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1.
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.  相似文献   

2.
The term ‘concept’ is used in different ways within educational literature and has at least two different, although related, referents in relation to science knowledge, namely, public knowledge and private understandings. A taxonomic structure for ‘science concepts’ (public knowledge) has been developed to provide a rationale for the choice of phenomena to be used in the investigation of students’ ‘concepts’ and also to act as a frame of reference for generating insights about the data to be collected. Furthermore, it may be a useful heuristic to predict other science concepts likely to be highly problematic in school teaching situations and thus worthy of detailed research. The taxonomy, called a ‘Scale of Empirical Distance’ (SED), enables science concepts to be mapped according to their degree of closeness to concrete realities. The scale shows a recognition of the empirical basis of science concepts and the role of human senses in the perception of the material world even though “absolute objectivity of observation is not a possible ideal of science” as Harre (1972) has noted. The scale uses two binary variables, namely, ‘visual’ and ‘tactile’, to generate four categories of science concepts ranging on a continuum from concrete to abstract. Some concepts related to ‘matter’ will be classified and discussed. Specializations: science teacher education, primary science curriculum and methods, students’ personal meanings of phenomena.  相似文献   

3.
Unattended science and technology exhibits of both static and operational types have been an integral part of museum displays for many years. More recently interactive exhibits in which observers are encouraged to become part of the system of exhibits have become more common. A study was commenced to explore the impact and potential of low cost, unattended, interactive exhibitsset up singly in a normal school classroom without the distractions of a multiplicity of activities as is common in ‘science museums’. Three small groups of Grade 5/6 primary school children interacted with a ‘Falling Towers’ exhibit and their voluntary activities were recorded on videotape for later analysis. Children appeared to state the results of their activity in ways consistent with their expectations rather than with their most recent experience with the exhibit. The responses of girls, boys and mixed groups are reported. Specializations: primary mathematics and science education, teaching strategies. Specializations: science education, students' understandings of phenomena in science.  相似文献   

4.
Conclusion In the papers presented one can detect a number of major areas of concern. The theorists like Shayer are largely concerned with the development and refinement of frameworks for studying cognitive development. Their ultimate purposes varied from reconstructing the entire field of science education, to accelerating cognitive development, to changing the ‘alternative frameworks’ of children. In essence, they seek totailor the teaching-learning process in accordance with a theoretical blue print. Those who see the problems as more content and context specific would prefer to chip away at particular topics which create teaching difficulties, thereby contributing to the improvement of practice in a more direct, piecemeal fashion. They could perhaps be described astinkers. So we havetinkers andtailors. Thesoldiers amongst us would equip teachers with the weapons needed to attack their own problems directly. They are working away at developing techniques Oh yes, thespies are the moles like me who are concerned with uncovering the secrets of classroom life, with identifying the structures, patterns and processes which characterise classroom interaction, and with the describing and monitoring the ‘theories in action’ and strategies which skilled practitioners have evolved to cope with the problems of promoting cognitive development in classroom settings. The ultimate question then, is what contribution can the tinkers, tailors, soldiers and spies make to science education?  相似文献   

5.
This paper reports an investigation into gender, ethnicity and rurality on Fijian students’ perceptions of science. A questionnaire was administered to a large sample of Form 5 classes. All students had completed a four year integrated "Basic Science" course in the junior secondary school and were continuing their studies in the upper secondary school. The responses were analysed to determine the significance of gender, ethnicity and rurality on the students’ perceptions of science, attitudes to science in the world and to science in the school curriculum. Specializations: gender issues and affective aspects of science and technology education. Specializations: Constructivism in science education, development education and gender issues.  相似文献   

6.
The attitude towards science of first year early childhood education students was explored using an instrument developed for the purpose. The instrument comprises four Likert-type scales, biographical items and two open-ended attitude items. The four scales, characterised as ‘confidence’, ‘enjoyment’, ‘usefulness’ and ‘appropriateness of science for young children’, were supported by varimax factor analysis and had reliabilities from 0.83 to 0.88. Use of the combined scales as a general ‘attitude towards science’ scale was supported by principal components analysis; reliability for the combined scale was 0.94. Comments made in response to the open-ended items supported the validity of the scales. For the student group as a whole, mean scores on all scales were slightly to moderately positive, with the highest mean being for the ‘science for young children’ scale. Students who had studied at least one science subject at Year 12 level had significantly higher scores on all scales than students who had not studied science at senior level. Australia.Specializations: early childhood science education, biological aspects of child development, conservation biology of gulls.  相似文献   

