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1.
In this paper we continue our search for a socially responsible science education by an examination of the trends in the Science,
Technology and Society movement. These trends reflect differing ideological perspectives and result in courses which serve
different ends. We identify two major flaws in the movement that inhibits the realization of a schooling in science dedicated
to democracy. We propose skills necessary for citizens to participate in debate over issues surrounding the impact of science
and technology on society and a teaching stategy to help develop them.
Specializations: social responsibility and the curriculum, ideology and comparative science education. 相似文献
2.
FOSS、STC、INSIGHTS是在20世纪80年代末美国新一轮科学课程改革的背景下,在"2061计划"的推动下启动的三项科学课程研究项目,也是当下美国较为流行的三套小学科学课程教材。本文对三套教材的出台背景作简要介绍,并通过对三套教材的课程内容、教学资源、特点等进行对比,透视美国科学教育的特点及整体发展趋势。 相似文献
3.
This paper examines the ideology of one the best known figures in science education in the USA, and draws attention to the
relationship between the political climate and curriculum in national curriculum developments. We are mindful of the forces
shaping the schooling of science in Australia, and we present this analysis as an example of the social forces that dominate
education both here and overseas. Paramount is our desire to open the door for a socially responsible Australian school science
experience.
Social Responsibility of Science in Science Education Group.Specializations: sociology of science education, the nature of science and the production of scientific knowledge, comparative science education
and environmental education.
Social Responsibility of Science in Science Education Group.Specializations: comparative education with particular reference to China, the nature of science and the production of scientific knowledge. 相似文献
4.
Yeung Chung Lee 《Cultural Studies of Science Education》2018,13(2):485-515
This paper draws together two important agendas in science education. The first is making science education more inclusive such that students from non-Western or indigenous cultures can benefit from culturally relevant curricula. The second is integrating technology into the curriculum under the umbrella of Science–Technology–Society (STS) education to embrace the social aspects of science, with technology serving as a bridge. The advancement of the first agenda is hindered by the pursuance by both Western and non-Western societies of narrow cultural and practical goals without considering the development of science and technology from a cross-cultural perspective. The second agenda is limited by the misconception that technology is applied science, leading to the exclusion from STS discussions of pre-science or indigenous technologies developed by non-Western cultures. Through selected case studies of the evolution of Chinese traditional technologies and their interaction with science, this paper offers a perspective from the Far East, and argues for situating culturally responsive science education in broader historical and cross-cultural contexts to acknowledge the multi-cultural contributions to science and technology. A form of cross-cultural STS education is advanced, encompassing the cultural basis of technological developments, technology diffusion, interactions of traditional technology with science, and the potential development of traditional or indigenous technologies. This approach provides a bridge between the existing universal science education paradigm promoted in the West and the different forms of multi-cultural education advocated by indigenous science educators. To translate theory into practice, a conceptual framework is proposed in which the essential transdisciplinary knowledge base, curricular goals, and pedagogical approaches are embedded. 相似文献
5.
Adopting an explicit and reflective approach to the teaching of the history and philosophy of science is useful in promoting high school students’ understanding of the nature of science. Whereas the history of science is usually signposted clearly in the school science curriculum, the philosophy of science is considered to be embedded in and integral to science education. This article argues that philosophical topics also need to be explicitly signposted and discussed in the teaching of the nature of science in high schools. This study investigates an interdisciplinary course on the nature of science in a Chinese senior high school. The course involved explicit teaching of philosophy of science topics with subject knowledge in each lesson. This mixed method design of the research included a modified version of the Views on Science, Technology and Society questionnaire as reported by Aikenhead and Ryan (Science Education, 76(5):477?491, 1992) and phenomenographical analysis. Although the sample size is small, the results suggest that explicit teaching of philosophy of science topics helps students better understand both the nature of science and the relationship between science, technology and society.
相似文献6.
