If any nature of science perspective is to be incorporated in science-related curricula, it is hard to imagine a satisfactory didactic toolkit that neglects the social studies of science, the academic field of study of the institutional structures and networks of science. Knowledge production takes place in a world populated by actors, instruments, and ideas, and various epistemic cultures are responsible for providing the concepts, abstractions, and techniques that slowly trickle down the information pathways to become stabilized in university curricula (...) or ossified in high-school science, losing much of the tacit knowledge along the way that enabled the production of knowledge in the first place. The discussion of the sociology of science and the sociology of scientific knowledge is followed by a short overview of recent approaches in science studies and the studies of expertise. (shrink)

This inaugural handbook documents the distinctive research field that utilizes history and philosophy in investigation of theoretical, curricular and pedagogical issues in the teaching of science and mathematics. It is contributed to by 130 researchers from 30 countries; it provides a logically structured, fully referenced guide to the ways in which science and mathematics education is, informed by the history and philosophy of these disciplines, as well as by the philosophy of education more generally. The first handbook to cover the (...) field, it lays down a much-needed marker of progress to date and provides a platform for informed and coherent future analysis and research of the subject. -/- The publication comes at a time of heightened worldwide concern over the standard of science and mathematics education, attended by fierce debate over how best to reform curricula and enliven student engagement in the subjects There is a growing recognition among educators and policy makers that the learning of science must dovetail with learning about science; this handbook is uniquely positioned as a locus for the discussion. -/- The handbook features sections on pedagogical, theoretical, national, and biographical research, setting the literature of each tradition in its historical context. Each chapter engages in an assessment of the strengths and weakness of the research addressed, and suggests potentially fruitful avenues of future research. A key element of the handbook’s broader analytical framework is its identification and examination of unnoticed philosophical assumptions in science and mathematics research. It reminds readers at a crucial juncture that there has been a long and rich tradition of historical and philosophical engagements with science and mathematics teaching, and that lessons can be learnt from these engagements for the resolution of current theoretical, curricular and pedagogical questions that face teachers and administrators. (shrink)

Research on the nature of science and science education enjoys a longhistory, with its origins in Ernst Mach's work in the late nineteenthcentury and John Dewey's at the beginning of the twentieth century.As early as 1909 the Central Association for Science and MathematicsTeachers published an article – ‘A Consideration of the Principles thatShould Determine the Courses in Biology in Secondary Schools’ – inSchool Science and Mathematics that reflected foundational concernsabout science and how school curricula should be informed by them. Sincethen (...) a large body of literature has developed related to the teaching andlearning about nature of science – see, for example, the Lederman and Meichtry reviews cited below. As well there has been intensephilosophical, historical and philosophical debate about the nature of scienceitself, culminating in the much-publicised ‘Science Wars’ of recent time. Thereferences listed here primarily focus on the empirical research related to thenature of science as an educational goal; along with a few influential philosophicalworks by such authors as Kuhn, Popper, Laudan, Lakatos, and others. Whilenot exhaustive, the list should prove useful to educators, and scholars in otherfields, interested in the nature of science and how its understanding can berealised as a goal of science instruction. The authors welcome correspondenceregarding omissions from the list, and on-going additions that can be made to it. (shrink)

Undergraduate geoscience students are rarely exposed to history and philosophy of science. I will describe the experiences with a short course unfavourably placed in the first year of a bachelor of earth science. Arguments how HPS could enrich their education in many ways are sketched. One useful didactic approach is to develop a broader interest by connecting HPS themes to practical cases throughout the curriculum, and develop learning activities that allow students to reflect on their skills, methods and their field (...) in relation to other disciplines and interactions with society with abilities gained through exposure to HPS. Given support of the teaching staff, the tenets of philosophy of science in practice, of conceptual history of knowledge, and of ethics of science for society can fruitfully and directly be connected to the existing curriculum. This is ideally followed by a capstone HPS course late in the bachelor programme. (shrink)

