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Science & Education - 相似文献
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Puneet Gill 《American journal of sexuality education》2016,11(1):18-26
Science classrooms—and science textbooks—are proving to be challenging spaces for education that contradicts abstinence-only-until-marriage (AOUM) sex education. However, science educators can teach against this knowledge in a way that is critical of oppressive language. In fact, having explicit dialogue about gender identities and sexual orientation can help uncover oppressive cultural attitudes and help science educators challenge universal views of the human body. This article examines two narratives that use a pedagogic practice to help them teach in AOUM environments. The first narrative discusses personal experiences of the author as a science teacher and the dilemmas faced by including what I call a “sex box” in a life science class. The second narrative discusses an excerpt from a research study conducted with life science teachers in which a participant uses this same method. The purpose of this discussion is to help expose the science classroom as a place to have meaningful discussions, even with policies and cultures that do not support the discussion of safe sex for minority human sexualities.1 This article suggests future science teachers and present teachers alike can advocate for the incorporation of national standards that counteract overtly discriminatory policies. 相似文献
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《欧洲教育》2013,45(3-4):130-135
In the second May issue of the Deutsche Universitäts-Zeitung [German University Journal] there was an article entitled "Is There Still Any Demand for German?" by Doctor Maas, which deals rather thoroughly with the importance of the German language and generally gives a positive impression, even in the realm of science. I have taken Dr. Maas's article as an opportunity to present my own observations over the years on this topic. The changes I have observed are not positive. In my opinion, their effects are harmful over the long term. 相似文献
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This study investigated girls’ attitudes towards science in Kenya. It was carried out with 120 girls from four secondary schools in the Eastern province of Kenya. These were an urban single-sex (SS) and co-educational (Co-Ed) school and a rural SS and Co-Ed school. Different schools were chosen in order to explore whether there are any differences in attitudes in SS and Co-Ed schools and in schools in rural and urban areas. The methodology included the use of both questionnaires and focus group interviews. The main aim was to gain insight into the extent and depth of students’ attitudes towards science. The findings of the study showed that the majority of Kenyan girls who participated in the study have a favourable attitude towards science. Girls in SS schools were found to have a more favourable attitude than those in Co-Ed schools, while girls in rural area schools were found to find science more relevant than those in urban schools. It emerged from this study that the attitudes of Kenyan girls are influenced by their perceptions of the relevance of science, enjoyment of studying science, perceptions of the suitability of science for a career, and their perceptions of subject difficulty. 相似文献
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Jessica Thompson 《学习科学杂志》2013,22(3):392-446
What does it mean for ethnic minority girls, who have historically been marginalized by schools, to “see themselves” in science? Schools fail to create spaces for students to engage their identity resources in the learning of science or to negotiate and enact new science-related identities. This study investigates relationships among identity, engagement, and science discourse and provides a conceptual argument for how and why underserved ethnic minority girls engage in collective identity work, with science learning as a valued byproduct. The primary context for the study was Lunchtime Science, a 4-week lunchtime intervention for girls failing their science courses. There were 4 distinct ways the girls engaged in learning during Lunchtime Science: gleaning content for outside worlds, supporting the group, negotiating stories across worlds, and critiquing science. Each pattern had a signature profile with variations in the sociohistorical narratives used as resources, the positioning of one another as competent learners, and the type of science story critiqued and constructed. These findings indicate that when the girls were given opportunities to engage their personal narratives, and when science was open to critique, ethnic minority girls leveraged common historical narratives to build science narratives. Moreover, the girls’ identity work problematizes the commonplace instructional notion of “bridging” students’ everyday stories with science stories, which often privileges the science story and the composing of “science” identities. It also challenges researchers to investigate how the construction of narratives is broader than 1 community of practice, broader than 1 individual, and broader than 1 generation. 相似文献
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Summaries English In this short paper, the author looks back over the past few years at the experience gained in English schools of mixed‐ability teaching in science, and makes some personal interpretation of the lessons to be learned from that experience. It is hoped that some of these issues will be of relevance to other countries too. 相似文献
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Maarit Arvaja 《学习科学杂志》2015,24(1):137-175
This article reports on a qualitative study on the dialogical approach to learning in the context of higher education. The aim was to shed light on the I-Position and multivoicedness in students’ identity building and to provide empirical substantiation for these theoretical constructs, focusing especially on the connection between personal knowledge and theoretical knowledge. The study explored how health science students’ reflections on their work and discipline-related experiences provided resources for making personal sense of and understanding the subject studied. The students took an online course on the philosophy of science. To study students’ internal and external dialogue in terms of multivoicedness in their sense-making processes I combined a discourse analysis with a dialogical approach. The results showed that in reflecting on their experiences in light of different scientific approaches, the students became engaged in dialogues with different voices, thereby experiencing tensions in their professional positioning. The reasoning tasks gave rise to internal dialogue, involving negotiation between different I-Positions of the self or heterodialogue with the texts. These identity negotiations were manifested in refining, strengthening, and reconstructing professional and scientific I-Positions and in sharing and constructing a We-Position. 相似文献
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Science & Education - The obstacles and difficulties that science teachers face when teaching the nature of science (NOS) are well-known. Nonetheless, little is known of what science teacher... 相似文献
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This research focuses on use of a triadic teaching approach in a science–technology–society (STS) course designed for future
science teachers for middle schools in Turkey. Forty-three pre-service science teachers were enrolled in a semester-long course
organized around issues students identified and used throughout the semester. The triadic teaching approach includes library-online
searches that lead the students to design and conduct investigations, to carrying out mini-scientific symposia, and to preparing
and conducting poster presentations open to the entire student body and faculty. The results of a 30-item Likert scale, administered
to the students as a pretest and a posttest, indicated that there were significant increases in positive attitudes towards
STS issues from the beginning to the end of the study. Individual interviews were also conducted with the students to determine
the individual effects of each component of the triadic teaching approach on their attitudes towards STS issues. All aspects
of the new approach provided significant contributions to the development of more positive attitudes among the students towards
STS via interviews and on all sub-scales of a survey administered that include: (1) pupil interest in STS issues; (2) teacher
interest in STS issues; (3) general perceptions regarding importance of STS issues.
