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1.
This is an editorial report on the outcomes of an international conference sponsored by a grant from the National Science Foundation (NSF) (REESE-1205273) to the School of Education at Boston University and the Center for Philosophy and History of Science at Boston University for a conference titled: How Can the History and Philosophy of Science Contribute to Contemporary US Science Teaching? The presentations of the conference speakers and the reports of the working groups are reviewed. Multiple themes emerged for K-16 education from the perspective of the history and philosophy of science. Key ones were that: students need to understand that central to science is argumentation, criticism, and analysis; students should be educated to appreciate science as part of our culture; students should be educated to be science literate; what is meant by the nature of science as discussed in much of the science education literature must be broadened to accommodate a science literacy that includes preparation for socioscientific issues; teaching for science literacy requires the development of new assessment tools; and, it is difficult to change what science teachers do in their classrooms. The principal conclusions drawn by the editors are that: to prepare students to be citizens in a participatory democracy, science education must be embedded in a liberal arts education; science teachers alone cannot be expected to prepare students to be scientifically literate; and, to educate students for scientific literacy will require a new curriculum that is coordinated across the humanities, history/social studies, and science classrooms. 相似文献
2.
Yuanlin Guo 《Science & Education》2014,23(9):1835-1844
In China, the philosophy of science and technology (PST) is derived from “Dialectics of Nature” (DN), which is based on Engels’ unfinished book Dialektik der Natur. DN as a political ideology provides political guidance for scientists and engineers. Therefore, since 1981, “Introduction to Dialectics of Nature” (IDN) has been an obligatory course for master’s degree students who study natural science or technology. In 1987, DN was renamed PST by the Chinese government in order to communicate and do research. The IDN teachers constitute most of the scholars who research PST. Nowadays, in China, PST includes philosophy of nature, philosophy of science, philosophy of technology, sociology of science, sociology of technology, “science, technology and society,” history of science, history of technology, management of science, and management of technology due to having too many IDN teachers. In fact, it is neither a branch of philosophy, nor a subject. The number of the IDN teachers has been increasing since 1981, which makes PST a miscellaneous collection of many branches or subjects. Finally, PST is facing two new challenges: the reduction of IDN and academic corruption. 相似文献
3.
The unique contributions of romanticism and romantic science have been generally ignored or undervalued in history and philosophy of science studies and science education. Although more recent research in history of science has come to delineate the value of both topics for the development of modern science, their merit for the educational field has not been explored. Romanticism was not only an obvious historical period, but a particular state of mind with its own extraordinary emotional sensitivity towards nature. It is especially the latter which we hope to revisit and reclaim for science education. After discussing several key historical contributions, we describe nine characteristics of ‘Romantic Science’ in order to focus on six ideas/possibilities that we believe hold much value for transforming current science education: (1) the emotional sensitivity toward nature, (2) the centrality of sense experience, (3) the importance of “holistic experience”, (4) the importance of the notions of mystery and wonder, (5) the power of science to transform people’s outlook on the natural world, and (6) the importance of the relationship between science and philosophy. It is argued that in view of a pragmatist/utilitarian conception of school science prevalent today the aforementioned ideas (especially the notion of wonder and the poetic/non-analytical mode of knowledge), can provide food for thought for both science teachers and researchers seeking to work out an aesthetic conception, one that complements current approaches such as inquiry science and conceptual change. 相似文献
4.
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5.
The inclusion of the practice of “developing and using models” in the Framework for K-12 Science Education and in the Next Generation Science Standards provides an opportunity for educators to examine the role this practice plays in science and how it can be leveraged in a science classroom. Drawing on conceptions of models in the philosophy of science, we bring forward an agent-based account of models and discuss the implications of this view for enacting modeling in science classrooms. Models, according to this account, can only be understood with respect to the aims and intentions of a cognitive agent (models for), not solely in terms of how they represent phenomena in the world (models of). We present this contrast as a heuristic—models of versus models for—that can be used to help educators notice and interpret how models are positioned in standards, curriculum, and classrooms. 相似文献
6.
This article examines the relationship between epistemic cognition and classroom argumentation practices in elementary science and history. Literature highlights argumentation as a critical epistemic practice for science and history learning (Duschl & J. Osborne, 2002; National Research Council, 2007, 2012). Although there is ample support for argumentation in the teaching of history and science, the specific epistemic issues that students address through this practice are not always empirically documented. We draw on the work of Chinn, Buckland, and Samarapungavan (2011) to examine argumentation practices in science and history in 2 fifth-grade and 2 sixth-grade urban classrooms. Students' and teachers' emergent argumentation practices were coded and analyzed and epistemic reasoning was examined using the 5 components of the Chinn et al. model. Findings highlight that students engaged in complex argumentation practices that were consistent across classrooms. The classroom case examples demonstrate that students addressed all 5 epistemic components in the Chinn et al. model through their argumentation practice. Further research to better understand the relationship between teacher epistemic commitments, pedagogical practices, and student epistemic commitments and learning is suggested. 相似文献
7.
