This anthology contains selected papers from the 'Science as Culture' conference held at Lake Como, and Pavia University Italy, 15-19 September 1999. The conference, attended by about 220 individuals from thirty countries, was a joint venture of the International History, Philosophy and Science Teaching Group (its fifth conference) and the History of Physics and Physics Teaching Division of the European Physical Society (its eighth conference). The magnificient Villa Olmo, on the lakeshore, provided a memorable location for the presentors (...) of the 160 papers and the audience that discussed them. The conference was part of local celebrations of the bicentenary of Alessandro Volta's creation of the battery in 1799. Volta was born in Como in 1745, and for forty years from 1778 he was professor of experimental physics at Pavia University. The conference was fortunate to have had the generous financial support of the Italian government's Volta Bicentenary Fund, Lombardy region, Pavia University, Italian Research Council, and Kluwer Academic Publishers. The papers included here, have or will be, published in the journal Science & Education, the inaugural volume (1992) of which was a landmark in the history of science education publication, because it was the first journal in the field devoted to contributions from historical, philosophical and sociological scholarship. Clearly these 'foundational' disciplines inform numerous theoretical, curricular and pedagogical debates in science education. Contemporary Concerns The reseach promoted by the International and European Groups, and by the journal, is central to science education programmes in most areas of the world. (shrink)

The aim of the article is the analysis of the principle of fair play which co-creates an axiological basis of contemporary sport as well as its basic moral category. The constituents of fair play are, first of all, responsibility and justice. Both values are central values, connected with each other, and also closely connected with other values inscribed in fair play, e.g. respect, solidarity, care or honesty. The conducted analysis shows that the rules of fair play connected with formal responsibility (...) and justice, i.e. following the rules and caring for the integrity of sport, are constituent for both sport and esports, whereas the rules of fair play connected with acting responsibly, i.e. respect and avoiding victory at all costs, are hard to realise in esports. It results from the fact that contact between the players is digitally mediated. Hence, apart from gestures and verbal communication, display of respect towards a player during a game is impeded, as is still more a spontaneous reaction to his or her being hurt. Also, avoiding winning at all costs is impeded in esports, as activities directed at obtaining victory are built into the content of the game and therefore should be carried out in accordance with the regulations, from the technical and tactical side and according to the possessed skills. However, it is possible to stop the game when the connection with the other player is suddenly interrupted. From a fair-play perspective also the content of some games employed in esports is questionable, as it assumes contesting moral rules, which in turn is at variance with the realisation of integrative, educational and formative functions of esports in society. (shrink)

Explores the teaching and learning of issues relating to the impact of science in society. This title offers practical guidance in devising learning goals and suitable learning and assessment strategies. It helps teachers to provide students with the skills and understanding needed to address these multi-faceted issues.

Primary Science Education: A Teacher's Toolkit is an accessible and comprehensive guide to primary school science education and its effective practice in the classroom. Primary Science Education is structured in two parts: Planning for Science and Primary Science in the Classroom. Each chapter covers fundamental topics, such as: curriculum requirements (including the Australian Curriculum and Australian Professional Standards for Teachers); preparing effective learning sequences with embedded authentic assessment; combining science learning with (...) other learning areas, such as technologies and STEM; and critically analysing the teacher's role in the classroom. The text features short-answer and 'Bringing it Together' questions to encourage readers to consolidate their understanding of key themes. Case studies throughout provide guidance on the classroom experience and Teacher Background Information boxes explore topics where more in-depth knowledge is required. The book is supported by a suite of online resources, including interviews with Australian primary teachers and students, and downloadable activities. (shrink)

Constructivism is one of the most influential theories in contemporary education and learning theory. It has had great influence in science education. The papers in this collection represent, arguably, the most sustained examination of the theoretical and philosophical foundations of constructivism yet published. Topics covered include: orthodox epistemology and the philosophical traditions of constructivism; the relationship of epistemology to learning theory; the connection between philosophy and pedagogy in constructivist practice; the difference between radical and social constructivism, and (...) an appraisal of their epistemology; the strengths and weaknesses of the Strong Programme in the sociology of science and implications for science education. The book contains an extensive bibliography. Contributors include philosophers of science, philosophers of education, science educators, and cognitive scientists. The book is noteworthy for bringing this diverse range of disciplines together in the examination of a central educational topic. (shrink)

In a recent contribution to Learning for Democracy, Richard Bailey argues that Thomas Kuhn advocated an indoctrinatory model of science education, which is fundamentally authority-based. While agreeing with Bailey’s conclusion, this article suggests that Kuhn was attempting to solve an important problem which Bailey only touches on – how to ensure that science students do not become hypercritical. It continues by offering a critical rationalist solution to this problem, arguing that paradigms qua exemplars should be historical problem-solving (...) episodes, rather than model solutions to puzzles. (shrink)

INTRODUCTION What relevance — if any — does philosophy of science have for science education? Unfortunately, this question has been largely unexplored. ...

