- and lower-grade groups. These results suggest a new understanding of C students as those who may not fully implement deep approaches to studying but, in general, demonstrate less reliance on surface approaches than lower-achieving students.
In the studies reported here, we investigate the effects of context on students' molecular-level ideas regarding aqueous solutions. During one-on-one interviews, 19 general chemistry students recruited from a two-year community college and a research university in the United States were asked to describe their molecular-level ideas about various aqueous solutions in the contexts of conductivity and boiling-point (BP) elevation. Results indicate that context is important for determining the molecular-level ideas that students express. Specifically, students were significantly more likely to draw pictures of aqueous NaCl as separated ions in the conductivity context compared with the BP elevation context, for which they more often drew "molecular" NaCl. This phenomenon was particularly striking because the students drew molecular-level NaCl(aq) pictures in the BP elevation context just minutes after completing the identical task in the context of conductivity. Additional data from laboratory assignments and course examinations further indicate that, even if students are able to correctly represent the molecular level in some contexts, their knowledge may remain inert in slightly different contexts. The results emphasise the importance of the context dependence of molecular-level ideas and have implications for designing instruction in which students develop robust, coherent understandings that they can apply appropriately in new contexts.
This study investigated relationships between the thinking processes that 28 undergraduate chemistry students engaged in during guided discovery and their subsequent success at reasoning through a transfer problem during an end-of-semester interview. During a guided-discovery laboratory module, students were prompted to use words, pictures, and symbols to make their mental models of chemical compounds added to water explicit, both prior to the start (initial model) and at the end (refined model) of the module. Based on their responses to these model assignments, we characterized students’ knowledge and thinking processes, including the extent to which individual students engaged in (a) constructing molecular-level models that were consistent with experimental evidence; (b) constructing molecular-level models that progressed toward scientific accuracy; (c) constructing molecular-level models that were scientifically correct; (d) making connections between laboratory observations and the molecular-level behavior of particles; (e) accurate metacognitive monitoring of how their molecular-level models changed; and (f) using evidence to justify model refinements. Analyses revealed three thinking processes that were strongly associated with correct reasoning in the transfer context during an end-of-semester interview: constructing molecular-level models that were consistent with experimental evidence, engaging in accurate metacognitive monitoring, and using evidence to justify model refinements. The extent of student engagement in these three key thinking processes predicted correct reasoning in a new context better than the scientific correctness of a student’s content knowledge prior to instruction. Although we did not explore causal relationships, these results suggest that integrating activities that promote the key thinking processes identified into instruction may improve students’ understanding and success at transfer.
Student interviews have found an increasingly important place in the educational research landscape. They are used to create and validate assessments and concept inventories, as well as to more clearly elucidate student thinking. One-on-one interviews are most often completed in person at the researcher’s or student’s institution. There are significant advantages, however, of conducting interviews remotely including access to more varied populations, travel-related time and cost savings, and the ability of a single researcher to efficiently collect data at multiple institutions. This paper presents a description of a remote interview process along with details of ways to maintain commonality with its in-person analog. Our research provides evidence that the efficacy of results is maintained and that remote interviews provide a viable alternative to more costly and time-intensive on-site interviews. These results are particularly timely as ways to enable graduate education and research to continue during the COVID-19 pandemic response.
On the basis of the results of two prior studies at the US Naval Academy (USNA), which described the choice of study resources and the self-reported learning approaches of students of differing achievement levels, the current investigation examines how students of differing achievement levels in general chemistry actually solve multiple-choice questions. A think-aloud protocol was selected as the vehicle for this investigation. This research utilized and compared the correlation of both a holistic qualitative and a quasi-quantitative approach to analyzing the interviews. The holistic qualitative approach identified student behaviors in four broad categories: problem-solving, conceptual understanding, test-taking strategies, and use of scientific language. The quasi-quantitative analysis allowed us to focus on more specific behavioral trends within these categories providing a more detailed picture of what middle-achieving students do when solving algorithmic and conceptual problems. Middle-achieving students demonstrated more variability when solving conceptual questions as compared to algorithmic questions, applying a mixture of behaviors that were characteristic of higher-achieving and lower-achieving students. Implications for teaching based on this research include the need to help middle-achieving students become aware of the difference between their approaches to solving algorithmic versus conceptual questions, emphasizing what they do correctly and how they can improve their problem solving.
Acid−base titration concepts and experiments are ubiquitous, yet challenging, aspects of the general chemistry curriculum. Most general chemistry courses include at least one acid−base titration laboratory experiment, though the focus is often on determining the concentration, pK a , or molar mass of an analyte rather than on the details of interpreting a titration curve more broadly. This article describes the transformation of a single-period, traditional confirmation laboratory experiment into a multiweek, guided-inquiry capstone experience investigating a phosphate buffer system. The revision was designed to improve student understanding of the composition of a buffer system, the chemical reactions occurring as the buffer is titrated with a strong acid, and the rationale behind a method for determining the concentration of the buffer components. An experimental design component was incorporated in which groups of students formulated their own procedure to determine the concentration of the buffer components in an unknown sample. Preliminary evidence regarding the success of the implementation of this guided-inquiry experience was obtained through student work submitted for the titration and experimental design activities, student comments from the course evaluation and a self-reflection exercise, and midterm and final exam assessment questions.
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