James S. Kaminsky 《Educational studies》1991,17(3):217-232
It would be convenient to pretend that the histories of educational philosophy in Britain and, by extension, the USA and Australia, were responses to a common social and intellectual history but convenience in this case could only be accomplished at the expense of explanatory power. The history of educational philosophy in these three places is parallel but not in common. Philosophy of education in Britain is more closely related to philosophy than is philosophy of education in the USA. Philosophy of education in the USA appropriated the lead of the American Social Science Association and initially retained closer connections with social science than did its English counterpart. Nevertheless, it is argued here that educational philosophy's reference to social science—Victorian and modern—is the missing explanatory element in modem histories of the discipline. The appropriation of education by social science—a common feature of the intellectual history of education in Britain, Australasia, and the USA—leavened the research agenda of educational philosophy in Britain. Peters’ educational work can be best understood as an attempt to reunite education with moral philosophy such that the study of education would resume a profile similar to its nineteenth‐century counterpart, when it was moral philosophy that provided the most interesting discussions of human nature, primitive customs, and social institutions—education among them. 相似文献
8.
This paper examines the relation between situated cognition theory in science education, and feminist standpoint theory in
philosophy of science. It shows that situated cognition is an idea borrowed from a long since discredited philosophy of science.
It argues that feminist standpoint theory ought not be indulged as it is a failed challenge to traditional philosophy of science.
Standpoint theory diverts attention away from the abiding educational and career needs of women in science. In the interest
of women in science, and in the interest of science, science educators would do best for their constituencies by a return
to feminist philosophy understood as the demand for equal access and a level playing field for women in science and society.
Dr. Cassandra L. Pinnick’s research interests focus on formal rationality and the epistemological weight of evidence, evidence in law and science, and anti scientific Realism. Her publications that concern women, science, and the philosophy of science, include essays in the journals Philosophy of Science, Metascience, Social Epistemology, a contributed chapter to the Routledge Companion for Philosophy of Science, and co-editorship of the anthology Scrutinizing Feminist Epistemology of Science (Rutgers). 相似文献
| Cassandra L. PinnickEmail: |
Dr. Cassandra L. Pinnick’s research interests focus on formal rationality and the epistemological weight of evidence, evidence in law and science, and anti scientific Realism. Her publications that concern women, science, and the philosophy of science, include essays in the journals Philosophy of Science, Metascience, Social Epistemology, a contributed chapter to the Routledge Companion for Philosophy of Science, and co-editorship of the anthology Scrutinizing Feminist Epistemology of Science (Rutgers). 相似文献
9.
Amy Ricketts 《Science & Education》2014,23(10):2119-2135
With the goal of producing scientifically literate citizens who are able to make informed decisions and reason critically when science intersects with their everyday lives, the National Research Council (NRC) has produced two recent documents that call for a new approach to K-12 science education that is based on scientific practices, crosscutting concepts, and disciplinary core ideas. These documents will potentially influence future state standards and K-12 curricula. Teachers will need support in order to teach science using a practices based approach, particularly if they do not have strong science backgrounds, which is often the case with elementary teachers. This study investigates one cohort (n = 19) of preservice elementary teachers’ ideas about scientific practices, as developed in a one-semester elementary science teaching methods course. The course focused on eight particular scientific practices, as defined by the National Research Council’s A Framework for K-12 Science Education: Practices, Crosscutting Concepts, and Core Ideas (2012). Participants’ written reflections, lesson plans and annotated teaching videos were analyzed in fine detail to better understand their ideas about what it means to engage in each of the practices. The findings suggest that preservice elementary teachers hold promising ideas about scientific practices (such as an emphasis on argumentation and communication between scientists, critical thinking, and answering and asking questions as the goal of science) as well as problematic ideas (including confusion over the purpose of modeling and the process of analysis, and conflating argumentation and explanation building). These results highlight the strengths and limitations of using the Framework (NRC 2012) as an instructional text and the difficulties of differentiating between preservice teachers’ content knowledge about doing the practices and their pedagogical knowledge about teaching the practices. 相似文献
10.
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
11.
