The ‘community of inquiry’ as formulated by C. S. Peirce is grounded in the notion of communities of discipline-based inquiry engaged in the construction of knowledge. The phrase ‘transforming the classroom into a community of inquiry’ is commonly understood as a pedagogical activity with a philosophical focus to guide classroom discussion. But it has a broader application. Integral to the method of the community of inquiry is the ability of the classroom teacher to actively engage in the theories and practices (...) of discipline-based communities of inquiry so as to become informed by the norms of the disciplines, not only to aspire to competence within the disciplines, but also to develop habits of self-correction for reconstructing those same norms when faced with novel problems and solutions, including those in the classroom. This has implications for science education and the role of educational philosophy in developing students' ability to think scientifically. But it also has broader implications for thinking critically within all key learning areas. Here we concentrate on science education. We present the parallels between philosophical inquiry and scientific inquiry that need to be realised to promote and engage with scientific inquiry in the classroom. We also discuss the conflicts between philosophical inquiry and the way inquiry science in the classroom is portrayed in the education literature. Based on philosophical and historical perceptions of science as inquiry, a practical approach to implementation of scientific inquiry in the science classroom is presented. (shrink)

We believe that physics education has to meet today’s requirement for a qualitative approach to Quantum Mechanics (QM) worldview. An effective answer to the corresponding instructional problem might allow the basic ideas of QM to be accessed atan early stage of physics education. This paper presents part of a project that aims at introducing a sufficient, simple, and relevant teaching approach towards QM into in-/preservice teacher education, i.e., at providing teachers with the indispensable scientific knowledge and epistemological base needed for (...) a reform of science education along the aforementioned line. The investigation of teacher–learners’ (t-ls’) initial knowledge indicated that their main misconceptions appear to be the result of their pre-/in university traditional instruction, which causes the overlapping/mix-up of the conceptual frameworks of Classical Physics (CP) and QM. Assuming that these misconceptions form by nature epistemological obstacles to the acquisition of QM knowledge, the educational strategy proposed here aims at leading t-ls to form a conceptual structure that includes CP and QM as two totally independent conceptual systems. Accepting, furthermore, that the complete distinction of these systems demands a radical reconstruction of t-ls’ initial knowledge, we present here an instructional model that bases the required reconstruction on the juxtaposition of two models that constitute the signal point of twentieth century’s “paradigm shift”: (a) Bohr’s semiclassical atom model, and (b) the model of the atom accepted by modern physics theory. (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)

Although postmodernist thought has become prominent in some educational circles, its influence on science education has until recently been rather minor. This paper examines the proposal of Michalinos Zembylas, published earlier in this journal, that Lyotardian postmodernism should be applied to science educational reform in order to achieve the much sought after positive transformation. As a preliminary to this examination several critical points are raised about Lyotard's philosophy of education and philosophy of science which serve to challenge and undermine Zembylas’ (...) project. Subsequently, the three main theses of Lyotard that Zembylas considers beneficial and wishes to transpose onto science classrooms and pedagogy are scrutinized and found to be more of a hindrance than a help to curriculum reformers. (shrink)

This commentary is a critical appraisal of Gil-Pérez et al.'s (2002) conceptualization of constructivism. It is argued that the following aspects of their presentation are problematic: (a) Although the role of controversy is recognized, the authors implicitly subscribe to a Kuhnian perspective of `normal' science; (b) Authors fail to recognize the importance of von Glasersfeld's contribution to the understanding of constructivism in science education; (c) The fact that it is not possible to implement a constructivist pedagogy without a constructivist epistemology (...) has been ignored; and (d) Failure to recognize that the metaphor of the `student as a developing scientist' facilitates teaching strategies as students are confronted with alternative/rival/conflicting ideas. Finally, we have shown that constructivism in science education is going through a process of continual critical appraisals. (shrink)