A la fin du XIXe siècle, le progrès des sciences et des techniques parut ouvrir une ère de bonheur où l'homme, délivré des tâches serviles et de toutes les superstitions, serait enfin le maître de la nature et de son propre destin. Mais le XXe siècle ne tint pas ces promesses. Certes, le progrès des sciences a fait reculer la mortalité infantile et allonger l'espérance de vie. Les nouveaux moyens de communication ont permis la circulation rapide d'informations autour du globe. (...) Mais notre environnement est menacé par toutes sortes de déchets. La biologie a ouvert des voies effrayantes. l'automatisation a bouleversé le monde du travail. La nécessité de former des scientifiques pour créer et maîtriser ces nouveaux outils a fait reculer la culture classique. De tels changements ont obscurci les repères traditionnels, les esprits sont déroutés, le sens est en crise. A l'entrée du troisième millénaire, l'Académie d'Education et d'Etudes sociales ne pouvait laisser ces questions dans l'ombre : elles sont trop souvent l'objet de débats plus passionnés que fondés et raisonnés. La science menace-t-elle l'homme et son environnement? Pèse-t-elle sur la cohésion sociale et la démocratie? Quelle est sa place dans la culture, à côté de la philosophie? Comment le chrétien se situe-t-il dans ce monde scientifique et technique? Par une étude raisonnée de ces questions, l'AES souhaite délivrer un message d'espoir et de confiance, et contribuer à mettre le développement scientifique et technique au service de l'homme, suivant la parole de l'Ecclésiastique : " Le Très-Haut a donné à l'homme le savoir pour être glorifié dans ses merveilles " (17,8). (shrink)

Over the past 50 years, postmodernism has been a progressively growing and influential intellectual movement inside and outside the academy. Postmodernism is characterised by rejection of parts or the whole of the Enlightenment project that had its roots in the birth and embrace of early modern science. While Enlightenment and ‘modernist’ ideas of universalism, of intellectual and cultural progress, of the possibility of finding truths about the natural and social world and of rejection of absolutism and authoritarianism in politics, (...) philosophy and religion were first opposed at their birth in the eighteenth century, contemporary postmodernism sometimes appeals to (and sometimes disdains) philosophy of science in support of its rejection of modernism and the enlightenment programme. (shrink)

Science educators and those who investigate science learning have tended, for good reason, to focus their attention on students' conceptual development, Such a focus is, however, too narrow to provide full and proper understanding of the complexities of original science learning. Recently developmental cognitive psychologists have called on the work of postpositivistic philosophers of science, especially Thomas Kuhn, to bolster their research into conceptual development in science acquisition. What these psychologists have not recognized is that (...) Kuhn's position is actually a derivative of Wittgenstein's methodological nominalism, a viewpoint far more favorable to behaviorism than cognitive psychology. After drawing out some of the consequences of this fact for the developmental cognitive psychologist program for studying science learning, we suggest our own radical alternative. Drawing on Floden, Buchmann and Schwille's idea of “Breaking with Everyday Experience” we propose an alternative notion of original science learning in terms of Alfred Schutz's modification of Williams James' many worlds thesis. The many worlds thesis will allow us to better understand students' difficulty in learning idealized worlds such as science, worlds that represent a discontinuous break with ordinary everyday practical experience. (shrink)

Mentalities like scientism and relativism idealise or belittle science respectively, and thus hurt science education and our literacy. However, it seems very hard to avoid the former mentality without sliding to the latter, and vise versa. I will suggest that part of what makes balancing between the two so difficult, is a representational account of meaning that science educators, like most of us really, usually endorse. Scientism then, arises from the assumption that ​there is such a (...) thing called science​. Relativism, on the other hand, assumes that ​there is no such thing called science,t​hereisnorealmeaningattachedtotheterm​.Wittgenstein'sremarksonrule-following then, could help us escape this twofold danger. Addressing scientism, Wittgensteinian writings remind us that, in order to understand the sciences, we do not need to point to some mental referendum of what science is. We rather need to grasp a matrix of overlapping, often implicit, always evolving rules that govern scientific practices. Addressing relativism, Wittgenstein's comments help us realise that there are always certain criteria about what kinds of things we call by a name; there are rules governing scientific practices, rules that even though they may be context dependent or evolving, are always in play. (shrink)

In this essay, I argue that Roy Bhaskar's philosophy of meta‐Reality creates the middle way to theorize emancipation in critical science education: between empiricism and idealism on the one hand, and naïve realism and relativism, on the other hand. This theorization offers possibilities to transcend the usual dichotomies and dualisms that are often perpetuated in some feminist and multiculturalist accounts of critical science education. Further, meta‐Reality suggests a radically new way to re‐visit the suspect notion of (...) emancipation. The implications for critical science education are discussed. (shrink)

This article responds to Schulz's criticisms of an earlier paper published in Educational Philosophy and Theory. The purpose in this paper is to clarify and extend some of my earlier arguments, to indicate what is unfortunate (i.e. what is lost) from a non‐charitable, modernist reading of Lyotardian postmodernism (despite its weaknesses), and to suggest what new directions are emerging in science education from efforts to move beyond an either/or dichotomy of foundationalism and relativism.