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| Osman Nafiz KayaEmail: |
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Paolo Manzelli 《International Journal of Science Education》2013,35(3):253-260
Summaries English Before constructing a new curriculum for any level in integrated‐science education, it is very important to establish a basic philosophy of science teaching which reflects a symbiotic relationship between education and the socio‐economic development in a particular country of the world. The curriculum structure of integrated‐science education should broaden the basis of curricular decision and should be designated to follow the expectations of the society in providing professional intellectual training so that education can make a significant contribution to the socio‐economic growth of the country. This basic assumption which established a link between cultural and socio‐economic growth, involves a diversification of the cultural trends of science education which must become appropriate to the economic and historical context of each country in a fast changing world of work. Therefore, by critically removing outside influences in the transmission of scientific knowledge, there should be less uniformity in the context and methods of teaching, and considerable restructuring of education for each country should occur. Thus, considering the historical and geographical differences, a new order in international division of labour would come into being. In such a hypothesis, a research‐oriented integrated curriculum in science education can play a central role (certainly a better one than in the traditional, discipline‐oriented scheme of science teaching) in obtaining an adequate interaction between scientific education and social problems; this is required for modern cultural and economic development of the world. 相似文献
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There is a current national emphasis on science, technology, engineering, and mathematics (STEM). Additionally, many states are transitioning to the Next Generation Science Standards (NGSS), which encourage teachers to incorporate engineering in science classrooms as well as have their students learn science by doing science. Methods courses are also shifting to adequately prepare preservice science teachers in these areas. This study examines preservice science teachers’ pre- and post-ideal inquiry-based lesson plan scenarios before and after intervention in their Secondary Science Methods I and II courses. These preservice science teachers participated in a variety of opportunities to practice authentic science inquiry (ASI) pedagogical techniques as well as integrated STEM topics, with a particular emphasis on computer programming throughout their 80 h of Methods instruction. ASI is a type of inquiry where students learn science by conducting science research in a grade-appropriate manner. Thirty-eight preservice teachers’ scenarios were analyzed using a rubric from Spuck (2014) to determine the degree to which the ten components of ASI were included in scenarios pre- to post-instruction. Trends in ASI component inclusion are discussed. These findings indicate that preservice science teachers are proficient at writing inquiry-based lessons where they planned opportunities for their future students to collaborate, use scientific instrumentation, and collect and analyze data, but need additional support with developing student activities where students create testable questions, revise their question and methods, participate in peer review, and disseminate their results to their peers or the larger scientific community. Overall, the results suggest Methods instruction should reinforce preservice teachers’ focus on planning lessons which include opportunities for all ASI components. Interventions in the aforementioned areas of weak inclusion may be beneficial to preservice teachers. 相似文献
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This preliminary ethnographic investigation focused on how Indigenous traditional wisdom can be incorporated into school science and what students learned as a result. Participants included community elders and knowledge keepers, as well as 4th grade (10-year-old) students, all of Amis ancestry, an Indigenous tribe in Taiwan. The students?? non-Indigenous teacher played a central role in developing a science module ??Measuring Time?? that combined Amis knowledge and Western science knowledge. The study identified two cultural worldview perspectives on time; for example, the place-based cyclical time held by the Amis, and the universal rectilinear time presupposed by scientists. Students?? pre-instructional fragmented concepts from both knowledge systems became more informed and refined through their engagement in ??Measuring Time??. Students?? increased interest and pride in their Amis culture were noted. 相似文献
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The present study deals with a school‐based professional development trajectory for secondary science teachers, aiming at scaffolding teachers in open‐inquiry teaching for the topic of water quality. Its design was based on the leading principle of ‘guiding by scaffolding’. Seven experienced teachers participated in institutional meetings and teaching at school. The research focused on designing scaffolding tools, addressing these tools in the meetings, and implementing them in the classroom. The main research data were obtained from meetings, classroom discussions, and observations. The results indicated that the professional development trajectory has promoted teachers’ learning of scaffolding students in open inquiry, especially the ability to know when and how to give students a well‐balanced combination of ‘structure’ for open‐inquiry learning and sufficient ‘space’ for that. The implications for science teacher education are discussed. 相似文献
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Alister Jones Cathy Buntting Rose Hipkins Anne McKim Lindsey Conner Kathy Saunders 《Research in Science Education》2012,42(4):687-708
