This chapter contains sections titled: Contemporary Curriculum Reform The Liberal Tradition HPS and Science Pedagogy Contemporary Philosophical Concerns Constructivism and Philosophy Conclusion.

The course Science, Technology, and Society is taken by about 500 engineering students each year at Bilkent University, Ankara. Aiming to complement the highly technical engineering programs, it deals with the ethical, social, cultural, political, economic, legal, environment and sustainability, health and safety, reliability dimensions of science, technology, and engineering in a multidisciplinary fashion. The teaching philosophy and experiences of the instructor are reviewed. Community research projects have been an important feature of the course. Analysis of (...) class='Hi'>teaching style based on a multi-dimensional model is given. Results of outcome measurements performed for ABET assessment are provided. Challenges and solutions related to teaching a large class are discussed. (shrink)

Ethics in science is integrated into an interdisciplinary science course called “Science, Technology and Society” (STS). This paper focuses on the section of the course called “Societal Impact on Science and Technology”, which includes the topics Misconduct in Science, Scientific Freedom and Responsibility, and the Use of Human Subjects in Research. Students in the course become aware not only of the science itself, but also of the process of science, some aspects of the (...) history of science, the social responsibilities of scientists, and the ethical issues in science. Teaching techniques include the instructor sharing experiences as a scientist with the students, sharing books and resources with students, utilizing current sources of information like the weekly “Science Times”, inviting guest speakers, and utilizing portfolios to assess student learning. (shrink)

The teaching of the ethical implications of scientific advances in science courses for undergraduates has significant advantages for both science and non-science majors. The article describes three courses taught by the author as examples of the concept, and examines the disadvantages as well as the advantages. A significant advantage of this approach is that many students take the courses primarily because of the ethical component who would not otherwise take science. A disadvantage is less time (...) in the course for the science; arguably, this is outweighed by the greater retention of the science when it is put into context. (shrink)

The debate about the appropriate methodology of medical education has been (and still is) dominated by the opposing poles of teaching science versus teaching practical skills. I will argue that this conflict between scientific education and practical training has its roots in the underlying, more systematic question about the conceptual foundation of medicine: how far or in what respects can medicine be considered to be a science? By analyzing the epistemological status of medicine I will show (...) that the internal aim of medicine( promoting health through the prevention and treatment of disease ) differs from the internal aim of science ( the methodological and systematic acquisition of knowledge ). Therefore, medicine as a whole discipline should not be considered as a science. However, medicine can be conceptually and methodologically scientific in so much as it is based on scientific knowledge. There is evidence from cognitive science research that diagnostic reasoning not only relies on the application of scientific knowledge but also — especially in routine cases – on a process of pattern recognition, a reasoning strategy based on the memory of previously encountered patients. Hence, medical education must contain both: the imparting of scientific knowledge and the rich exposure to concrete cases during practical training. Hence, the question of teaching science vs. the apprentice model will not be either-or but rather both — but in which proportion? (shrink)

With the goal of understanding how Christopher Southgate communicates his in-depth knowledge of both science and theology, we investigated the many roles he assumes as a teacher. We settled upon wide-ranging topics that all intertwine: (1) his roles as author and coordinating editor of a premier textbook on science and theology, now in its third edition; (2) his oral presentations worldwide, including plenaries, workshops, and short courses; and (3) the team teaching approach itself, which is often needed (...) by others because the knowledge of science and theology do not always reside in the same person. Southgate provides, whenever possible, teaching contexts that involve students in experiential learning, where they actively participate with other students.We conclude that Southgate’s ultimate goal is to teach students how to reconcile science and theology in their values and beliefs, so that they can take advantage of both forms of rational thinking in their own personal and professional lives. The co-authors consider several examples of models that have been successfully used by people in various fields to integrate science and religion. (shrink)

In the context of technological dissemination sessions aimed at prospective students at the Polytechnic University of Baja California in the city of Mexicali, Baja California, the importance of engineering and its role in scientific and technological progress was stressed, as well as its role in scientific and technological progress as drivers of economic development in the region. A group of 2,154 students from 20 different institutions of public high school education answered a survey designed as an evaluation tool for a (...) career path or technology area of interest. The survey results show that students have a low preference for engineering careers. Moreover, these results were augmented with an additional study on the high attrition of students in engineering schools in the city of Mexicali, Baja California, also conducted by the authors. It raises the importance of teaching science in the early education levels, which aims to prepare scientists and technologists needed for the development of research and innovation as a foundation for economic prosperity and welfare of an emerging economy such as Mexico. (shrink)

Ethics in science is integrated into an interdisciplinary science course called “Science, Technology and Society” (STS). This paper focuses on the section of the course called “Societal Impact on Science and Technology”, which includes the topics Misconduct in Science, Scientific Freedom and Responsibility, and the Use of Human Subjects in Research. Students in the course become aware not only of the science itself, but also of the process of science, some aspects of the (...) history of science, the social responsibilities of scientists, and the ethical issues in science. Teaching techniques include the instructor sharing experiences as a scientist with the students, sharing books and resources with students, utilizing current sources of information like the weekly “Science Times”, inviting guest speakers, and utilizing portfolios to assess student learning. (shrink)

This paper discusses a way of introducing a scientific controversy, which emphasizes objective aspects of such issues as multiple theoretical interpretation of phenomena, choosing a theory, insistence on the chosen theory, and others. The goal is to give students a better insight into the workings of science and provide guidelines for building theories in their own research.