Bayer Corporation 《Journal of Science Education and Technology》2014,23(5):617-623
A major debate is currently underway in the USA about whether there is, in fact, a science, technology, engineering and mathematics (STEM) workforce shortage in the country or not. This is the subject of the Bayer Facts of Science Education XVI: US STEM Workforce Shortage—Myth or Reality? Fortune 1000 Talent Recruiters on the Debate. An ongoing public opinion research project commissioned by Bayer Corporation, the Bayer Facts surveys examine US STEM education, diversity and workforce issues. The 16th in the series, the newest survey asks talent recruiters at some of the country’s largest employers—those included in the Fortune 1000—to weigh in on current and future demand for new hires with 2- and 4-year STEM degrees. As professionals responsible for scouting, recruiting and hiring talent at Fortune 1000 companies, both STEM and non-STEM alike, these individuals are on the frontlines, tasked with assessing and filling their companies’ workforce needs. The survey asks the recruiters whether new hires with 2- and 4-year STEM degrees are as, more or less in demand than their peers without STEM degrees? Are more new STEM jobs being created at their companies than non-STEM jobs? Can they find adequate numbers of qualified candidates in a timely manner and how fierce is the competition for STEM degree holders? To answer these and other questions, the survey polled 150 talent recruiters at Fortune 1000 companies, both STEM and non-STEM alike. The survey also asks the recruiters about diversion in STEM, workforce diversity in the pipeline, the role of community colleges in developing the STEM pipeline and the desired skills and competencies of new hires. 相似文献
12.
This is not the profile or an account of the scientific contributions of an individual but a sharing of personal experience with a visionary, missionary and grass-root researcher — Yelavarthy Nayudamma — who made the Central Leather Research Institute (CLRI) rise to glory. His is a life that raises the hopes and aspirations of youth from small towns. His contributions are part of a living legacy. His research on the shrinkage1 phenomena of leather and the theory of tanning has stood the test of time. His leadership qualities carry many lessons for leaders of scientific establishments for generations to come. The League of Nations heeded as Nayudamma spoke for the cause of developing nations and for connecting science to development. Theory and practice for him were like two eyes essential for depth vision. For many who knew him he is a living inspirational spirit — his legacy lives long after his passing away in a tragic air crash in 1985. 相似文献
13.
Bobbie A. Henderson 《Early Childhood Education Journal》1983,11(1):10-11
CIA does not stand for what you ordinarily would think, The Central Intelligence Agency! These initials can be quite meaningful to caregivers and definitely beneficial to school-agers who are involved in before and after school care. CIA—Creativity, Imagination and Anticipation! These are key words and functions which can enhance a school-age program. 相似文献
14.
Gianna Katsiampoura 《Science & Education》2008,17(6):663-668
There is thus nothing paradoxical about the inclusion of alchemy in the ensemble of the physical sciences nor in the preoccupation
with it on the part of learned men engaged in scientific study. In the context of the Medieval model, where discourse on the
physical world was ambiguous, often unclear, and lacking the support of experimental verification, the transmutation of matter,
which was the subject of alchemy, even if not attended by a host of occult features, was a process that was thought to have
a probable basis in reality. What is interesting in this connection is the utilization of the scientific categories of the
day for discussion of transmutation of matter and the attempt to avoid, in most instances in the texts that survive, of methods
reminiscent of magic.
Gianna Katsiampoura is researcher of History and History of Science in the Byzantine Era and she has taught at the University of Crete, Greece. Her Ph.D. Dissertation is about Perception, Transmission and Function of Science in Middle Byzantine Era and the Quadrivium of 1008, Department of Sociology, Panteion University of Social and Political Science, Athens 2004. She has published papers in referred journals on History and Philosophy of Science in Byzantium. Her research interests include history and philosophy of science, history of education and the relation between history of science and political and economic history of Byzantium. 相似文献
| Gianna KatsiampouraEmail: |
Gianna Katsiampoura is researcher of History and History of Science in the Byzantine Era and she has taught at the University of Crete, Greece. Her Ph.D. Dissertation is about Perception, Transmission and Function of Science in Middle Byzantine Era and the Quadrivium of 1008, Department of Sociology, Panteion University of Social and Political Science, Athens 2004. She has published papers in referred journals on History and Philosophy of Science in Byzantium. Her research interests include history and philosophy of science, history of education and the relation between history of science and political and economic history of Byzantium. 相似文献
15.
In everyday language we tend to think of knowledge as reasoned belief that a proposition is true and the natural sciences provide the archetypal example of what it means to know. Religious and ideological propositions are the typical examples of believed propositions. Moreover, the radical empiricist worldview so often associated with modern science has eroded society's meaningful sense of life. Western history, however, shows that knowledge and belief have not always been constructed separately. In addition, modern developments in the philosophy and history of science have seriously undermined the radical empiricist's excessive confidence in scientific methods. Acknowledging in the science classroom the parallel structure of knowledge and belief, and recognizing that science requires a presuppositional foundation that is itself not empirically verifiable would re introduce a valuable discussion on the meaning of science and its impact on life. Science would less likely be taught as a `rhetoric of conclusions'. The discussion would also help students to gain a firmer integration of science with other important knowledge and beliefs that they hold. 相似文献
16.
17.