7.
Routines are a fundamental aspect of classroom life and much attention in recent years has focused on routines for management. The concept of ‘behaviour settings’ and transitions between them as classroom routines is explained and exemplified. This view of routines provides an explanation for the difficulties faced by relieving teachers and student teachers who enter classrooms at mid year and suggests how new routines for complex science activity may be introduced. Specializations: Science curriculum science teacher education, teacher  相似文献   

8.
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9.
This paper reports on research into two teachers' views and practices about assessment at the classroom level. Emphasis was given to practical work and its assessment. Findings suggest it is unhelpful to define practical work as distinct from other activities in the science classroom. Various methods used for assessing activity within the participant teachers' classrooms are described. The participant teachers were found to be primarily concerned about issues of ‘fairness’: task validity, reliability of assessment based on co-operative work and assessment of the affective domain. The place of teacher intuition in assessment is raised and briefly discussed. Directions for the ongoing research are foreshadowed. Specializations: science education, technology education, assessment and curriculum development.  相似文献   

10.
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.  相似文献   

11.
A study of primary school children's explanations of a range of phenomena concerning air pressure revealed considerable fluidity in their use of conceptions. A measure of consistency was developed and applied to children's written and oral explanations in a range of contexts. While the results showed a general trend with age toward more abstract, ‘generalizable’ conceptions, the notion of parsimony was found to be problematic on a number of levels. Children do not apply a single conception to a phenomenon, but rather operate with multiple conceptions in their explanations, complicating the whole notion of consistency. Moreover, as they develop and apply more advanced conceptions, children inevitably display temporary reductions in consistency. These findings suggest a rather more complex model of conceptual advance than implied in the literature on ‘conceptual change’. Specializations: children's science explanations, conceptual change, primary science teacher education, physics education.  相似文献   

12.
New Zealand has had a national school science curriculum for more than 80 years. In the past the evolution content of this document has varied, and has at times been strongly influenced by creationist lobby groups. The ‘new’ science curriculum, to be fully implemented in 2010, places much greater emphasis than before on understanding evolution, and also on teaching the nature of science. Interplay between the two can potentially improve student understanding of the culture and processes of science in general and evolutionary theory in particular. While the explicit use of the word ‘evolution’ highlights its significance, it is necessary to provide both resources and pedagogical guidelines to support teachers in dealing with this important topic.  相似文献   

13.
This paper describes an ongoing process of participatory curriculum development. It outlines some of the tensions which need to be explored in science curriculum development: debates about the nature of science, of society, of school science content and of learning theories. The process whereby action can arise from this debate is also explored. An example will be outlined of a network of science curriculum action which has developed from the work of a range of science education projects in Natal, South Africa. Specializations: science curriculum development from primary to tertiary level. Specializations: inservice primary science teacher development. Specializations: inservice teacher development, biology education. Specializations: environmental education, teacher development. Specializations: environmental education, teacher development.  相似文献   

14.
I know about lisp but how do i put it into practice?   总被引:1,自引:0,他引:1  
This paper outlines some initial findings of the Learning in Science Project (Teacher Development) on the process of teacher development with respect to implementing the findings of the previous Learning in Science Projects. The findings on course components, the ‘pay-offs’ for the teachers, reflection and support for the change process are discussed as are the implications of these for further research. Specialisations: learning theories, curriculum development, equity issues, teacher development. Specialisations: Teachers' knowledge, life histories.  相似文献   

15.
Existing instruments for assessing student or teacher perceptions of characteristics of actual or preferred classroom psychosocial environment are unsuitable for one of the most important settings in science teaching, namely, the science laboratory class. Consequently, the Science Laboratory Environment Inventory (SLEI), was designed to assess student or teacher perceptions of seven scales:Teacher Supportiveness, Student Cohesiveness, Open-Endedness, Integration, Organization, Rule Clarity andMaterial Environment. An important feature of the design of the study was that the new instrument was field tested simultaneously in six countries: Australia, USA, Canada, England, Nigeria and Israel. This paper is based on a sample of 4643 students in 225 individual laboratory classes, together with the teachers of most of these classes. Preliminary analyses were used to shed light on various important research questions including the differences between Actual and Preferred environments, gender differences in perceptions of Actual and Preferred environment, the relationship between the science laboratory environment and attitude towards science laboratory work, differences between school and university laboratory classes, differences between teachers’ and students’ perceptions of the same laboratory classes, and differences between laboratory classes in different science subjects (Physics, Chemistry, Biology). Specializations: Science education, educational evaluation. Specializations: Curriculum, science education, science laboratory teaching. Specializations: Learning environments, science education, educational evaluation, curriculum.  相似文献   

