Gender inclusive Curricula: A focus on two responses

One of the requirements of the New Zealand Curriculum Framework (Ministry of Education, 1993a) is that all curricula developed in New Zealand must be gender inclusive. Developers of the recently released science curriculum, and the draft technology curriculum, have responded to this requirement in different ways. In this paper I discuss a theorisation of the term ‘gender inclusive’ within national curriculum development generally, and explore and analyse these different responses within the specific context of the science and technology curriculum developments. Particular emphasis is placed on the historical difference between science education and technology education in New Zealand schools, and on the impact theoretical discourses have on the way in which terms such as ‘gender inclusive curricula’ are conceptualised, and viewed as appropriate, or not, for specific purposes. Specializations: feminist theory, science education, technology education, technology curriculum development.     

Student perceptions of technology and implications for an empowering curriculum

Growing interest in technology education in 1988 led the Curriculum Development Division of the then New Zealand Department of Education to seek a survey of students' perceptions of technology using the internationally trialled Pupils' Attitudes Towards Technology (PATT) questionnaire. Early in 1989 a national sample of 1,469 form 3 students completed the questionnaire and responded to an open question about the nature of technology. Results indicated that students have generally positive attitudes towards technology, but poor concepts of technology. The nature of these attitudes and concepts and related factors have implications for the development of the National Curriculum Statement in Technology. Specializations: science and technology education, gender     

Science and technology management: Designing an undergraduate course

This research focusses on the role of science educators in preparing technically educated graduates for their careers. A comparison was made between the skills and abilities in science and technology students desired by industrial employers and whether New Zealand graduates exhibit these qualities. To address some of the management-based issues identified by the research, the design of a new Science and Technology Management course is outlined. Specializations: science and technology education, co-operative education, development of professional skills. Specializations: co-operative education programmes.     

新西兰职前技术教师教育框架述评及启示

开设适合的技术类课程以应对当前技术教育不断发展的新形势是师范院校亟待解决的关键问题。新西兰职前技术教师教育框架是奥克兰大学、梅西大学等六所高校共同开发的一个共享资源,旨在支持六所高校在职前技术教育方面保持信息一致,提升职前技术教师教育质量。该框架由技术哲学、技术教育的原理、技术课程和技术教学四个关键要素组成,在强调技术知识和技术教学知识的同时,关注技术价值观和目的观教育,并提供相应素材支持课程开发与实施。新西兰职前技术教师教育框架对我国技术教师教育具有重要启示。     

Adult experiences of science and technology in everyday life: Some educational implications

This paper outlines a project that is focussed on examining the complex ways in which adults experience science and technology in different areas of their everyday life including paid work, the home, health and leisure. The research has involved interviews with individual adults situated in a diverse range of life situations in New Zealand. A case study is presented to indicate the type of data being analysed and the implications emerging for education from the project. Specializations: science teacher education, science curriculum development, science and technology in society.     

Meeting the Global Challenge? Comparing Recent Initiatives in School Science and Technology

A comparison is made between two schemes in England and New Zealand--the technology colleges programme and the Science and Technology Teacher Fellowship scheme--designed to promote science and technology education in the two countries. Both schemes are placed within the context of recent developments in science and technology education in England and New Zealand and are evaluated as responses to the challenges posed for science and technology education by the forces of globalisation and the growing importance of the 'knowledge economy'.     

Teachers' perceptions of technology education: Implications for curriculum innovation

This paper describes research into teachers' perceptions of technology education carried out as part of the Learning in Technology Education Project. Thirty primary and secondary school teachers were interviewed. Secondary teachers interpreted technology education in terms of their subject subcultures as did some primary teachers. The primary teachers were also influenced by current initiatives, outside school interests and teaching programs. Specializations: investigations in science, science and technology education. Specializations: learning theories, history and philosophy of science, chemical education.     

The development of a K-3 science program in the context of the National Science Statement and Profile

This paper highlights the challenges and problems in developing an innovative K-3 science program to support teachers in the implementation of the national Statement and Profile in science. The program has been developed by the authors in association with the Curriculum Corporation. The paper outlines the assumptions made about teachers of young children, the role of research in the construction of the program, and the extent to which the Statement and Profile have influenced the process. The resolution of a number of key problems in this curriculum development is discussed: responding to teachers' needs for a base of science discipline knowledge, developing strategies for working scientifically with very young children, and helping teachers develop an extended understanding of the nature of science. Specializations: early childhood science and technology education. Specializations: primary science education, teacher education in science, adult experiences of science and technology, and curriculum development.     