The pendulum has had immense scientific, cultural, social and philosophical impact. Historical, methodological and philosophical studies of pendulum motion can assist teachers to improve science education by developing enriched curricular material, and by showing connections between pendulum studies and other parts of the school programme, especially mathematics, social studies, technology and music. The pendulum is a universal topic in high-school science programmes and some elementary science courses; an enriched approach to its study can result in deepened (...) science literacy across the whole educational spectrum. Such literacy will be manifest in a better appreciation of the part played by science in the development of society and culture. Such history, philosophy and science (HPS)-informed teaching and study of pendulum motion can serve as an exemplar of the benefits of HPS-informed teaching across the science curriculum. (This chapter draws on material in Matthews (1998, 2000, 2001, 2004), and on contributions to Matthews et al. (2005)). (shrink)

Both science and ethics are embedded in cultural traditions where truths are shared through education; both need competent critics educated within such traditions. Education in both ought to be directed although moral education demands levels of responsible agency that science education does not. Evolutionary science often carries an implicit or explicit understanding of who and what humans are, one which may not be coherent with the implicit or explicit human self‐understanding in moral (...) class='Hi'>education. The latter in turn may not be coherent with classical human self‐understandings. Moral education may enlighten and elevate the human nature that has evolved biologically. (shrink)

Two varieties of constructivism are distinguished. In part 1, the psychological or “radical” constructivism of von Glasersfeld is discussed. Despite its dominant influence in science education, radical constructivism has been controversial, with challenges to its principles and practices. In part 2, social constructivism is discussed in the sociology of scientific knowledge. Social constructivism has not been primarily concerned with education but has the most direct consequences in view of its challenge to the most fundamental, traditional assumptions in (...) the philosophy of science and to the practice of science itself. (shrink)

ABSTRACT This essay argues that science education can gain from close engagement with the history of science both in the training of prospective vocational scientists and in educating the broader public about the nature of science. First it shows how historicizing science in the classroom can improve the pedagogical experience of science students and might even help them turn into more effective professional practitioners of science. Then it examines how historians of science (...) can support the scientific education of the general public at a time when debates over “intelligent design” are raising major questions over the kind of science that ought to be available to children in their school curricula. It concludes by considering further work that might be undertaken to show how history of science could be of more general educational interest and utility, well beyond the closed academic domains in which historians of science typically operate. (shrink)

One of the most important and consistent voices in the reform of science education over the last thirty years has been that of Peter Fensham. His vision of a democratic and socially responsible science education for all has inspired change in schools and colleges throughout the world. Often moving against the tide, Fensham travelled the world to promote his radical ideology. He was appointed Australia's first Professor of Science Education, and was later made a (...) Member of the Order of Australia in recognition of his work in this new and emerging field of study. In this unique book, leading science educators from around the world examine and discuss Fensham's key ideas. Each describes how his arguments, proposals and recommendations have affected their own practice, and extend and modify his message in light of current issues and trends in science education. The result is a vision for the future of science teaching internationally. Academics, researchers and practitioners in science education around the world will find this book a fascinating insight into the life and work of one of the foremost pioneers in science education. The book will also make inspiring reading for postgraduate students of science education. (shrink)

In a number of countries, issues to do with religion seem increasingly to be of importance in school science lessons and some other science educational settings, such as museums. This chapter begins by discussing the nature of religion and the nature of science and then looks at understandings of possible relationships between science and Christianity with particular reference to such issues as determinism, evolution and the uses to which advances in scientific knowledge may be put. It (...) then goes on to examine whether the notion of worldviews is helpful to science educators working in this area. Finally, ways of teaching science so as to take account of Christian beliefs are considered. (shrink)

This chapter explores how perspectives on science drawn from Indian experiences can contribute to the interface between history and philosophy of science (HPS) and science education (SE). HPS is encoded in science texts in the various presuppositions that underlie both the content and the way the content is presented. Thus, a deeper engagement with contemporary work in HPS will be of great significance to science teaching. By drawing on the notion of multicultural origins of (...) science as well as redefining the nature of science debate by invoking the Indian engagement with science, this chapter aims to make both HPS and SE more sensitive to other cultural understandings of science and scientific method. The last two sections describe ways of drawing on the Indian philosophical traditions that could be relevant for contemporary debates, such as constructivism and teaching critical thinking, in science education. (shrink)