Nasser Mansour 《Journal of Science Teacher Education》2010,21(5):513-534
The failure of much curriculum innovation has been attributed to the neglect by innovators of teachers’ perceptions. The purpose
of this study was to investigate inservice science teachers views of integrating Science, Technology and Society (STS) issues
into the science curriculum and identify the factors that influence their decisions concerning integrating STS issues (or
not). The study used mixed methods (questionnaire and interviews) with Egyptian science teachers who teach science courses
for 12- to 14-year-old students. The findings indicate that unless curriculum developers take account of teachers’ beliefs
and knowledge and the sociocultural factors that shape or influence those beliefs in designing and planning new STS curriculum
materials, these materials are unlikely to be implemented according to their intended plan. 相似文献
7.
应循科学技术和科学教育发展而诞生的STSE教学,几十年来在课程形式和功能上的演变经历了三个阶段,完善了其教学地位,并在新世纪基础教育课程与教学改革中发挥着新的功能。论文试图以理科化学课程为例,阐明不同的STSE的课程作用与演进形式,并从实现理科课程教学三维目标的角度论述了STSE的教学作用。 相似文献
8.
The need for the inclusion of socio‐scientific issues (SSI) into science curricula has been generally accepted, but relatively few science teachers have incorporated SSI into their courses. Most science teachers feel that their most important task by far is to teach the principles of science, and any substantive pedagogical changes represent a burden. Reformers and researchers often point out science teachers' lukewarm reactions to the reforms as a major barrier for educational changes but pay little attention to teachers' deeper values and inspirations. However, there are some teachers who address SSI out of their own personal initiative. Detailed case studies of four such teachers showed that although the teachers were aware of Science, Technology, Society or other reform efforts, they developed their own thrust and materials for SSI based on their own values, ideals, philosophies and personal concerns. This suggests that the current curriculum reforms (Science, Technology, Society, SSI, and Nature of Science) tend to suggest theoretical ideals, but do not effectively connect with teachers' deeper values and ideals. 相似文献
9.
10.
Bugrahan Yalvac Ceren Tekkaya Jale Cakiroglu Elvan Kahyaoglu 《International Journal of Science Education》2013,35(3):331-348
The international science education community recognises the role of pre‐service science teachers’ views about the interdependence of Science, Technology, and Society (STS) in achieving scientific literacy for all. To this end, pre‐service science teachers’ STS views signal the strengths and the weaknesses of science education reform movements. Turkey, a country that follows the international reform movement, aims at improving citizen’s understanding of the STS interdependence to enable them to fully participate in an industrialised, democratic society. This study explores the Turkish pre‐service science teachers’ views (n = 176) on STS issues and discusses the ongoing reform efforts’ strengths and weaknesses within the context of the study findings. Data were collected through an adopted “Views on Science–Technology–Society” instrument. Analysis revealed that many participants held realistic views on science, technology, and society interdependence, while their views on technology and the nature of science were differed. Some viewed technology as an application of science, and some viewed science as explanatory and an interpretation of nature. Most agreed that the scientific knowledge is tentative but they did not present a thorough understanding of the differences between hypotheses, laws, and theories. 相似文献
11.
M. B. Ogunniyi 《International Journal of Science Education》2013,35(10):1189-1207
In response to the needs of a newly democratic South Africa, a new education policy required science teachers to integrate Indigenous Knowledge Systems (IKS) with school science: Curriculum 2005 (C2005) was developed. The first phase of that curriculum was implemented in 1997 with the hope that by 2005 it would have been implemented in the entire school system (i.e., R–12 grades). Since then science educators have been making a concerted effort to develop science teacher education programmes compatible with the postulates of the new curriculum policy. As part of that effort, this study used a Practical Argumentation Course to equip a group of science teachers with knowledge and instructional skills needed to implement an integrated Science‐IKS curriculum in their classrooms. The findings showed that, as a result of the course, the teachers’ understanding of, and awareness about, the Nature of Science and IKS improved considerably. Similarly, the teachers made noticeable perceptual shifts from construing science and IKS as polar opposites to considering the two thought systems as compatible and complementary. The implications of the findings for instructional practices are highlighted in the paper. 相似文献
12.