Research in science education has recognized the importance of history and philosophy of science (HPS), and this has facilitated the evaluation of science textbooks. Purpose of this chapter is to review research based on analyses of science textbooks that explicitly use a history and philosophy of science framework. This review has focused on studies published in the 15-year period (1996–2010) and has drawn on the following major science education journals: International Journal of Science Education, Journal of Research in Science Teaching, (...) Science Education, and Science & Education. Based on HPS-related criteria, 52 articles were selected for review, and of these 28 were published in Science & Education, which clearly shows the importance of HPS for this journal. Selected articles were classified in the following subject areas depending on the textbooks analyzed: university biology textbooks (n = 2), university chemistry textbooks (n = 14), university physics textbooks (n = 17), and primary, secondary, and high school textbooks (n = 19). Results obtained revealed the following: (a) Most biology, chemistry, physics, and school science textbooks lack a history and philosophy of science perspective; (b) most of the textbooks analyzed were published in the USA and to a much lesser extent in other countries; (c) few studies provided details of the procedure and reliability of the application of criteria/rubric for analyzing textbooks; (d) some of the topics analyzed in the textbooks were nature of science, atomic structure, Newtonian mechanics, quantum mechanics, special theory of relativity, and evolution; (e) textbooks avoided including controversial and difficult aspects of different topics (e.g., concepts of force, weight, heat, temperature, origin of the quantum hypothesis, oil drop experiment, Millikan’s data supported Einstein’s photoelectric equation but not his theory); and (f) various science topics provide an opportunity to illustrate the tentative nature of scientific knowledge, and still very few textbooks referred to this important aspect. As textbooks do refer to laws and theories while referring to historical content, it is concluded that HPS is already “inside” the science curriculum provided textbook authors make an effort to scrutinize the historical reconstructions while dealing with the different topics. (shrink)

Despite claims that STS science education promotes ethical responsibility, this approach is not supported by a clear philosophy of ethics. This paper argues that the work of Emmanuel Levinas provides an ethics suitable for an STS science education. His concept of the face of the Other redefines education as learning from the other, rather than about the other. Extrapolating the face of the Other to the non‐human world suggests an ethics for science education where the goal of pedagogy is peace (...) with each other and the world through the rupture, eros and justice that arises from openness to the demands of the world. Understanding the infinite responsibility of the invocation presented by the face of the Other radically reconceptualizes science education from STS towards an E‐STS curriculum of responsiveness that critically employs the said of modern science and opportunities of experience to enable the next generation of citizens to act in peace to what the world is saying. (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)