The change in the organization of science education over the past fifty years is quickly recalled. Being its cultural bound the lack of a conception of the foundation of science, the multiple innovations have resulted as temporary improvements without a clear direction, apart from the technocratic goal of an automation of learning processes. The discovery of two dichotomies as the foundations of science suggests a pluralist conception of science, and hence the need to entirely renew (...) class='Hi'>science education, in particular by introducing the notions of incommensurability and radical variations in meaning of the basic notions. This change was already anticipated by several proposals within each subject-matter. (shrink)

The paper describes the author's experience in using the history of science in teaching physics to science teachers. lt was found that history becomes more useful to teachers when explicitly combined with 'investigative' experimentation, which, in turn. can benefit from various uses of the history of science.

Interdisciplinary courses on science, engineering and society have been successfully established in two cases, at Bilkent University, Ankara, Turkey, and at the University of Hamburg, Germany. In both cases there were institutional and perceptual barriers that had to be overcome in the primarily disciplinary departments. The ingredients of success included a clear vision of interdisciplinary themes and didactics, and the exploitation of institutional opportunities. Haldun M. Ozaktas in Ankara used the dynamics of an accreditation process to establish courses on (...) engineering and society. At the University of Hamburg the introduction of optional courses into all curricula allowed for the establishment of a seminar series on physics and society, as well as on peace education and peace building. Both of these approaches have a weakness in common: the courses can disappear once their initiators have left, unless the interdisciplinary themes are integrated into compulsory core curricula. (shrink)

This paper provides arguments to philosophers, scientists, administrators and students for why science students should be instructed in a mandatory, custom-designed, interdisciplinary course in the philosophy of science. The argument begins by diagnosing that most science students are taught only conventional methodology: a fixed set of methods whose justification is rarely addressed. It proceeds by identifying seven benefits that scientists incur from going beyond these conventions and from acquiring abilities to analyse and evaluate justifications of scientific methods. (...) It concludes that teaching science students these skills makes them better scientists. Based on this argument, the paper then analyses the standard philosophy of science curriculum, and in particular its adequacy for teaching science students. It is argued that the standard curriculum on the one hand lacks important analytic tools relevant for going beyond conventional methodology—especially with respect to non-epistemic normative aspects of scientific practice—while on the other hand contains many topics and tools that are not relevant for the instruction of science students. Consequently, the optimal way of training science students in the analysis and evaluation of scientific methods requires a revision of the standard curriculum. Finally, the paper addresses five common characteristics of students taking such a course, which often clash with typical teaching approaches in philosophy. Strategies how best to deal with these constraints are offered for each of these characteristics. (shrink)

Case studies are increasingly used in the teaching of science. They are effective in the teaching of critical thinking skills because case studies place the subject matter in the context of a memorable story. Today there are case study repositories such as the National Center for Case Study Teaching in Science at the University at Buffalo with hundreds of cases and teaching notes and workshops to train faculty in their use. A new book is (...) in press, Science Stories: Using Case Studies to Teach Critical Thinking, which includes 37 cases for introductory science courses. Serious study of the effectiveness of the method is just beginning with several reports newly published or in progress. Future work needs to focus on the efficacy of the different case study approaches; a predictive model is presented that suggests that the most effective learning will come from those methods with the most student interaction. (shrink)

Starting from the traditional approaches to teaching science and religion we discuss modern pedagogical methods based on inquiry. We explore whether and how the teaching methods specific to each discipline may benefit in the teaching of the other.

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.

History, Philosophy and Science Teaching argues that science teaching and science teacher education can be improved if teachers know something of the history and philosophy of science and if these topics are included in the science curriculum. The history and philosophy of science have important roles in many of the theoretical issues that science educators need to address: the goals of science education; what constitutes an appropriate science curriculum for (...) all students; how science should be taught in traditional cultures; what integrated science is; how scientific literacy can be promoted; and the conflict which can occur between science curriculum and deep-seated religious or cultural values and knowledge. In part, answers to these questions hinge on views about the nature of science, views that are best informed by historical and philosophical study. Outlining the history of liberal, or contextual, approaches to the teaching of science, Michael Matthews elaborates contemporary curriculum developments that explicitly address questions about the nature and the history of science. He provides examples of classroom teaching and develops useful arguments on constructivism, multicultural science education and teacher education. The book will appeal to school and university science teachers, educators of science teachers, and historians and philosophers of science. (shrink)

Using humor, empathy, and improvisation to make science more accessible to the average person, the center has helped many scientists communicate more effectively about what they do. In many cases, this involves taking science down from the metaphorical “ivory tower” and bringing it into the comfort zone of students and people who may not have had a positive experience in science classes. A variety of metaphors are used to make science “come alive.” This is an interesting (...) counter example to earlier theories of metaphor and comedy such as the “disparagement theory” which described jokes as more successful if they relied on disparaging metaphors that build community through shared hostility. The metaphor approach builds community and creates inclusion through “social-facilitative functions of playful language”. When a scientist helps a layperson or student understand humorous metaphors, it communicates the literal meaning of terms, but also the contextual meaning, research practices, and the laboratory social setting. This is argued through examples of humor, comedy, and metaphor—a timely issue given current political discussions in the United States. (shrink)

The author has surveyed a quarter of the accredited undergraduate computer science programs in the United States. More than half of these programs offer a “social and ethical implications of computing” course taught by a computer science faculty member, and there appears to be a trend toward teaching ethics classes within computer science departments. Although the decision to create an “in house” computer ethics course may sometimes be a pragmatic response to pressure from the accreditation agency, (...) this paper argues that teaching ethics within a computer science department can provide students and faculty members with numerous benefits. The paper lists topics that can be covered in a computer ethics course and offers some practical suggestions for making the course successful. (shrink)