Wanja Gitari 《科学教学研究杂志》2006,43(2):172-193
The role of science education in rural development is of great interest to science educators. In this study I investigated how residents of rural Kirumi, Kenya, approach health and healing, through discussions and semistructured and in‐depth interviews with 150 residents, 3 local herbalists, and 2 medical researchers over a period of 6 months. I constructed objects of learning by looking for similarities and differences within interpretive themes. Objects of learning found comprise four types of personal learning tools, three types of relational learning tools, three genres of moral obligation, and five genres of knowledge guarding. Findings show that rural people use (among other learning tools) inner sensing to engage thought processes that lead to health and healing knowledge. The sociocultural context is also an important component in learning. Inner sensing and residents' sociocultural context are not presently emphasized in Kenyan science teaching. I discuss the potential use of rural objects of learning in school science, with specific reference to a health topic in the Kenyan science curriculum. In addition, the findings add to the literature in the Science, Technology, Society, and Environment (STSE) approach to science education, and cross‐cultural and global science education. © 2005 Wiley Periodicals, Inc. J Res Sci Teach 43: 172–193, 2006 相似文献
13.
Aaron S. Blicblau 《Journal of Science Education and Technology》1997,6(3):231-240
The teaching of science and technology in the final year of high school is examined in a new curriculum developed for the education system in Victoria, Australia. The traditional areas of Physics and Chemistry together with a technology related subject, Materials and Technology, are investigated The major curriculum link amongst these studies was the area of materials. In Chemistry this involved the nature of materials, the chemical basis for the production of metals and polymers, and the social consequences of waste disposal. Within Physics, the major involvement was the investigation of the structure and physical properties of materials through theory and practical investigation. The selection of materials, production of components and their testing were the major area involved with Materials and Technology. Although the area of materials related all three subjects enrollments were comparatively high for Physics and Chemistry but Materials and Technology had less than one tenth as much enrollment. Similarly, school providers were significantly lower for materials and technology. Materials and Technology is still considered a vocational subject compared with the science oriented subjects. When gender enrollments were considered, Chemistry had a similar number of females and males, Physics had twice as many males as females, and Materials and Technology had twice as many males as females. This appears to be a consequence of typical gender roles. 相似文献
14.
The transfer of matter and energy from one organism to another and between organisms and their physical setting is a fundamental concept in life science. Not surprisingly, this concept is common to the Benchmarks for Science Literacy (American Association for the Advancement of Science, 1993 ), the National Science Education Standards (National Research Council, 1996 ), and most state frameworks and likely to appear in any middle‐school science curriculum material. Nonetheless, while topics such as photosynthesis and cellular respiration have been taught for many years, research on student learning indicates that students have difficulties learning these ideas. In this study, nine middle‐school curriculum materials—both widely used and newly developed—were examined in detail for their support of student learning ideas concerning matter and energy transformations in ecosystems specified in the national standards documents. The analysis procedure used in this study was previously developed and field tested by Project 2061 of the AAAS on a variety of curriculum materials. According to our findings, currently available curriculum materials provide little support for the attainment of the key ideas chosen for this study. In general, these materials do not take into account students' prior knowledge, lack representations to clarify abstract ideas, and are deficient in phenomena that can be explained by the key ideas and hence can make them plausible. This article concludes with a discussion of the implications of this study to curriculum development, teaching, and science education research based on shortcomings in today's curricula. © 2004 Wiley Periodicals, Inc. J Res Sci Teach 41: 538–568, 2004 相似文献
15.
Nathaniel A. Omilani S. Akin Akinyele Tunde S. Durowoju Ebenezer Ifeoluw Obideyi 《Education 3-13》2019,47(6):760-772
Basic Science and Technology is a subject that is based on the broad field curriculum which is the foundation for science education in Nigeria at the basic level of education. Pupils learning outcomes is usually limited to the assessment of their achievement in paper pencil test. Pupils’ skills in carrying out scientific investigation and the investigation they carry out is usually not assessed neither is the score part of pupils score in Basic Science and Technology. In this paper, we determined the effect of the integration of assessment of science practicals on basic four pupils’ achievement and problem solving in Basic Science and Technology (basic science, basic technology, and information and communication technology). Participant 303 basic four pupils (primary four) in Odeda local government of Ogun. The result indicated that pupils in the treatment group were better problem solvers in two out of the three themes in Basic Science and Technology (basic science and basic technology). Also pupils in the treatment group had a significantly higher achievement in information and communication technology theme of Basic Science and Technology. 相似文献
16.