Risk-taking and teachers' professional development: The case of satellite remote sensing in science education

The introduction of satellite remote sensing into the U. K. National Curriculum for Science, and the tasks facing teachers in bringing about this innovation, are discussed in terms of risk, its evaluation, reduction, and address. Conclusions are drawn about strategies by which teachers can confront the risk involved in curriculum innovation in school science and technology. Specializations: science and technology education     

Technology in the curriculum: A vehicle for the development of children's understanding of science concepts through problem solving

This research was carried out over a period of ten months with children in Grades 2 and 3 (aged 7 and 8) who were participating in a sequence of technology activities. Since the introduction into Victorian primary schools ofThe Technology Studies Framework P-10 (Crawford, 1988), more teachers are including technology studies in their classrooms and by so doing may assist children's understanding of science concepts. Children are being exposed to science phenomena related to the technology activities and Technology Studies may be a way of providing children with science experiences. ‘Technology Studies’ in this context refers to children carrying out practical problem solving tasks which can be completed without any particular scientific knowledge. Participation in the technology activities may encourage children to become actively involved, thereby facilitating an exploration of the related science concepts. The project identified the importance of challenge in relation to the children's involvement in the technology activities and the conference paper (available from the first author) discusses particular topics in terms of the balance between cognitive/metacognitive and affective influences (Baird et al., 1990) Specializations: science and technology education, interest and attitudinal change. Specialization: technology in the primary school.     

Towards an indigenous science curriculum

The recent development of a national science curriculum in Māori opened up space to contest whose knowledge and whose ways of knowing are included. This paper outlines the background to the curriculum development work in Aotearoa New Zealand with respect to the indigenous Māori people and science education. Concern is expressed about the fitting of one cultural framework into another and questions are raised about the approach used in the development of the science curriculum. Further research in the area of language, culture and science education is discussed along with how Māori might move forward in the endeavour of developing a curriculum that reflects Māori culture and language. This paper forms part of an MEd thesis. For a fuller analysis of the development of “Te Tauākī Marautanga Pūtaiao: He Tauira” (Draft National Science Curriculum in Māori) see McKinley (1995) in the references. See alsoSAMEpapers 1995 (Hamilton, New Zealand: Centre for Science, Mathematics and Technology Education, University of Waikato).     

Outcomes of the primary and early childhood science and technology education project at the university of Canberra

The aim of the Primary and Early Childhood Science and Technology Education Project (PECSTEP) is to improve teaching and learning in science and technology of by increasing the number of early childhood and primary teachers who are effective educators. PECSTEP is based on an interactive model of teaching and systematically links work on gender with the learning and teaching of science and technology. The project involves: a year-long inservice program which includes the development of a science curriculum unit by teachers in their schools; linking of the preservice and inservice programs; and the development of support networks for teachers. Each phase of PECSTEP has been researched by means of surveys, interviews and the use of diaries. Research questions have focussed particularly on changes in: teachers’ and student teachers’ attitudes to teaching science and technology; their perceptions of science and technology; their perceptions of their students’ responses and their understandings of how gender relates to these areas. Specializations: primary science curriculum, science teacher education, sociology of science, technology and education. Specializations: gender and science/science teacher education, feminist theory, curriculum theory. Specializations: Science education research, curriculum development.     

Comparison of personal and class forms of the science laboratory environment inventory

Existing instruments in classroom environment research have limitations when subgroups are investigated or case studies of individual students conducted. This study reports the validation and development of a personal form of the Science Laboratory Environment Inventory which is better suited to such studies. Further, systematic differences between scores on the class and personal forms of the instrument are reported along with comparisons of their associations with inquiry skill and attitudinal outcomes. Specializations: Science education, Preservice science teacher education. Specializations: Learning environments, science education, educational evaluation, curriculum. Specializations: Curriculum, science education, science laboratory teaching.     

How can we find out what 3 and 4 year olds think? New approaches to eliciting very young children's understandings in science

This paper outlines work in progress on a study which is investigating what children understand about natural and processed materials and how scientific learning on the topic could be extended and reinforced in the home. Four different interview schedules for eliciting children's understanding were developed and tried out. Children's understandings prior to each of the four units, and at the conclusion of the teaching program were documented through individual interviews. Family interviews were also conducted prior to and at the conclusion to the teaching. In this paper the difficulties associated with researching young children's thinking are explored. The rationale for a storytelling context for the interviews is presented, and there is a preliminary discussion on the effectiveness of the methodology utilised. Specializations: early childhood science education; the Curriculum Corporation K-3 Science Program. Specializations: primary science education, teacher education in science, adult experiences of science and technology; the K-3 Science Program.     