Thomas Kuhn’un ufuk açıcı eseri Bilimsel Devrimlerin Yapısı’nda yer verdiği bilimin yapısı ve işleyişi konusundaki tespitleri ve bilimin gerçek doğasını anlama yönündeki girişimleri bilime yönelik sergilenen pozitivist bakış açısını değiştirerek eğitici ve öğrencilerin modern bilim anlayışının özelliklerini daha iyi anlamalarında ve eğitim alanında yeni düzenlemelerin yapılmasında giderek etkili olmaktadır. Başta fen eğitimi araştırmacıları olmak üzere her geçen yıl eğitimciler tarafından Kuhn’un çalışmalarına yönelik artan ilgi ve başvuru bu durumu destekler niteliktedir (Loving ve Cobern, 2000, s. 187). Eğitim araştırmalarında Kuhn’un görüşlerinin (...) etkisinin en çok hissedildiği alanlar kavramsal değişim araştırmaları, yapılandırmacı öğrenme yaklaşımı, Bilim, Teknoloji ve Toplum çalışmaları ile bilime ilişkin kültürel çalışmalar gösterilebilir (Matthews, 2022: 38). Fen eğitimi araştırmalarında ise kavramsal değişim kuramları ile yapılandırmacı öğrenme kuramlarında bu etki görülmektedir (Loving ve Cobern, 2000, s. 187). Fen eğitimi ve öğrenimi konusundaki mevcut yaklaşımlar göz önüne alındığında Kuhn’un düşüncelerinin eğitim alanındaki yansımaları yapılandırmacı öğrenme kuramının temel kaynaklarından birisi olarak değerlendirilmekte (Hodson, 1988, s. 32), bilimsel ilerleme kapsamında paradigma, paradigma değişimi ve paradigmaların eşölçülemezliği gibi bilimin işleyişine yönelik belirlemeleri ise kavramsal değişim kuramında sıklıkla başvurulan görüşler olarak karşımıza çıkmaktadır. Kavramsal değişim kuramlarını desteklemek amacıyla birçok eğitimci (Loving ve Cobern, 2000; Songer ve Linn, 1991; Duschl ve Gitomer, 1991; Metz, 1991) tarafından Kuhn’un bilimsel ilerlemeyi örneklendirmek üzere başvurduğu fizik gibi bilimlerde görülen gelişim ve değişim ile bilimlerde meydana gelen paradigma değişiklerine yönelik düşünceleri, eğitimde gerçekleşen bireysel gelişim ve değişim sonucunda insan zihninde meydana gelen bilişsel değişimler ve kavramsal değişimlerle ilişkilendirilerek öğrencilerin eğitilmesine yönelik araştırmalarda kullanılmaktadır. Fen eğitimi özelinde kavramsal değişim araştırmaları bireysel öğrenme sırasında ya da sonucunda zihinde gerçekleşen kavramsal değişim ve bilişsel gelişim aşamaları ile bilimsel devrimler sonucunda bilim insanları ve bilim topluluğunda meydana gelen kavramsal değişim ve bilimin gelişim aşamaları arasında benzerlik kurularak öğrencilerin fen öğrenimi sırasındaki zihinsel durumlarının araştırmacılar tarafından daha iyi anlaşılabilmesi amacıyla ileri sürülmektedir (Hewson, 1981, s. 383). Kavramsal değişim araştırmaları, Piaget’nin (1969) çocukların bilişsel gelişimi konusundaki görüşleri ile Thomas Kuhn'un (1970a) bilimsel bilginin tarihsel gelişimi hakkındaki çalışmalarının ilişkilendirilmeye başlanmasından yola çıkılarak inşa edilmekle birlikte kavramsal değişim kuramı ya da yaklaşımı fen eğitimi araştırmalarında ön plana çıkan bir yöntem ya da paradigma haline gelmeye başlamıştır (Abell, Appleton, ve Hanuscin, 2013, s. 7; 59). Kavramsal değişim konusunda araştırma yapanlar Kuhn’un bilimin yapısı hakkındaki görüşlerinden hareketle öğrencilerin eğitim alırken karşılaştıkları yeni bilgiler ile zihinlerindeki mevcut ön kabuller ve bilgiler arasındaki uyum ya da uyumsuzluk durumunu belirtmek amacıyla yararlanmaktadırlar (Abimbola 1987, Duit 1991, Villani, 1992). Bu kapsamda çalışmada ilk olarak fen eğitimi alanında kavramsal değişim yaklaşımının temel unsurlarına öncülük eden Kuhn’un bilim anlayışı çerçevesinde bilimsel ilerleme, paradigma değişimi ve farklı paradigmaların eşölçülmezliğine yönelik görüşlerinin detaylarına yer verilerek kavramsal değişim yaklaşımını hangi açılardan etkilediğinin tespiti yapılmaktadır. Ardından Kuhn’un fen eğitimine yönelik görüşleri doğrultusunda ileri sürdüğü öğrencilerin zihninde paradigma gibi önceden bir kabul olduğu düşüncesi sonucunda eğitim araştırmalarında öğrenci merkezli anlayışın ön plana çıkması ile kavramsal değişim yaklaşımının detaylarına yer verilmektedir. Son olarak Margaret Masterman’ın belirlemeleri ile Kuhn’un Bilimsel Devrimlerin Yapısı’nda paradigma kavramını çeşitli anlamlarda kullanmasının kavramsal değişim yaklaşımının temel öğretilerine hangi açılardan kaynaklık ettiği vurgulanmaktadır. Böylelikle bilim tarihinde ya da bilimsel ilerleme süreçlerinde görülen kavramsal değişim ile eğitimcilerin yararlandığı bireylerin zihinlerinde gerçekleşen kavramsal değişime yönelik kurulan benzerlik ilişkisinde öğrencilerin bilişsel ve zihinsel durumlarını daha iyi anlamak için başvurulan kavramsal değişim yaklaşımına ilişkin öğeler derinleştirilerek Kuhn’un görüşlerinin bu öğelerle nasıl ilişkilendirildiği ortaya konulmaktadır. (shrink)

