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1.
Dr Richard Gunstone 《Research in Science Education》1994,24(1):129-136
Technology education and science education are seen to be related in a particular fashion by many science educators, a relationship
exemplified by the common pairing of the two areas in labels such as “Science-Technology-Society” and “Science and Technology
Curriculum”. At the heart of this common science education perspective is a view of technology education as dependent on and
subservient to science education. In this paper engineering, often seen by scientists as a form of applied science dependent
on and subservient to science, is considered. An analysis of the arguments that engineering, far from being an applied science,
is a unique way of knowing (that engineering has a unique epistemology) is used to consider the technology education view
of the relationships between science education and technology education. It is suggested that science educators need to rethink
their perceptions of this relationship if they are to understand the arguments of technology educators.
Specializations: science education, teacher education. 相似文献
2.
M. K. Summers 《International Journal of Science Education》2013,35(1):19-27
Summaries English The purpose of this article is to promote awareness of a growing body of literature concerned with the relationship between the epistemology of science and school science education, and to stimulate debate concerning the role such epistemological considerations should play in the professional training of science teachers. First of all, a rationale is provided for the inclusion of the epistemology of science and its relationship to school science education as an essential component on the professional training of all science teachers. This is followed by a review of existing resources for use in science teacher education curricula, and suggestions for new resource material. Finally, a possible curriculum for inclusion in science teacher education programmes is presented. 相似文献
3.
Jeffrey W. Bloom 《International Journal of Science Education》2013,35(4):401-415
The intent of the present study is to describe preservice elementary teachers’ understanding of science and how certain contextual variables contribute to this understanding. Eighty students in three sections of an elementary science methods course participated in the study by completing a questionnaire. Six questions dealt with knowledge of science, theories and evolution. In addition, a 21‐item rating scale covering various aspects of science and science teaching was included. The major theme arising out of the data is how beliefs affect preservice teachers’ understandings of science. The anthropocentricity in the subjects’ definitions and purposes of science, theories and evolution is the most explicit and pervasive of the beliefs influencing the conceptualizations of science. The often vague and misinformed definitions of theories add a further dimension of how science is perceived. When evolution is introduced, both the anthropocentric view of science and the misunderstood notion of theory come together to confound the subjects’ understanding. When asked about the teaching of evolution, the subjects’ confusion concerning the nature of science becomes strikingly evident. 相似文献
4.
Learning science interpreted in existing theoretical frameworks often means that students are assimilated, accommodated or enculturated from the entity of the vernacular world to the entity of the scientific world. However, there are some unsolved questions as to how students can best learn purely a new language or new knowledge of science. The purpose of this study is to conduct microanalysis of moment-to-moment interactions in order to understand how science language is taught and learned in details. Informed by Bakhtin’s dialogism, the analysis indicates that learning science is a process of appropriating authoritative discourse into internally persuasive discourse. Based on our analysis and findings, we propose the framework of discursive evolution to describe the process of teaching and learning the language of science. Four different stages of discursive evolution are identified to demonstrate the discursive changes during the course of science teaching and learning discourse: (a) using deictic references to connect scientific terminologies, (b) understanding science terminologies through its derivatives, (c) communicating science practices conventionally through science terminologies, and (d) communicating science practices innovatively through mutated science terminologies. The findings suggest that science teaching and learning comprise a heterogeneous process which draws on both science and non-science language and is a constantly evolving process. Understanding teaching and learning as a heterogeneous and constantly evolving process allows us to reunite the roles of teachers and students as mutually responsible collaborators rather than science knowledge givers and consumers. 相似文献
5.
刘景光 《福建教育学院学报》2011,(2):91-96
小学科学课程承担着培养小学生科学素质的重任,早期科学教育对每个人科学素质的形成具有十分重要的影响。然而在调研中发现,小学科学课程实施情况不尽人意:专职科学教师数量极其缺乏;科学课程开设严重不齐不足,兼职教师挪课现象相当严重;设施设备投入不足,科学专用教室和设备严重缺乏。这些问题严重影响小学科学教育正常开展。因此,必须提高对科学课程开设重要性认识,配备专职科学教师,保证开齐开好科学课程,促进学生创新意识和实践能力的提高。 相似文献
6.