W artykule jest suponowana opozycja między statyką i dynamiką nauki. Przez naukę rozumiemy głównie nauki empiryczne, zwłaszcza przyrodnicze, lub nauki ścisłe (sciences), inaczej: matematyczne przyrodoznawstwo. Przy doborze kategorii jako przedmiotu podjętych analiz kierowano się racjami badawczymi oraz odwołującymi się do praktyki naukowej i metanaukowej. Kontekstowe objaśnienia tych obiektów relatywizowano do sytuacji poznawczej potencjalnych odbiorców. Uwzględniano zarówno adeptów, jak i profesjonalnie zainteresowanych refleksją nad czynnościowo i wytworowo ujmowaną nauką. Podjęte zagadnienia są rozpatrywane poprzez stopniowe dyskusje aspektywnie wyselekcjonowanych problemów. W rozpatrywanej perspektywie (...) należą do nich: ramowe stanowiska; terminy-klucze; statyka/dynamika nauki; rewolucje w filozofii nauki; dwa konteksty; nowa filozofia nauki; nurt normatywny i deskryptywny; kategoria rewolucji naukowych; super-, supra- i maksiteorie jako jednostki ponadteoretyczne; problematyka aksjologiczna; pluralizm filozofii nauki; problem / teoria problemu; wartość — kategoria z zakresu aksjologii epistemicznej; dalsze zagadnienia filozofii nauki; charakterystyka opracowania. (shrink)

Inquiry teaching can be viewed as an approach for communicating the knowledge and practices of science to learners. In its various forms inquiry offers potential learning opportunities and poses constraints on what might be available to learn. Philosophical analysis offers ways of understanding inquiry, knowledge, and social practices. This chapter will examine philosophical problems that arise from teaching science as inquiry. Observation, experimentation, measurement, inference, explanation, and modeling pose challenges for novice learners who may not have the conceptual and epistemic (...) knowledge to engage effectively in such scientific practices in inquiry settings. Science learning entails apprenticeship and socialization into a legacy of conceptual knowledge and epistemic practices (Kelly. Inquiry, Activity, and Epistemic Practice. In R. Duschl & R. Grandy (Eds.) Teaching Scientific Inquiry: Recommendations for Research and Implementation (pp. 99–117; 288–291). Rotterdam: Sense Publishers, 2008). Modern science increasingly relies on abstract and computational models that are not readily constructed from the student-driven questions that often function as an early step in inquiry approaches to instruction. Thus, engaging students in the epistemic practices of science poses challenges for educators. -/- The argument developed in this chapter draws from an epistemological position that makes clear the need for building from extant disciplinary knowledge of a relevant social group in order to learn through inquiry. Establishing a social epistemology in educational settings provides opportunities for students to engage in ways of speaking, listening, and explaining that are part of constructing knowledge claims in science (Kelly and Chen. Journal of Research in Science Teaching 36, 883–915, 1999). This perspective on epistemology emphasizes the importance of dialectical processes in science learning. Thus, an inquiry-oriented pedagogy needs to attend to developing norms and practices in educational settings that provide opportunities to learn through and about inquiry. By considering the situated social group as the epistemic subject, inquiry teaching and learning can be viewed as creating opportunities for supporting the conceptual, epistemic, and social goals of science education (Duschl. Review of Research in Education, 32, 268–291, 2008; Kelly. Inquiry, Activity, and Epistemic Practice. In R. Duschl & R. Grandy (Eds.) Teaching Scientific Inquiry: Recommendations for Research and Implementation (pp. 99–117; 288–291). Rotterdam: Sense Publishers, 2008). -/- The chapter addresses the philosophical considerations of inquiry in science education by identifying the epistemological constraints to teaching science as inquiry, reviewing the potential contributions of philosophy of science to discussions regarding inquiry, considering how social epistemology aligns with developments in psychology of learning with understandings about science, and offering ways that philosophical analysis can contribute to the on-going conversations regarding science education reform. (shrink)

We assessed the impact of teaching methodological aspects of physics on students’ scientistic beliefs and subject interest in physics in a repeated-measurement design with a total of 142 students of upper secondary physics classes. Students gained knowledge of methodological aspects from the pre-test to the post-test and reported reduced scientistic beliefs, both from their own views and from their presumed prototypical physicists’ views. We found no direct impact of teaching on students’ subject interest in physics. As path analysis indicates, this (...) result can be traced back to opposing paths: Lower scientistic beliefs of students attenuate subject interest while lower presumed scientistic beliefs that they hold of physicists foster subject interest. This finding is in accordance with the self-to-prototype matching theory that predicts an impact of the overlap between students’ self-image and their prototypical image on subject interest in physics. (shrink)