This chapter utilises scholarship in philosophy of biology and philosophy of chemistry to produce meaningful implications for biology and chemistry education. The primary purpose for studying philosophical literature is to identify different perspectives on the nature of laws and explanations within these disciplines. The goal is not to resolve ongoing debates about the nature of laws and explanations but to consider their multiple forms and purposes in ways that promote deep and practical understanding of biological and chemical knowledge in educational (...) contexts. Most studies on the nature of science in science education tend to focus on general features of scientific knowledge and underemphasise disciplinary nuances. The authors aim to contribute to science education research by focusing on the characterisations of laws and explanations in biology and chemistry in the philosophical literature and illustrating how the typical coverage of biology and chemistry textbooks does not problematise meta-perspectives on the nature of laws and explanations. The chapter concludes with suggestions for making science teaching, learning and curriculum more inclusive of the epistemological dimensions of biology and chemistry. (shrink)

In this paper, domain-specificity is presented as an understudied problem in chemical education. This argument is unpacked by drawing from two bodies of literature: learning of science and epistemology of science, both themes that have cognitive as well as philosophical undertones. The wider context is students’ engagement in scientific inquiry, an important goal for science education and one that has not been well executed in everyday classrooms. The focus on science learning illustrates the role of domain specificity in scientific reasoning. (...) The discussion on epistemology of science presents ideas from the emerging field of philosophy of chemistry to highlight the much neglected area of epistemology in chemical education. Domain-specificity is exemplified in the context of chemical laws, in particular the Periodic Law. The applications of the discussion for chemical education are explored in relation to argumentation, itself an epistemologically grounded discourse pattern in science. The overall implications include the need for reconceptualization of the nature of teaching and learning in chemistry to include more particular epistemological aspects of chemistry. (shrink)

Although the goal of developing school students’ understanding of nature of science has long been advocated, there is still a lack of research that focuses on probing how science teachers, a kind of major stakeholder in NOS instruction, perceive the values of teaching NOS. Through semi-structured interviews, this study investigated the views of 15 Hong Kong in-service senior secondary science teachers about the values of teaching NOS. These values as perceived by the teachers fall into two types. The first type (...) is related to students’ learning of science in the classroom and involves: facilitating the study of subject knowledge, increasing the interest in learning science, supporting the conduct of scientific inquiry, meeting the needs of public examinations, and fulfilling the requirement of learning science. The second type goes beyond learning science and includes developing thinking skills, cultivating scientific ethics in students, and supporting the participation in public decisions on socioscientific issues. Although rich relationships were perceived by these teachers between NOS instruction and students’ learning of science, few values were stated from broad social and cultural perspectives. Suggestions are made about developing teachers’ views of the values of teaching NOS so as to influence their intention of teaching it. (shrink)

An analysis of the present situation regarding the incorporation of HPS into science education is carried out, and some ideas are suggested as to how to make progress in this direction. More precisely, some sections evaluate the situation in Argentina with regard to the incorporation of HPS contributions into physics and biology education. Some aspects that are analysed are the underlying epistemological features in education laws and natural science curriculum design at secondary level in Argentina, the incorporation of HPS in (...) research and the dissemination of HPS contributions to physics teaching among in-service teachers. (shrink)