Recent research in science and technology studies changed the way we understand science as it is practiced—that is, how scientific knowledge emerges from social, natural, social, political, cultural, historical, and economic contingencies of scientific work. Many science educators agree that students should learn not only science but also about science. In this article, we (a) outline important findings, research methods, and ways of reporting research that emerged from science and technology studies; and (b) show how familiarity with science and technology studies research can provide science educators with valuable insights about curriculum design and research on learning. We conclude that science and technology studies can serve as a resource to science education and that there is a potential for conducting collaborative work between science education and science and technology studies. Such collaborations have the potential to yield better theories about how people become competent in science from childhood to adulthood. © 1998 John Wiley & Sons, Inc. J Res Sci Teach 35: 213–235, 1998. 相似文献
7.
Allison J. Williams Judith H. Danovitch Candice M. Mills 《Mind, Brain, and Education》2021,15(1):67-76
Efforts have been made to promote children's interest in science, but little is known about how children's interest in science relates to other characteristics, such as science‐specific curiosity, domain‐general epistemic curiosity, and verbal intelligence. The current study examines how these factors relate to individual differences in children's self‐reported interest in science topics. Children 7‐ to 10‐years‐old (n = 91) rated their interest in science and non‐science topics and completed measures of science‐specific curiosity, domain‐general epistemic curiosity, and verbal intelligence. An additional 94 7‐ to 10‐year‐olds rated their interest in science and non‐science topics and completed the science‐specific curiosity measure. The results suggest that individual differences in children's science interest relate most strongly to scientific curiosity, and specifically to the drive to seek out information and new experiences. 相似文献
8.
This study considers the relationship between science, science teaching and the philosophy of science perceiving these three
cultural phenomena as a semantic triad. This approach presents science teaching as being a form of a scientific reflection.
The relationship of science teaching to the philosophy of science is advocated to be essential, revealing the conceptual meaning
of science in the science curriculum and thus removing the semantic degeneracy taking place when the philosophy of science
is ignored in science education. The study points at the bricolage as well as magic nature of the science curriculum preserving
as long as science teaching preserves semantic degeneracy. Different types of meaning of Schwab’s commonplaces were recognized.
The study challenges the common view of the relationship between science, science teaching and pedagogy and suggests effective
representation of individual knowledge of science educators. 相似文献
9.
Meghan Odsliv Bratkovich 《Science & Education》2018,27(7-8):769-782
The work of science is a linguistic act. However, like history and philosophy of science, language has frequently been isolated from science content due to factors such as school departmentalization and narrow definitions of what it means to teach, know, and do science. This conceptual article seeks to recognize and recognize—to understand and yet rethink—science content in light of the vision of science expected by academic standards. Achieving that vision requires new perspectives in science teaching and teacher education that look into the role that science language expectations play in science content. These perspectives reposition attention to language from a hidden, overlooked, or outsourced aspect of science teaching, to one at its core. To help bring teachers and teacher educators into this integrative view of science content, this article offers a mirror, a prism, and a lens as three metaphorical tools to explore the essential roles that language plays for, in, and as science content. The reflection, refraction, and refocusing of science content reveal complex science language expectations that function alongside facts, figures, and formulas of science as gatekeeping mechanisms that, once noticed, cannot be ignored or marginalized in science teaching and science teacher education. 相似文献
10.
Various science education researchers believe that science tuition should include some discussion about how science has developed over time. Therefore, deliberations about the nature of science should be integrated in the science curriculum. Many researchers argue that teaching the history of science is a good way to place the nature of science in science classes. This paper contributes to this debate and argues the importance of having young students study the birth of modern science. Such study could allow students to understand that some of the issues about the nature of science arose in the seventeenth century with the birth of modern science. To achieve this purpose, it is important to discuss the different factors that immersed the birth of modern science. To accomplish this goal, the novel The Name of the Rose by Umberto Eco may be used. Beyond introducing issues surrounding the nature of science, this strategy could help overcome the separation between the arts and humanities in education. 相似文献
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13.
This study investigated visitors’ and staff’s perceptions about the communication of science in a traditional natural history
museum. The research examined the science-related outcomes for adult visitors and explored visitors’ and staff’s ideas of
science and how it is portrayed at the museum. Data were collected by questionnaire and interview from 84 staff and 102 visitors.