The technology-science relationship: Some curriculum implications

Technology encompasses the goods and services which people make and provide to meet human needs, and the processes and systems used for their development and delivery. Although technology and science are related, a distinction can be made between their purposes and outcomes. This paper considers four possible approaches to teaching students about the relationship between technology and science. Atechnology-as-illustration approach treats technology as if it were applied science; artefacts are presented to illustrate scientific principles. Acognitive-motivational approach also treats technology as applied science, but presents technology early in the instructional sequence in order to promote student interest and understanding. In anartefact approach, learners study artefacts as systems in order to understand the scientific principles which explain their workings. Finally, atechnology-as-process approach emphasises the role of technological capability; in this approach, scientific concepts do not have privileged status as a basis for selecting curriculum content. Specializations: science and technology education, educational evaluation, measurement of attitudes and interests.     

Relativism,Values and Morals in the New Zealand Curriculum Framework

The New Zealand Curriculum Framework, 1993, is the official document for teaching, learning and assessment in New Zealand schools. It consists of a set of curriculum statements, which define the learning principles, achievement aims and essential skills for seven learning areas. It also indicates the place of attitudes and values in the school curriculum. This paper investigates the requirements for teaching attitudes, values and ethics in the curriculum statements for Science, Biology and Technology. The question is raised whether the teaching of skills for resolving moral and ethical dilemmas are required by the official education standards in New Zealand, and internationally.The paper reports on a survey done on pre-service teacher trainees of their understanding of these requirements. Implications for courses that might need to be provided in future pre-service teacher education programmes are briefly discussed.     

Introducing technology education to young children: A design,make and appraise approach

The National Statement on Technology Education will soon be released in Australia. The statement advocates adesign,make andappraise approach to technology education. The document includes Year One children and provides exemplars of curriculum activities for early childhood children. Although much curriculum development in technology education for primary and early childhood has taken place in the UK, little research has been conducted within the early childhood area in Australia. This paper describes a study which sought to investigate how thedesign,make andappraise approach could be implemented within early childhood using existing materials, procedures and teaching programmes. In particular, the pre-school programme was considered to see if the approach was suitable for young children, and if girls could be encouraged into this newly defined area of study. Specializations: early childhood science education, early childhood technology education.     

Towards teaching science for social responsibility: An examination of flaws in science,technology and society

In this paper we continue our search for a socially responsible science education by an examination of the trends in the Science, Technology and Society movement. These trends reflect differing ideological perspectives and result in courses which serve different ends. We identify two major flaws in the movement that inhibits the realization of a schooling in science dedicated to democracy. We propose skills necessary for citizens to participate in debate over issues surrounding the impact of science and technology on society and a teaching stategy to help develop them. Specializations: social responsibility and the curriculum, ideology and comparative science education.     

Linking Science and Statistics: Curriculum Expectations in Three Countries

This paper focuses on the curriculum links between statistics and science that teachers need to understand and apply in order to be effective teachers of the two fields of study. Meaningful statistics does not exist without context and science is the context for this paper. Although curriculum documents differ from country to country, this paper uses extracts from three countries: Australia, New Zealand and the USA. The statistical ideas from the Australian Curriculum: Mathematics, the New Zealand Mathematics and Statistics Curriculum and the US Common Core State Standards for Mathematics are linked to the relevant parts of the Australian Curriculum: Science, the New Zealand Science Curriculum and the US Next Generation Science Standards for States, by States. Teachers of mathematics need to be aware of the potential of science to provide meaningful contexts within which to set statistical investigations. Similarly, teachers of science, who are developing methods for implementing investigations and experiments in their classrooms, need to be aware of the close ties to statistical tools for decision-making.     

History,philosophy and science teaching: Current british,American and Australian developments

The history and philosophy of science components of the new British National Curriculum, and the American Association for the Advancement of Science Project 2061 curriculum guidelines are described. Some curriculum background is given to these developments; and a contemporary international project concerned with the utilization of the history and philosophy of science in science teaching and teacher education is also described. Finally the recent Discipline Review of the Training of Science and Mathematics Teachers in Australia is examined and criticised for its lack of recommendations about the need for appropriate history and philosophy of science courses to be included in science teacher education programmes. Specializations: history and philosophy of science, philosophy of education.