Jack Pearpoint 《International Review of Education/Internationale Zeitschrift für Erziehungswissenschaft/Revue internationale l'éducation》1989,35(4):491-503
Two basic points are made in this article: -We must make a choice whether we ‘isolate’ people from or ‘include’ people in our communities. Including people is the only viable option. -The key to ‘including’ people is with the very people we most often label as ‘the problems’. These ‘problem people’ can help generate answers when we learn how to listen, and when we offer genuine learning opportunities and valid partnerships with those who have been ‘missed’ and discarded. Examples from various Frontier College programs illustrate these points and elaborate the central philosophy of the College (Student Centred Individualized Learning — SCIL), which is based on the beliefs that: -All are welcome -All belong -All can learn -All have contributions to make The programmes are focused on ‘literacy’, which is a great deal more than reading and writing — it is about what kind of society we want. Literacy is a tool for ‘inclusion’ in communities. It is hard work, and includes love and tears, grief and joy, families and friends. It is based on the Right to Learn, and builds dignity, self esteem and choices. 相似文献
18.
Don Howard 《Science & Education》2009,18(2):199-220
This paper asks what is necessary in a theory of science adequate to the task of empowering philosophers of science to participate
in public debate about science in a social context. It is argued that an adequate theory of science must be capable of theorizing
the role of values and motives in science and that it must take seriously the irreducibly social nature of scientific knowledge.
Don Howard is a Professor in the Department of Philosophy and the Program in History and Philosophy of Science at the University of Notre Dame. He holds a B.Sc. in physical sciences from Michigan State University and both an M.A. and a Ph.D. in philosophy from Boston University. His special interests include the history and philosophical foundations of physics and the history of the philosophy of science. Recent publications include: The Challenge of the Social and the Pressure of Practice: Science and Values Revisited, co-edited with Martin Carrier and Janet Kourany (University of Pittsburgh Press, forthcoming); “‘Let me briefly indicate why I do not find this standpoint natural.’ Einstein, General Relativity, and the Contingent A Priori,” in Synthesis and the Growth of Knowledge: Examining Michael Friedman’s Approach to the History of Philosophy and Science, Michael Dickson and Mary Domski, eds. (Open Court, forthcoming); “Einstein and the Philosophy of Science,” in the Cambridge Companion to Einstein, Michel Janssen and Christoph Lehner, eds. (Cambridge University Press, forthcoming); and “Albert Einstein as a Philosopher of Science,” Physics Today (2005). 相似文献
| Don HowardEmail: |
Don Howard is a Professor in the Department of Philosophy and the Program in History and Philosophy of Science at the University of Notre Dame. He holds a B.Sc. in physical sciences from Michigan State University and both an M.A. and a Ph.D. in philosophy from Boston University. His special interests include the history and philosophical foundations of physics and the history of the philosophy of science. Recent publications include: The Challenge of the Social and the Pressure of Practice: Science and Values Revisited, co-edited with Martin Carrier and Janet Kourany (University of Pittsburgh Press, forthcoming); “‘Let me briefly indicate why I do not find this standpoint natural.’ Einstein, General Relativity, and the Contingent A Priori,” in Synthesis and the Growth of Knowledge: Examining Michael Friedman’s Approach to the History of Philosophy and Science, Michael Dickson and Mary Domski, eds. (Open Court, forthcoming); “Einstein and the Philosophy of Science,” in the Cambridge Companion to Einstein, Michel Janssen and Christoph Lehner, eds. (Cambridge University Press, forthcoming); and “Albert Einstein as a Philosopher of Science,” Physics Today (2005). 相似文献
19.
Tenaha O’Reilly Jonathan Weeks John Sabatini Laura Halderman Jonathan Steinberg 《Educational Psychology Review》2014,26(3):403-424
When designing a reading intervention, researchers and educators face a number of challenges related to the focus, intensity, and duration of the intervention. In this paper, we argue there is another fundamental challenge—the nature of the reading outcome measures used to evaluate the intervention. Many interventions fail to demonstrate significant improvements on standardized measures of reading comprehension. Although there are a number of reasons to explain this phenomenon, an important one to consider is misalignment between the nature of the outcome assessment and the targets of the intervention. In this study, we present data on three theoretically driven summative reading assessments that were developed in consultation with a research and evaluation team conducting an intervention study. The reading intervention, Reading Apprenticeship, involved instructing teachers to use disciplinary strategies in three domains: literature, history, and science. Factor analyses and other psychometric analyses on data from over 12,000 high school students revealed the assessments had adequate reliability, moderate correlations with state reading test scores and measures of background knowledge, a large general reading factor, and some preliminary evidence for separate, smaller factors specific to each form. In this paper, we describe the empirical work that motivated the assessments, the aims of the intervention, and the process used to develop the new assessments. Implications for intervention and assessment are discussed. 相似文献
20.
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