Development and Assessment of Self-explaining Skills in College Chemistry Instruction

Villalta-Cerdas, Adrian

18 June 2014

The prevalent trend in chemistry instruction relies on what has been described as the classroom game. In this model, students take a passive role and the instructor does all the explaining (thinking), and learning is trivialized to knowing the correct answers (memorizing) and being able to produce them when prompted (regurgitating). The generation of explanations is central to scientific and technological development. In the process of figuring out explanations, the generation of inferences relies on the application of skills associated with scientific behaviors (e.g., analytical reasoning and critical thinking). The process of explanation generation causes a deeper analysis and revision of the scientific models, thus impacting the conceptual understanding of such models. Although the process of generating authentic explanations is closer to the experience of doing science, this process is seldom replicated in science instruction. Self-explaining refers to the generation of inferences about causal connections between objects and events. In science, this may be summarized as making sense of how and why actual or hypothetical phenomena take place. Research findings in educational psychology show that implementing activities that elicit self-explaining improves learning in general and specifically enhances authentic learning in the sciences. Research also suggests that self-explaining influences many aspects of cognition, including acquisition of problem-solving skills and conceptual understanding. Although the evidence that links self-explaining and learning is substantial, most of the research has been conducted in experimental settings. The purpose of this work was to advance knowledge in this area by investigating the effect of different self-explaining tasks on self-explaining behavior and the effect of engaging in different levels of self-explaining on learning chemistry concepts. Unlike most of the research in the field, this work did not focus on advancing procedural knowledge through self-explanation of examples or conceptual understanding through self-explanation of textual information and concepts. Instead, it focused on an experience closer to doing science by presenting a familiar phenomenon to the participants and a fact that would potentially induce cognitive imbalance to then prompt them to self-explain. This work used a multi-condition, mixed-method approach to categorize students' self-explaining behaviors in response to learning tasks and link it to the performance in a post-learning task. Students were randomly assigned to conditions that included the following: studying an experts' explanation, explaining correct and incorrect answers, explaining agreement with another's answer, and explaining one's own answer for others to use. Data were gathered in the classroom ecology of a university, large-enrollment general chemistry course. Content and construct validity evidence support the functionality of the research instruments for the assessment of conceptual understanding of entropy and the Second Law of Thermodynamics. An in-depth analysis of the post-learning task showed that the data collected from the instrument is reliable, consistent and reproducible. Findings supported an association between the self-explaining tasks and students' self-explaining behaviors. Results showed distinct categorical self-explaining behaviors in students' written responses. These self-explaining behaviors were associated with the self-explaining task given to the students. Thoughtful design of learning tasks can effectively elicit engagement in sophisticated self-explaining in natural, large-enrollment college chemistry classroom environments. Comparison analyses of performance in the post-learning task suggested that in the context of large-enrollment college chemistry classroom environments, self-explaining activities improved students' conceptual understanding in chemistry. Overall, the work showed that students can self-explain chemical phenomena and apply the underlying chemistry concepts in the resolution of novel problems without direct intervention of an instructor. This work supports the incorporation of self-explaining activities in the repertoire of teaching practices of both experienced and novice instructors for general chemistry courses.

Chemical Education

Higher Education

Science Education

Self-explaining Effect

Chemistry

Self-explaining and Individual Differences in Multimedia Learning

January 2014

abstract: Multimodal presentations have been found to facilitate learning, however, may be a disadvantage for low spatial ability students if they require spatial visualization. This disadvantage stems from their limited capacity to spatially visualize and retain information from both text and diagrams for integration. Similarly, working memory capacity (WMC) likely plays a key role in a learner's ability to retain information presented to them via both modalities. The present study investigated whether or not the act of self-explaining helps resolve deficits in learning caused by individual differences in spatial ability, working memory capacity, and prior knowledge when learning with text, or text and diagrams. No interactions were found, but prior knowledge consistently predicted performance on like posttests. The author presents methodological and theoretical explanations as to the null results of the present study. / Dissertation/Thesis / M.S. Applied Psychology 2014

Cognitive psychology

Experimental psychology

Psychology

diagrams

learning

Self-explaining

Spatial ability

text

working memory capacity

"Why we (do not) substitute meat" : Exploring how households with elementary school children explain their intentions and behaviour (gap) regarding meat substitute consumption.

Vreeburg, Danielle Elisabeth, de Regt, Roxanne Manuella

January 2021

Background: The consumption of meat in western societies keeps growing. This leads to a paradox, with a growing awareness in the society of health and environmental issues regarding meat consumption and a growing willingness to substitute meat more often.  Purpose: Explore the intentions of households with elementary school children to consume meat substitutes and to match these intentions with the actual behavior to find the extent of the intention-behavior gap and how they explain their intentions, behavior, and potential disconnect. Method: To understand the actual behavior of the households, two weeks' worth of grocery receipts were collected and analyzed. To explore intentions, additional semi-structured interviews were conducted, where the participants got the opportunity to explain their intentions, behavior, and gap.  Conclusion: The results show that there are three types of consumers, depending on the level of intention. The profiles differ whether they feel the need to explain their intention or the intention-behavior gap. To explain themselves,  All profiles state that meat is too delicious to leave out and that meat is a habit formed in childhood. Depending on the profile, additional reasoning was more internal or external.

Intention-behaviour gap

meat substitutes

meat consumption

self-explaining

qualitative

Economics and Business

Ekonomi och näringsliv

Business Administration

Företagsekonomi

SUPPORTING MATHEMATICAL EXPLANATION, JUSTIFICATION, AND ARGUMENTATION, THROUGH MULTIMEDIA: A QUANTITATIVE STUDY OF STUDENT PERFORMANCE

Stoyle, Keri L.

16 May 2016

No description available.

Educational Psychology

Educational Technology

Elementary Education

Middle School Education

Mathematics Education

self-explaining

mathematical practice standards

interactive and constructive learning

TPAK

cognitive and constructivist learning

student performance