Julie Stanfel 《Educational Media International》2013,50(3):172-180
Abstract The National Film Board of Canada is breaking new ground in educational technology with a pilot series of ‘interactive’ videos entitled Perspectives in Science. The series, aimed at the junior high school level, addresses issues of environmental and sociological concern not traditionally dealt with in formal science curricula. This paper examines the rationale behind the development of the Perspectives in Science video series. Science curriculum guidelines across Canada are being re‐written to reflect a change in education strategies that will encompass not only the teaching of scientific concepts, but also the applications of those concepts, as well as the implications of utilizing those concepts. Referred to as the ‘S‐T‐S’ connection, or, Science‐Technology‐Society, the new focus has been extensively documented by the Science Council of Canada and is currently causing a stir in the science teaching community as teachers scramble to find audio‐visual productions that address these new concerns and, at the same time, engage their students. This paper also explains the design concept for presenting materials on S‐T‐S in an interactive model. Each video includes a short, open‐ended drama, followed by a number of ‘interactive components’. The tapes are ‘interactive’ in that teachers and students can choose to follow the material linearly or search for specific segments using the running time code as an electronic page reference. The interactive components consist of documentary style discussions with Canadians involved in some aspect of the scientific, technological, and societal issues presented, animated sequences, experiments, and filmography. The videos investigate issues of water, biotechnology, and toxic waste—with additional topics on soil, forestry, and air in production. Finally, this paper documents the formative evaluation of the series noting the favourable response of teachers and students to the design concept and material content. The findings of this research indicated that the interactive video was both timely and appropriate for science teaching in view of major changes now being made to science curricula. 相似文献
17.
18.
Dr Michael R. Matthews 《Research in Science Education》1990,20(1):220-229
The history and philosophy of science components of the new British National Curriculum, and the American Association for
the Advancement of Science Project 2061 curriculum guidelines are described. Some curriculum background is given to these
developments; and a contemporary international project concerned with the utilization of the history and philosophy of science
in science teaching and teacher education is also described. Finally the recent Discipline Review of the Training of Science
and Mathematics Teachers in Australia is examined and criticised for its lack of recommendations about the need for appropriate
history and philosophy of science courses to be included in science teacher education programmes.
Specializations: history and philosophy of science, philosophy of education. 相似文献
19.
M. Teresa Ibáñez‐Orcajo 《International Journal of Science Education》2013,35(6):747-769
Numerous investigations show that most school science teaching, in Spain and elsewhere, implicitly transmits an inductivist and very stereotyped view of science and conveys an unrealistic image of scientific work. We present some results of an investigation with fourth‐level Spanish secondary education students (15 year olds) who were taught genetics through a unit based on an open problem‐solving methodology as an investigation. Among the learning objectives were the modification of their view of the nature of science in relation to ideas about: how science is done, what a theory is, what scientists do, and, finally, what the relationship is between Science–Technology–Society. The conceptual change about the nature of science experienced by the students in the experimental group was not observed in the control group, which worked in a traditional manner. Also, these new concepts remained with the students over time without a significant backward shift. 相似文献
20.
Porter E. Coggins III 《学校用计算机》2013,30(3):282-293
The purpose of this aricle is to present several implications and recommendations regarding what elementary school children, aged 9–12 years, know about computer passwords and what they know about why computer passwords are important. Student knowledge can then be used to make relevant curriculum decisions based in conjunction with applicable state and national standards. Weak computer password construction, use, and knowledge have been identified as areas of high risk for data security. By identifying what children know about passwords, an appropriate curriculum can be designed to help children develop strong password habits that will minimize unauthorized data access via computer technology. This is especially important because elementary school children today will become industry computer users tomorrow. By instilling appropriate computer password habits in children today, curriculum can be designed to follow them through the education experience and into industry. Relevant standards from the International Society for Technology in Education (ISTE), ISTE National Educational Technology Standards for Students (NETS?S), and the Association for Computing Machinery's Computer Science Teachers Association K–12 (CSTA K–12) are referenced. 相似文献