Both groups held positive views about science, its importance and the need for everyone to understand it. Comparison of visitors’
pretest and posttest scores on the questionnaire revealed some significant changes, several suggesting a change to views about
science that were less “scientific.” Most visitors thought that their ideas about science had not changed as a result of their
visit, but they were positive about the museum as a place for learning science. Staff held more “scientific” views about the
nature of science than did visitors; they recognized the potential of the museum to educate people about science, but felt
it needed to be presented as more relevant and accessible, particularly in terms of science as a cultural practice. Neither
staff nor visitors perceived that the museum stimulated visitors to think critically about science. While acknowledging that
interpreting complex scientific knowledge into exhibits readily understood by lay visitors and displaying controversy are
difficult, these challenges must be addressed if visitors are to be encouraged to think about science and the social, cultural
and political contexts which shape it.
Léonie J. Rennie is professor of science and technology education and Dean, Graduate Studies at Curtin University of Technology in Australia.
Her research interests include adults' and children's learning in science and technology and the communication of science
in a range of out-of-school contexts. Currently, she is working on research projects relating to integrated curriculum in
science, mathematics and technology, and a statewide program to enhance scientific literacy in the community.
Gina F. Williams currently is a stay-at–home mother of two and pursuing a master’s degree in science communication from the Australian National
University. At the time of the research, she was working as a Research Associate with Léonie J. Rennie at Curtin University
of Technology in Australia. Gina was involved in a number of projects with a focus on the communication of science, in particular
research into the learning experiences of adults in free- choice learning environments. With a background in science, Gina
became interested in the issues involved in communicating science whilst working as an explainer at a science center. Her
research interests include the wider community’s engagement with science in their everyday lives, and the development of community-based
science projects. 相似文献
14.
Recent arguments in science education have proposed that school science should pay more attention to teaching the nature of science and its social practices. However, unlike the content of science, for which there is well‐established consensus, there would appear to be much less unanimity within the academic community about which “ideas‐about‐science” are essential elements that should be included in the contemporary school science curriculum. Hence, this study sought to determine empirically the extent of any consensus using a three stage Delphi questionnaire with 23 participants drawn from the communities of leading and acknowledged international experts of science educators; scientists; historians, philosophers, and sociologists of science; experts engaged in work to improve the public understanding of science; and expert science teachers. The outcome of the research was a set of nine themes encapsulating key ideas about the nature of science for which there was consensus and which were considered to be an essential component of school science curriculum. Together with extensive comments provided by the participants, these data give some measure of the existing level of agreement in the community engaged in science education and science communication about the salient features of a vulgarized account of the nature of science. Although some of the themes are already a feature of existing school science curricula, many others are not. The findings of this research, therefore, challenge (a) whether the picture of science represented in the school science curriculum is sufficiently comprehensive, and (b) whether there balance in the curriculum between teaching about the content of science and the nature of science is appropriate. © 2003 Wiley Periodicals, Inc. J Res Sci Teach 40: 692–720, 2003 相似文献
15.
In this essay, David Waddington and Noah Weeth Feinstein explore how Dewey's conception of science can help us rethink the way science is done in schools. The authors begin by contrasting a view of science that is implicitly accepted by many scientists and science educators — science as a search for truth — with Dewey's instrumentalist, technological, and nonrealist conception of science. After demonstrating that the search‐for‐truth conception is closely linked to some ongoing difficulties with science curricula that students find particularly alienating, they then analyze some of the educational opportunities that Dewey's vision opens up. Ultimately, Waddington and Weeth Feinstein argue that Dewey offers a humble and humanistic vision of science and science education practice that captures the power of science by connecting it clearly to everyday human activities and challenges. 相似文献
16.
