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The roles of belief, evidence, perspective, and individual differences in scientific evaluationsBeatty, Erin Leigh 21 October 2009
Reasoners who adopt the perspective of another can increase the proportion of logically valid inferences they make (Thompson, Evans, & Handley, 2005). A possible explanation is that shifting perspective promotes analytic reasoning. If this were the case, then shifting perspectives should also reduce the belief-bias effect. Furthermore, strong evidence should be preferred over weak evidence. To test this, 256 participants read twenty-four research descriptions that varied in evidence quality and degree of personal belief content. Participants indicated whether the data supported the researchers hypotheses. Belief bias was reduced when participants evaluated the data from the researchers perspective relative to their own. Evidence strength was an important determining factor in decision-making and it was sensitive to perspective and individual differences.
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The roles of belief, evidence, perspective, and individual differences in scientific evaluationsBeatty, Erin Leigh 21 October 2009 (has links)
Reasoners who adopt the perspective of another can increase the proportion of logically valid inferences they make (Thompson, Evans, & Handley, 2005). A possible explanation is that shifting perspective promotes analytic reasoning. If this were the case, then shifting perspectives should also reduce the belief-bias effect. Furthermore, strong evidence should be preferred over weak evidence. To test this, 256 participants read twenty-four research descriptions that varied in evidence quality and degree of personal belief content. Participants indicated whether the data supported the researchers hypotheses. Belief bias was reduced when participants evaluated the data from the researchers perspective relative to their own. Evidence strength was an important determining factor in decision-making and it was sensitive to perspective and individual differences.
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Room for discussion? : Examining the role of discussions in students' work with socio-scientific issuesAreljung, Sofie January 2010 (has links)
In this thesis the students' experiences of science classroom discussions are examined as well as the nature of their discussions and their ability to take different perspectives while working with socio-scientific issues (SSI). Student questionnaires concerning their attitudes towards school science and science in society, a paper-and-pencil test and focus group discussions have been analysed. The results show that students get to discuss during science lessons, and that they learn a lot from doing so. They also show that the SSI work has brought about a lot of discussions, to which students have a positive attitude. When investigating students' written and oral demonstrationsfewexamplesof argument-based discussions or ofperspective-taking ability were found. Based on these results I argue that in-service teacher training should be carried out, focusing how to organise SSI discussions so that they support students' development of concepts and of generic skills.
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Identifying Student Difficulties in Causal Reasoning for College-aged Students in Introductory Physics Laboratory ClassesOwens, Lindsay 07 June 2018 (has links)
No description available.
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Investigation and Evaluation of Scientific Reasoning Development in the College Chemistry ClassroomCarmel, Justin H. 21 July 2015 (has links)
No description available.
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Student Reasoning from Data Tables: Data Interpretation in Light of Student Ability and Prior BeliefBogdan, Abigail Marie 22 September 2016 (has links)
No description available.
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Scientific reasoning skills development in the introductory biology courses for undergraduatesSchen, Melissa S. 30 August 2007 (has links)
No description available.
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Peer review in an undergraduate biology curriculum : effects on students' scientific reasoning, writing and attitudesTimmerman, Briana Eileen January 2008 (has links)
Scientific reasoning and writing skills are ubiquitous processes in science and therefore common goals of science curricula, particularly in higher education. Providing the individualized feedback necessary for the development of these skills is often costly in terms of faculty time, particularly in large science courses common at research universities. Past educational research literature suggests that the use of peer review may accelerate students' scientific reasoning skills without a concurrent demand on faculty time per student. Peer review contains many elements of effective pedagogy such as peer-peer collaboration, repeated practice at evaluation and critical thinking, formative feedback, multiple contrasting examples, and extensive writing. All of these pedagogies may contribute to improvement in students' scientific reasoning. The effect of peer review on scientific reasoning was assessed using three major data sources: student performance on written lab reports, student performance on an objective Scientific Reasoning Test (Lawson, 1978) and student perceptions of the process of peer review in scientific community as well as the classroom. In addition, the need to measure student performance across multiple science classes resulted in the development of a Universal Rubric for Laboratory Reports. The reliability of this instrument and its effect on the grading consistency of graduate teaching assistants were also tested. Further, application of the Universal Rubric to student laboratory reports across multiple biology classes revealed that the Rubric is further useful as a programmatic assessment tool. The Rubric highlighted curricular gaps and strengths as well as measuring student achievement over time. / This study demonstrated that even university freshman were effective and consistent peer reviewers and produced feedback that resulted in meaningful improvement in their science writing. Use of peer review accelerated the development of students' scientific reasoning abilities as measured both by laboratory reports (n = 142) and by the Scientific Reasoning Test (n = 389 biology majors) and this effect was stronger than the impact of several years of university coursework. The structure of the peer review process and the structure of the assignments used to generate the science laboratory reports had notable influence on student performance however. Improvements in laboratory reports were greatest when the peer review process emphasized the generation of concrete and evaluative written feedback and when assignments explicitly incorporated the rubric criteria. The rubric was found to be reliable in the hands of graduate student teaching assistants (using generalizability analysis, g = 0.85) regardless of biological course content (three biology courses, total n = 142 student papers). Reliability increased as the number of criteria incorporated into the assignment increased. Consistent use of Universal Rubric criteria in undergraduate courses taught by graduate teaching assistants produced laboratory report scores with reliability values similar to those reported for other published rubrics and well above the reliabilities reported for professional peer review. / Lastly, students were overwhelmingly positive about peer review (83% average positive response, n = 1,026) reporting that it improved their writing, editing, researching and critical thinking skills. Interestingly, students reported that the act of giving feedback was equally useful to receiving feedback. Students connected the use of peer review in the classroom to its role in the scientific community and characterized peer review as a valuable skill they wished to acquire in their development as scientists. Peer review is thus an effective pedagogical strategy for improving student scientific reasoning skills. Specific recommendations for classroom implementation and use of the Universal Rubric are provided. Use of laboratory reports for assessing student scientific reasoning and application of the Universal Rubric across multiple courses, especially for programmatic assessment, is also recommended.
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Identifying Student Difficulties in Conditional Probability within Statistical ReasoningFabby, Carol January 2021 (has links)
No description available.
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SCIENTIFIC REASONING:RESEARCH, DEVELOPMENT, AND ASSESSMENTHan, Jing 08 August 2013 (has links)
No description available.
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