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- Orraryd, Daniel, 1976-
(författare)
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Making science come alive : Student-generated stop-motion animations in science education
- 2021
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- The availability of digital technology in classrooms does not only increase the possibility for teachers to present content in new visual and dynamic ways. This technology also offers students the opportunity to become cocreators of content in science classrooms. The dissertation explores, mainly through qualitative methods, the potential of student generated stop-motion animations in science education research and practice. This exploration is motivated by the challenges learners experience when they are introduced to abstract dynamic science concepts spanning several organisational levels in space and time. In addition, it emphasises the importance of multiple representations for communicating and reasoning about such concepts. This novel approach is used, in combination with a conceptual characterisation of students’ written explanations, to expand the knowledge about students’ conceptions of evolution by natural selection. The potential of a stop-motion approach to stimulate meaning making of evolution biology and redox-chemistry classrooms is also explored. The thesis consists of four studies and a comprehensive summary with an extended analysis and discussion of the results.In relation to students’ written explanations about the mechanisms of evolution, the student generated stop-motion animations express the same pattern concerning key-concepts connected to evolution by natural selection. However, the analysis of misconceptions in the student-generated animations resulted in interesting differences from written explanations. The globally reported misconception of essentialism (the idea that all individuals of a species share a common essence, and that this essence is what is changed in evolution) was represented in only a low proportion of the animations. On the other hand, another misconception was expressed more often in the stop-motion animation than in written explanations, namely evolution as an event. These findings support the view that students’ expression of different misconceptions is influenced by the context and representational form.The work reveals that generating stop-motion animations to explain scientific concepts is an engaging approach that stimulates students to explore their understanding in a creative and personal manner. The analysis of the videorecorded animation process showed that one important realisation expressed in the student dialogue was that a representation is symbolic and cannot be a picture of reality, as it then would lose some of its explanatory value. The design of the task, the forms of feed-back during the work process, as well as the nature of the science content are important to consider before the approach of stop-motion animations is used in the classroom. Otherwise, the potential for meaningful learning may be lost and the activity becomes at best a lesson in creating an animation, albeit a fun and creative one.
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| 2. |
- Bohlin, Gustav, 1981-
(författare)
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Evolving germs – Antibiotic resistance and natural selection in education and public communication
- 2017
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Bacterial resistance to antibiotics threatens modern healthcare on a global scale. Several actors in society, including the general public, must become more involved if this development is to be countered. The conveyance of relevant information provided through education and media reports is therefore of high concern. Antibiotic resistance evolves through the mechanisms of natural selection; in this way, a sound understanding of these mechanisms underlies explanations of causes and the development of effective risk-reduction measures. In addition to natural selection functioning as an explanatory framework to antibiotic resistance, bacterial resistance as a context seems to possess a number of qualities that make it suitable for teaching natural selection – a subject that has been proven notoriously hard to teach and learn. A recently suggested approach for learning natural selection involves so-called threshold concepts, which encompass abstract and integrative ideas. The threshold concepts associated with natural selection include, among others, the notions of randomness as well as vast spatial and temporal scales. Illustrating complex relationships between concepts on different levels of organization is one, of several, areas where visualizations are efficient. Given the often-imperceptible nature of threshold concepts as well as the fact that natural selection processes occur on different organizational levels, visual accounts of natural selection have many potential benefits for learning.Against this background, the present dissertation explores information conveyed to the public regarding antibiotic resistance and natural selection, as well as investigates how these topics are presented together, by scrutinizing media including news reports, websites, educational textbooks and online videos. The principal method employed in the media studies was content analysis, which was complemented with various other analytical procedures. Moreover, a classroom study was performed, in which novice pupils worked with a series of animations explaining the evolution of antibiotic resistance. Data from individual written assignments, group questions and video-recorded discussions were collected and analyzed to empirically explore the potential of antibiotic resistance as a context for learning about evolution through natural selection.Among the findings are that certain information, that is crucial for the public to know, about antibiotic resistance was conveyed to a low extent through wide-reaching news reporting. Moreover, explanations based on natural selection were rarely included in accounts of antibiotic resistance in any of the examined media. Thus, it is highly likely that a large proportion of the population is never exposed to explanations for resistance development during education or through newspapers. Furthermore, the few examples that were encountered in newspapers or textbooks were hardly ever visualized, but presented only in textual form. With regard to videos purporting to explain natural selection, it was found that a majority lacked accounts of central key concepts. Additionally, explanations of how variation originates on the DNA-level were especially scarce. These and other findings coming from the content analyses are discussed through the lens of scientific literacy and could be used to inform and strengthen teaching and scientific curricula with regards to both antibiotic resistance and evolution. Furthermore, several factors of interest for using antibiotic resistance in the teaching of evolution were identified from the classroom study. These involve, among others, how learners’ perception of threshold concepts such as randomness and levels of organization in space and time are affected by the bacterial context
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