16.
Advocates of constructivist science recommend that school science begins with children’s own constructions of reality. This notion of the way in which students’ knowledge of science grows is closely paralleled by recent research on teachers’ knowledge. This paper draws on case study evidence of teachers’ work to show how two experienced teachers’ attempts to develop alternative ways of teaching science involved reframing their previous patterns of understanding and practice. Two alternative interpretations of the case study evidence are offered. One interpretation, which focuses on identifying gaps in the teachers’ knowledge of science teaching, leads to theconstructivist paradox. The second interpretation explores theconstructivist parallel, an approach which treats the process of teachers’ knowledge growth with the same respect as constructivists treat students’ learning of science. This approach, the authors argue, is not only more epistemologically consistent but also opens up the possibilities of helping teachers lead students towards a constructivist school science. Specializations: Teachers’ knowledge and culture, educational change, qualitative research methodology. Specializations: Teachers’ knowledge, imagery and teachers’ work, teacher collegiality, supervision of teachers’ work.  相似文献   

17.
The general aim of our human nutrition project is to develop a health education model grounded in ‘everyday’ or ‘situated’ cognition (Hennessey, 1993). In 1993, we began pilot work to document adult understanding of human nutrition. We used a HyperCard stack as the basis for a series of interviews with 50 adults (25 university students, and 25 adults from offcampus). The interviews were transcribed and analysed using the NUDIST computer program. A summary of the views of these 50 adults on selected aspects of human nutrition is presented in this paper. Specializations: educational technology and the teaching-learning process, public understanding of science and technology. Specializations: educational technology, mathematics education.  相似文献   

18.
‘Thinking schools’ will be sites of learning for everyone declared the Singapore Prime Minister, Goh Chok and Minister of Education Teo Chee Hean’s in 1997 also spoke on the model of’ ‘thinking schools, learning nation’. Gardner’s model was used for the thinking school model in Singapore, in order to develop critical and creative thinking in students. This was to be done with the use of instructional technology as an enabling tool using a diversity of approaches including integrated project work. This paper reports on how one school went about changing approaches to teaching and learning by implementing integrated project work as a way of integrating the content areas of the curriculum, mathematics and science through English language, supported by the tools of instructional technology.  相似文献   

19.
As there is nothing as practical as a good theory, there is a continuing need in the field of science education enquiry to look for theories which help to interpret the findings about students' alternative frameworks and to inform the design of teaching strategies which relate to a research focus on ‘how the student learns’. The developmental model of cognitive functioning based on the SOLO Taxonomy (Biggs & Collis, 1982) as updated in 1991 (Biggs & Collis, 1991; Collis & Biggs, 1991) is being applied in this way. Questionnaire data from two large studies of science learning of Australian students (conducted by ACER and NBEET) are being re-analysed in terms of the current theory. This paper illustrates the theory and describes a plan of further research. Specializations: science education, students' understandings of phenomena in science. Specializations: cognitive development, evaluation, mathematics and science education. Specializations: mathematics education, students' understanding of chance and data concepts.  相似文献   

20.
This study explored the effects that the incorporation of nature of science (NoS) activities in the primary science classroom had on children’s perceptions and understanding of science. We compared children’s ideas in four classes by inviting them to talk, draw and write about what science meant to them: two of the classes were taught by ‘NoS’ teachers who had completed an elective nature of science (NoS) course in the final year of their Bachelor of Education (B.Ed) degree. The ‘non-NoS’ teachers who did not attend this course taught the other two classes. All four teachers had graduated from the same initial teacher education institution with similar teaching grades and all had carried out the same science methods course during their B.Ed programme. We found that children taught by the teachers who had been NoS-trained developed more elaborate notions of nature of science, as might be expected. More importantly, their reflections on science and their science lessons evidenced a more in-depth and sophisticated articulation of the scientific process in terms of scientists “trying their best” and “sometimes getting it wrong” as well as “getting different answers”. Unlike children from non-NoS classes, those who had engaged in and reflected on NoS activities talked about their own science lessons in the sense of ‘doing science’. These children also expressed more positive attitudes about their science lessons than those from non-NoS classes. We therefore suggest that there is added value in including NoS activities in the primary science curriculum in that they seem to help children make sense of science and the scientific process, which could lead to improved attitudes towards school science. We argue that as opposed to considering the relevance of school science only in terms of children’s experience, relevance should include relevance to the world of science, and NoS activities can help children to link school science to science itself.  相似文献   

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