Sedat Ucar 《Journal of Science Education and Technology》2012,21(2):255-266
Every aspect of teaching, including the instructional method, the course content, and the types of assessments, is influenced
by teachers’ attitudes and beliefs. Teacher education programs play an important role in the development of beliefs regarding
teaching and learning. The purpose of the study was to document pre-service teachers’ views on science, scientists, and science
teaching as well as the relations between these views and the offered courses over several years spent in an elementary science
teacher training program. The sample consisted of 145 pre-service elementary science teachers who were being trained to teach
general science to students in the 6th through 8th grades. The research design was a cross-sectional study. Three different
instruments were used to collect the data, namely, the “Draw a Scientist Test”, “Draw a Science Teacher Test”, and “Students’
Views about Science” tests. The elementary science teacher training program influenced pre-service science teachers’ views
about science, scientists and science teaching to different degrees. The most pronounced impact of the program was on views
about science teaching. Participants’ impressions of science teaching changed from teacher-centered views to student-centered
ones. In contrast, participants’ views about scientists and science did not change much. This result could be interpreted
as indicating that science teacher training programs do not change views about science and scientists but do change beliefs
regarding teaching science. 相似文献
17.
Özgecan Taştan Kırık 《Research in Science Education》2013,43(6):2497-2515
This study explores the science teaching efficacy beliefs of pr-service elementary teachers and the relationship between efficacy beliefs and multiple factors such as antecedent factors (participation in extracurricular activities and number of science and science teaching methods courses taken), conceptual understanding, classroom management beliefs and science teaching attitudes. Science education majors (n?=?71) and elementary education majors (n?=?262) were compared with respect to these variables. Finally, the predictors of two constructs of science teaching efficacy beliefs, personal science teaching efficacy (PSTE) and science teaching outcome expectancy (STOE), were examined by multiple linear regression analysis. According to the results, participation in extracurricular activities has a significant but low correlation with science concept knowledge, science teaching attitudes, PSTE and STOE. In addition, there is a small but significant correlation between science concept knowledge and outcome expectancy, which leads the idea that preservice elementary teachers’ conceptual understanding in science contributes to their science teaching self-efficacy. This study reveals a moderate correlation between science teaching attitudes and STOE and a high correlation between science teaching attitudes and PSTE. Additionally, although the correlation coefficient is low, the number of methodology courses was found to be one of the correlates of science teaching attitudes. Furthermore, students of both majors generally had positive self-efficacy beliefs on both the STOE and PSTE. Specifically, science education majors had higher science teaching self-efficacy than elementary education majors. Regression results showed that science teaching attitude is the major factor in predicting both PSTE and STOE for both groups. 相似文献
18.
评费耶阿本德的多元方法论——析《反对方法》 总被引:1,自引:0,他引:1
王元明 《天津师范大学学报(社会科学版)》2001,(6):18-23
当代美国科学哲学家费耶阿本德在《反对方法》一书中提出了多元方法论,指出:科学在本质上是无政府主义的事业,科学方法是多元的;理论多元论有利于科学发展,理论一元论是没有道德的。费耶阿本德强调分析特殊性、强调理论增生包含一定的积极内容,但他否定普遍性,把迷信与科学等量齐观,贬低科学的作用则是错误的和有害的。 相似文献
19.
The purpose of this study was to examine the relationships among science content knowledge, understanding the Learning Cycle,
and self-efficacy among preservice teachers. Preservice teachers enrolled in an elementary science-methods course were categorized
as Fearful, Disinterested, Successful, or Enthusiastic science learners based on differing background characteristics in the
variables of science interest, performance in science courses methods courses. Analysis revealed that the four categories
increased differentially in their science content knowledge, understanding of the Learning Cycle, science teaching self-efficacy,
and confidence to learn science. Fearful science learners demonstrated less increases in science content knowledge and understanding
of the Learning Cycle than the other three categories. Disinterested science learners demonstrated fewer gains in science
content knowledge than Enthusiastic science learners. Fearful science learners were less confident to learn science than other
categories.
Electronic supplementary material The online version of this article (doi:) contains supplementary material that is available to authorized users.
An erratum to this article can be found at 相似文献
20.
This paper reports on the development stages of three attitudes to science and school scales for use with children aged from 5-11 years. The investigation is part of a project intended to improve pupil achievement in science in 16 schools in an English city. The base-line performance of the attitude scales with over 800 pupils is reported. Attitude sub-scales measure 'liking school', 'independent investigator', 'science enthusiasm', the 'social context' of science, and 'science as a difficult subject' with Cronbach Alpha reliabilities for the year groups varying from above 0.8 to below 0.7. For the sample, both boys' and girls' enthusiasm for science declines progressively with age alongside a similar decline in their perception that science is difficult. 相似文献