Exploring the Design and Use of Molecular Animations that Conflict for Understanding Chemical Reactions

Kelly, Resa M.; Hansen, Sarah J. R.

doi:10.21577/0100-4042.20170043

Cited by 11 publications

(8 citation statements)

References 26 publications

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“…Attention has also been paid to various areas of chemical education research. Researchers studied, e.g., models, spectra reading, , or chemical reactions. ,, Research in these disciplines for example showed successful solvers (respectively experts) focus more on relevant information, ,, although there were some studies where the result was not proven. , This is possibly connected to their knowledge in this area . The results then translate to the time the students need to solve a task (faster than unsuccessful solvers , ).…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Students’ Procedure When Solving Problem Tasks Based on the Periodic Table: An Eye-Tracking Study

2021

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This work is focused on upper-secondary school students' ability to use the periodic table of elements to solve problem tasks. Eye-tracking and retrospective think-aloud methods were used to evaluate the reasoning behind the students' (N = 8) performance, i.e., to map the strategies they used and problems they faced when solving the tasks. The data from the eye-tracker were submitted to a quantitative analysis−time fixation duration evaluation on predefined areas of interest. The think-aloud method supporting the eye-tracking record together with the students' transitions also enabled a qualitative analysis of the students' procedure. Most of the students failed the tasks. The main reason was their lack of fundamental knowledge together with low reading and problem-solving skills, in addition to a lack of motivation to solve more demanding tasks. Their knowledge and ability to use the periodic table was proved insufficient to the corresponding curricular objective. The students mostly used expansive strategies, however, due to some problems (e.g., low prior knowledge, misunderstanding, or inattentive reading), they used limiting strategies (e.g., deducing from the task structure or guessing answers), and failed the tasks. These results offer a solid foundation for subsequent steps toward improving classroom practice, which stresses the need to focus on problem-solving and strategy development more during (chemistry) lessons. Also, the results call for extra support for the periodic table's teaching conception.

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Section: Theoretical Backgroundmentioning

confidence: 99%

Students’ Procedure When Solving Problem Tasks Based on the Periodic Table: An Eye-Tracking Study

2021

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“…Students can understand chemistry conceptually if they can translate chemical phenomena into macroscopic, submicroscopic, and symbolic representations (Helsy & Andriyani, 2017;Safitri, Nursa'adah, & Wijayanti, 2019). Submicroscopic visualization is very important, so students understand the concept of chemistry as a whole (Kelly & Hansen, 2017). One concept that requires submicroscopic visualization is hybridization.…”

Section: Introductionmentioning

confidence: 99%

Augmented Reality-based Media on Molecular Hybridization Concepts Learning

Irwansyah

Asyiah

Farida

2019

Tadris

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Students' problems in understanding of the hybridization process need to be overcome by using interactive media. Therefore, this study aimed to analyze the results of the validation test and the feasibility test of learning media based on Augmented Reality (AR) on the concept of hybridization. The research method used was the Design-based Research (DBR) method based on technology that supports the learning process within two stages, namely the analysis stage and the design and development stage. Data collecting instruments used were a validation test questionnaire and a limited trial sheet. The media was validated by 3 expert lecturers and 10 respondents of Chemical Education Department students at UIN Sunan Gunung Djati Bandung, Indonesia. Overall validation test results obtained an average value of robserved of 0.88. The validation test obtained a value above 0.30, which showed that the learning media was valid and can be used for the limited trial. The limited trial obtained an average value of 88.59 % within a feasible category. This research concluded that AR learning media on the concept of hybridization is appropriate to be used as teaching material in the learning.

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“…Current eye-tracking research often compares visual behavior over different stages of expertise. Numerous studies in various fields show that with increasing expertise less time is taken, more fixations are made on relevant aspects of the display to successfully solve a specific task, and overall more “focused” behavior is shown. − In the context of chemistry, several studies apply eye-tracking in cases of multiple representations, such as text-image combinations, animations, or comparisons of different representational forms. − As for expertise comparisons in chemistry education research, successful students are also faster with a task and spend more time on relevant features of a representation. − Consequently, unsuccessful students distribute their attention more equally over areas of interest (AOI) containing different forms of representations. , Further, Tang and Pienta found that students who are unsuccessful at solving a gas law problem have more fixations on the question text than on the graphs that provide the essential information . In a study by Cullipher and Sevian, where students were supposed to explain how molecular structures cause specific spectra, successful students show more transitions between the different representations .…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Decoding Case Comparisons in Organic Chemistry: Eye-Tracking Students’ Visual Behavior

et al. 2020

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Reaction mechanisms commonly used in organic chemistry are a great challenge for students in terms of understanding the representation and inferring the appropriate chemical concepts. In order to support the process of identifying and selecting chemical concepts, purposefully designed case comparisons are widely used. While these tasks place great demands on students' problem-solving capabilities, it is unknown how learners distribute their attention on the complex and information-rich representations. Understanding students' visual decoding behavior when dealing with case comparisons could provide valuable insights into supporting students' problemsolving process. In this exploratory study, we employed eye-tracking methodology to observe beginner and advanced undergraduate chemistry students when working through case-comparison tasks. By establishing a novel eye-tracking measure, the fixation/transition ratio, distinct viewing behaviors could be observed. Results indicate significant differences between both status groups. Advanced students are overall faster in their decision-making and transition more frequently between the representations, indicating a higher selectivity for chemically relevant entities. Further, the results show a significant impact of the visual complexity of a representation on students' visual behavior. Implications for designing case comparisons and supporting students' decoding process are discussed.

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Exploring the Design and Use of Molecular Animations that Conflict for Understanding Chemical Reactions

Cited by 11 publications

References 26 publications

Students’ Procedure When Solving Problem Tasks Based on the Periodic Table: An Eye-Tracking Study

Students’ Procedure When Solving Problem Tasks Based on the Periodic Table: An Eye-Tracking Study

Augmented Reality-based Media on Molecular Hybridization Concepts Learning

Decoding Case Comparisons in Organic Chemistry: Eye-Tracking Students’ Visual Behavior

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