The use of visual models such as pictures, diagrams and animations in science education is increasing. This is because of the complex nature associated with the concepts in the field. Students, especially entrant students, often report misconceptions and learning difficulties associated with various concepts especially those that exist at a microscopic level, such as DNA, the gene and meiosis as well as those that exist in relatively large time scales such as evolution. However the role of visual literacy in the construction of knowledge in science education has not been investigated much. This article explores the theoretical process of visualization answering the question “how can visual literacy be understood based on the theoretical cognitive process of visualization in order to inform the understanding, teaching and studying of visual literacy in science education?” Based on various theories on cognitive processes during learning for science and general education the author argues that the theoretical process of visualization consists of three stages, namely, Internalization of Visual Models, Conceptualization of Visual Models and Externalization of Visual Models. The application of this theoretical cognitive process of visualization and the stages of visualization in science education are discussed.
In the field of biochemistry, the use of external representations such as static diagrams and animations has increased rapidly in recent years. However, their effectiveness as instructional tools can be hindered if students lack the visual literacy and cognitive skills necessary for processing and interpreting such representations. We aimed to identify and assess visualisation skills necessary for effective processing of external representations in biochemistry. We used a modified Bloom’s taxonomy to identify the cognitive skills essential for optimal visual literacy, and designed probes based on those skills to develop a test instrument. Student responses to the probes were scored and processed with the Rasch model. This approach enabled us to rate the degree of difficulty of each visualisation skill on a linear logit scale, and to generate a person–item map to measure biochemistry students’ level of visual literacy. The results showed that the identified visualisation skills could be measured reliably, and the Rasch model was effective both for ranking the skills according to level of difficulty and for estimating a student’s relative level of visual literacy.
The use of visual models in teaching, learning and research has increased. Consequently, students have to develop various new competencies including visual literacy in order to learn efficiently. However, visual literacy among biochemistry students is not well documented. Using quantitative research methodology, the current research was aimed at determining visual literacy among biochemistry students. The participants were 74 purposefully selected third year undergraduate biochemistry students from the University of KwaZulu-Natal. The data were collected using a Senior Aptitude test and BioVisual Literacy test. The results show that students performed well in the sub-sections of the Senior Aptitude test including patterns test and spatial perception 2D test. They had difficulties with non-verbal reasoning with figures and spatial visualization 3D tests, as well as with the BioVisual Literacy tests. The results suggest that students generally have poor visual literacy, which could affect their ability to comprehend content knowledge in biochemistry. Keywords: biochemistry, biovisual literacy, senior aptitude, visual literacy, visuo-spatial abilities.
The significance of visuo-semiotic models in biology education has increased. Students have to develop visuo-semiotic skills, which could enable them to learn biology effectively. However, a lack of a universal theory of visual literacy has made it challenging to develop and assess visualization skills, including visuo-semiotic skills. The aim of the present research, therefore, was to develop an instrument for assessing visuo-semiotic reasoning in biology (VSR-b) in the context of amino acid structures. The research question guiding the
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