Chemical understanding and graphing skills in an honors case‐based computerized chemistry laboratory environment: The value of bidirectional visual and textual representations

Dori, Yehudit Judy; Sasson, Irit

doi:10.1002/tea.20197

Cited by 104 publications

(104 citation statements)

References 70 publications

(67 reference statements)

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“…Since the gain of the experimental group was double that of the control group, the potential for ''forgetting'' was higher, but, nonetheless, the retention of the experimental students remained significantly higher than their peers. This is in accordance with another study of high school honors studentsÕ retention that investigated a computerized chemistry laboratory environment which emphasized visualizations, teamwork, hands-on activities, and embedded assessment (Dori and Sasson, 2008). The present research also indicated that some TEAL students were able to transfer the knowledge and skills from the TEAL E&M course to advanced courses.…”

Section: Summary and Discussionsupporting

confidence: 91%

How Much Have They Retained? Making Unseen Concepts Seen in a Freshman Electromagnetism Course at MIT

et al. 2007

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The introductory freshmen electromagnetism course at MIT has been taught since 2000 using a studio physics format entitled TEAL-Technology Enabled Active Learning. TEAL has created a collaborative, hands-on environment where students carry out desktop experiments, submit web-based assignments, and have access to a host of visualizations and simulations. These learning tools help them visualize unseen electromagnetic concepts and develop stronger intuition about related phenomena. A previous study has shown that students who took the course in the TEAL format (the experimental group) gained significantly better conceptual understanding than those who took it in the traditional lecture-recitation format (the control group). The present longitudinal study focuses on the extent to which these two research groups (experimental and control) retain conceptual understanding about a year to 18 months after finishing the course. It also examines students attitudes about whether the teaching format (TEAL or traditional) contributes to their learning in advanced courses. Our research has indicated that the long-term effect of the TEAL course on studentsÕ retention of concepts was significantly stronger than that of the traditional course. This research is significant because it documents the long-term cognitive and affective impact of the TEAL studio physics format on learning outcomes of MIT students.KEY WORDS: conceptual understanding; electromagnetism; longitudinal study; retention; undergraduate physics education; visualization INTRODUCTIONStudies of how much conceptual understanding college students retain from their science courses are quite rare. Related studies include Barufaldi and Spiegel (1994), and Martenson et al. (1985). As Halpern and Hakel (2003) have discussed, educators need to provide students with education that lasts a lifetime. Thus, instructors need to adopt teaching and learning strategies for long-term retention in order for their students to remember what they have learned beyond the end of the semester.Beginning in 2000, the introductory freshmen electromagnetism course (E&M) at MIT has been taught using a new approach-Technology-Enabled Active Learning (TEAL). This study was reported by Dori and Belcher (2005a, b). The objective of the TEAL Project was to reform a mandatory largeenrollment physics class in order to increase studentsÕ conceptual understanding of electromagnetism and decrease failure rates in the course. The problems with passive learning in large classes were identified and researched over a decade ago (Hake, 1998;McDermott, 1991;Redish et al., 1997;Sokoloff and Thornton, 1997 stronger intuition about, and create more robust conceptual models of electromagnetic phenomena.In the previous study (Dori and Belcher, 2005a, b) we used pre-and post-tests which were administered to students taking the class in the TEAL format and to those taking the class in the traditional lecturerecitation format. We showed that students who took the course in the TEAL format gained significantly bett...

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Section: Summary and Discussionsupporting

confidence: 91%

How Much Have They Retained? Making Unseen Concepts Seen in a Freshman Electromagnetism Course at MIT

et al. 2007

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“…Other strategies used as the basis of the customization of computer-based scaffolding included setting scaffolding to reduce in strength according to fixed time intervals (fixed fading) (Dori & Sasson, 2008;McNeill, Lizotte, Krajcik, & Marx, 2006;Philpot, Hall, Hubing, & Flori, 2005) or when students click a button (selfselected fading) (Clark, Touchman, Martinez-Garza, Ramirez-Marin, & Skjerping Drews, 2012;Metcalf, 1999;Renkl, 2002). Customization based on fixed time intervals means that the scaffold designer determines time intervals after which scaffolding should be faded or added.…”

Section: Customization Basismentioning

confidence: 99%

Computer-Based Scaffolding Strategy

Belland

2016

Instructional Scaffolding in STEM Education

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This chapter covers variations in scaffolding strategies along the following characteristics-scaffolding function (e.g., strategic and conceptual), context specificity (i.e., generic or context-specific), customization (e.g., fading and fading/ adding), and customization schedule (e.g., self-selected and performance-based). These variations and the theoretical basis for these are explained. Then, results from the meta-analysis are shared, which indicate that there are no differences in cognitive outcomes according to scaffolding function, context specificity, and customization. These results are then discussed.

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“…In the light of all these, it can be said that even though the importance of laboratory applications in science education has long been acknowledged, recent years witnessed a surging interest in laboratory works and practical work. Literature has revealed that laboratory practices are useful in terms of students' both cognitive and affective development [6]. In terms of cognitive skills, laboratories are places where students learn the concepts, principles, and laws by exploring with experiments [7].…”

Section: Introductionmentioning

confidence: 99%

Pre-service Science Teachers' Views on Laboratory Applications in Science Education: The Effect of a Two-semester Course

Harman¹,

Çökelez²,

Dal³

et al. 2016

ujer

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The aim of this study was to examine pre-service science teachers' views about laboratory applications in science education and how their views changed through laboratory applications that were carried out for two semesters. 63 (52 females, 11 males) pre-service teachers participated in the study. The study was carried out by using pre-test and post-test design. Data was collected on the differences between the views of pre-service science teachers before and after laboratory courses. For data collection, teachers were given forms including 3 open-ended questions. Data analysis was carried out through qualitative content analysis. The results showed that pre-service teachers defined laboratory as "a place of application", and after laboratory applications, they could give more comprehensive definitions about laboratory. The most popular answers pertaining to the aim of laboratory applications included effective learning, permanent learning, ending rote learning, and better understanding, faster learning and learning with fun. Along with the quality of learning, participants attached importance to the methods and techniques to be utilized in lab setting to reach that desired quality. Their focus was predominantly on visualizing, experimental learning, materializing of the theoretical information through application and observation. Study showed that they mostly attributed the importance of laboratories to the quality of learning and methods were expressed as visualizing, materializing and application, observation and experiment for the quality of learning.

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Chemical understanding and graphing skills in an honors case‐based computerized chemistry laboratory environment: The value of bidirectional visual and textual representations

Cited by 104 publications

References 70 publications

How Much Have They Retained? Making Unseen Concepts Seen in a Freshman Electromagnetism Course at MIT

How Much Have They Retained? Making Unseen Concepts Seen in a Freshman Electromagnetism Course at MIT

Computer-Based Scaffolding Strategy

Pre-service Science Teachers' Views on Laboratory Applications in Science Education: The Effect of a Two-semester Course

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