Futures thinking involves a structured exploration into how society and its physical and cultural environment could be shaped in the future. In science education, an exploration of socio-scientific issues offers significant scope for including such futures thinking. Arguments for doing so include increasing student engagement, developing students?? values discourse, fostering students?? analytical and critical thinking skills, and empowering individuals and communities to envisage, value, and work towards alternative futures. This paper develops a conceptual framework to support teachers?? planning and students?? futures thinking in the context of socio-scientific issues. The key components of the framework include understanding the current situation, analysing relevant trends, identifying drivers, exploring possible and probable futures, and selecting preferable futures. Each component is explored at a personal, local, national, and global level. The framework was implemented and evaluated in three classrooms across Years 4?C12 (8 to 16-year olds) and findings suggest it has the potential to support teachers in designing engaging science programmes in which futures thinking skills can be developed. 相似文献
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Hope K. Gerde Steven J. Pierce Kyungsook Lee Laurie A. Van Egeren 《Early education and development》2018,29(1):70-90
Research Findings: Quality early science education is important for addressing the low science achievement, compared to international peers, of elementary students in the United States. Teachers’ beliefs about their skills in a content area, that is, their content self-efficacy is important because it has implications for teaching practice and child outcomes. However, little is known about how teachers’ self-efficacy for literacy, math and science compare and how domain-specific self-efficacy relates to teachers’ practice in the area of science. Analysis of survey and observation data from 67 Head Start classrooms across eight programs indicated that domain-specific self-efficacy was highest for literacy, significantly lower for science, and lowest for math. Classrooms varied, but in general, engaged in literacy far more than science, contained a modest amount of science materials, and their instructional support of science was low. Importantly, self-efficacy for science, but not literacy or math, related to teachers frequency of engaging children in science instruction. Teachers’ education and experience did not predict self-efficacy for science. Practice or Policy: To enhance the science opportunities provided in early childhood classrooms, pre-service and in-service education programs should provide teachers with content and practices for science rather than focusing exclusively on literacy. 相似文献
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The study explored the changes in pre-service science teachers’ understanding of the nature of science and their opinions about the nature of science, science teaching and argumentation after their participation in explicit nature of science (NOS) and socioscientific argumentation processes. The participants were 56 third-grade pre-service science teachers studying in a state university in Turkey. The treatment group comprised 27 participants, and there were 29 participants in the comparison group. The comparison group participants were involved in a student-centred science-teaching process, and the participants of the treatment group were involved in explicit NOS and socioscientific argumentation processes. In the study, which lasted a total of 11 weeks, a NOS-as-argumentation questionnaire was administered to all the participants to determine their understanding of NOS at the beginning and end of the data collection process, and six random participants of the treatment group participated in semi-structured interview questions in order to further understand their views regarding NOS, science teaching and argumentation. Qualitative and quantitative data analysis revealed that the explicit NOS and socioscientific argumentation processes had a significant effect on pre-service science teachers’ NOS understandings. Furthermore, NOS, argumentation and science teaching views of the participants in the treatment group showed a positive change. The results of this study are discussed in light of the related literature, and suggestions are made within the context of contribution to science-teaching literature, improvement of education quality and education of pre-service teachers. 相似文献
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Recent accounts by cognitive scientists of factors affecting cognition imply the need to reconsider current dominant conceptual theories about science learning. These new accounts emphasize the role of context, embodied practices, and narrative‐based representation rather than learners’ cognitive constructs. In this paper we analyse data from a longitudinal study of primary school children’s learning to outline a framework based on these contemporary accounts and to delineate key points of difference from conceptual change perspectives. The findings suggest this framework provides strong theoretical and practical insights into how children learn and the key role of representational negotiation in this learning. We argue that the nature and process of conceptual change can be re‐interpreted in terms of the development of students’ representational resources. 相似文献
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This essay considers the question of why we should teach science to K-2. After initial consideration of two traditional reasons for studying science, six assertions supporting the idea that even small children should be exposed to science are given. These are, in order: (1) Children naturally enjoy observing and thinking about nature. (2) Exposing students to science develops positive attitudes towards science. (3) Early exposure to scientific phenomena leads to better understanding of the scientific concepts studied later in a formal way. (4) The use of scientifically informed language at an early age influences the eventual development of scientific concepts. (5) Children can understand scientific concepts and reason scientifically. (6) Science is an efficient means for developing scientific thinking. Concrete illustrations of some of the ideas discussed in this essay, particularly, how language and prior knowledge may influence the development of scientific concepts, are then provided. The essay concludes by emphasizing that there is a window of opportunity that educators should exploit by presenting science as part of the curriculum in both kindergarten and the first years of primary school. 相似文献