The aim of this paper is to examine the current state of development of Mäori science curriculum policy, and the roles that various discourses have played in shaping these developments. These discussions provide a background for suggestions about a possible future direction, and the presentation of a new concept for Mäori science education.

The aim of this paper is to examine the current state of development of Mäori science curriculum policy, and the roles that various discourses have played in shaping these developments. These discussions provide a background for suggestions about a possible future direction, and the presentation of a new concept for Mäori science education (note that in this paper this phrase refers to science that incorporates Mäori language and/or knowledge, rather than Mäori participation in science education).

Science and technology have significant roles in life. Most of the researches and discussions about science education are related to development of sciencecurriculum and science education in school. Science curriculum must be developed based on student and society needs, scientific and technological developments in the field of science and educational science. The aims of science curriculum should reflect these elements given above. The aims of science curriculum also refer to (...) changing philosophy of education. In this study, the results of the two studies, which were conducted with 314 primary school class teachers and science teachers, and literature reviews are discussed under the heading of "Future aims of science curriculum for primary school”. (shrink)

This paper describes the author’s experience of infusing an introductory database course with privacy content, and the on-going project entitled Integrating Ethics Into the Database Curriculum, that evolved from that experience. The project, which has received funding from the National Science Foundation, involves the creation of a set of privacy modules that can be implemented systematically by database educators throughout the database design thread of an undergraduate course.

The article focuses on the analysis of curriculum documents from Taiwan to investigate how benchmarks for learning nature of science are positioned in different versions of the science curricula. Following a review of different approaches to the conceptualization of NOS and the role of NOS in promoting scientific literacy, an empirical study is reported to illustrate how the science curriculum documents represent different aspects of NOS. The article uses the family resemblance approach as the account (...) of NOS and adapts it for analysis of the curriculum documents. The FRA defines NOS as cognitive-epistemic and social-institutional systems that serve as constructs of knowledge categories with a high level of interconnectedness. The FRA was used as an analytical tool for investigating two sets of Taiwanese curriculum guidelines published 10 years apart, providing an opportunity to discuss how NOS is addressed in the curriculum reforms. The findings show a shift away from the excessive centralization of the cognitive-epistemic system to a consideration of the social-institutional system. Modifications to the benchmarks are proposed in order to achieve a more holistic and progressive approach to NOS. The article contributes to studies on NOS in science education by illustrating how the FRA can act as a tool for exploring interconnectedness of NOS ideas in the curriculum. (shrink)

This paper comments on the process of re-development of the Maori-medium Science (Pūtaiao) curriculum, as part of overall curriculum development in Aotearoa New Zealand. A significant difference from the English Science curriculum was the addition of an ‘extra strand’ covering the history and philosophy of science. It is recommended that this strand be taught by means of narratives (i.e. using ‘narrative pedagogy’) in order to avoid a superficial didacticism that succumbs to the traditional notion (...) of science curriculum content as ‘merely factual’ in nature. An argument is presented for the ethical necessity of including this extra material in Māori science education. (shrink)

Feminist educators and theorists are stretching the boundaries of what it means to do religion and science. They are also expanding the theoretical and practical frameworks through which we might present curricula in thosefields. In this paper, I reflect on the implications of feminist pedagogies for the interdisciplinary field of religion and science. I begin with a brief discussion of feminist approaches to education and the nature of the feminist classroom as a setting for action. Next, I present (...) some theoretical and practical issues to consider when developing a feminist praxis and an antisexist curriculum. This leads into a discussion of the role of language and critical reflection in the religion and science classroom, the risks associated with reflective discourse, and considerations in the use of ‘feminist’ teaching tools such as small group work, journals, and portfolio assessment. Iconclude with a reflection on how feminist pedagogy promotes an epistemology that speaks to the hearts and minds of participants in the dialogue of religion and science. (shrink)

This paper presents the results of a survey of students majoring in STEM fields whose education contained a significant history, philosophy and sociology of science component. The survey was administered to students in a North American public 4-year university just prior to completing their HPS sequence. The survey assessed students’ attitudes towards HPS to gauge how those attitudes changed over the course of their college careers, and to identify the benefits and obstacles to studying HPS as a component of (...) their STEM education. The survey reveals that students generally found unexpected value in taking HPS within their STEM curriculum. It also reveals that framing HPS courses as a means of gaining communication skills necessary to be an influential scientist seems to resonate with students. However, students also identified several factors limiting engagement with HPS content, including the length and density of required readings and assessment via essays and papers. (shrink)

This paper describes the major components of ImpactCS, a program to develop strategies and curriculum materials for integrating social and ethical considerations into the computer science curriculum. It presents, in particular, the content recommendations of a subcommittee of ImpactCS; and it illustrates the interdisciplinary nature of the field, drawing upon concepts from computer science, sociology, philosophy, psychology, history and economics.

The infusion of environmental topics in science courses has long been considered an especially appropriate method of implementing the STS approach to science teaching. While this claim has been supported by anecdotal accounts and case studies, there are few relevant quantitative studies. To begin filling this void, a survey of science teachers in secondary schools in Dade County, Florida, was conducted to investigate the extent and effectiveness of the infusion of environmental topics in the science (...) class='Hi'>curriculum. The results of this study indicate that the responding science teachers are very likely to incorporate environmental topics in their science classes. They do this regardless of their length of tenure, and most have engaged in the practice from the beginning of their careers. Finally, while the experience of a teacher in using environmental topics has some positive effect in increasing student interest, the success of this method depends much more strongly on the frequency of its use. Those teachers routinely using environmental topics as a vehicle for teaching science are most successful with it. (shrink)

Technological developments affect and disturb all aspects of human existence and values more than any other factor in our modern man-made world. This calls for responsive higher education which will produce better decision-makers capable of being actively, rationally, and creatively involved in the continuous search for solutions to our current and future problems in a world of conflicting interests and values. Consequently, science teaching in future higher education should be drastically changed in order to be relevant to needs of (...) both students and society rather than to reflect the needs of the disciplines per se. (shrink)

Traditional methods of instruction can fail to produce enduring ways of learning, especially in rapidly changing disciplines in the life sciences. Educators and funding agencies are thus calling for new, integrated teaching approaches to address the life sciences. Hierarchical frameworks are being proposed as ways to tackle curricula with large numbers of concepts. Comparing lecture‐based and interactive formats by measuring performance with pre‐ and post‐tests indicated significantly higher learning gains and better conceptual understanding in the more interactive course. Other work (...) has examined how the history of biology can be used to infuse relevance into the biology curriculum. In this paper, I describe a project at Stanford to create, implement, and evaluate an integrated curriculum in undergraduate stem cell education comprised of scientific, laboratory, and ELSI topics. (shrink)

This second research paper on science education in Māori‐medium school contexts complements an earlier article published in this journal (Stewart, 2005). Science and science education are related domains in society and in state schooling in which there have always been particularly large discrepancies in participation and achievement by Māori. In 1995 a Kaupapa Māori analysis of this situation challenged New Zealand science education academics to deal with ‘the Māori crisis’ within science education. Recent NCEA results (...) suggest Pūtaiao (Māori‐medium Science) education, for which a national curriculum statement was published in 1996, has so far increased, rather than decreased, the level of inequity for Māori students in science education. What specific issues impact on this lack of success, which contrasts with the overall success of Kura Kaupapa Māori, and how might policy frameworks and operational systems of Pūtaiao need to change, if better achievement in science education for Māori‐medium students is the goal? A pathway towards further research and development in this area is suggested. (shrink)