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1.
Mr. Peter Aubusson Associate Professor Joe Relich Mr. Dan Wotherspoon 《Research in Science Education》1991,21(1):10-19
About 100 science teachers in the Sydney Metropolitan West Region were surveyed to determine their professional development
needs and the ways in which these needs could be met. The findings provide a ranking of science teacher perceived professional
development needs, a list of possible incentives to motivate science teachers to complete inservice programs (in priority
order) and an indication of the preferred modes of presentation to meet professional development needs. In general, science
teachers stated a preference for professional development related to modern trends in science education directly related to
classroom practice. In contrast to recommendations from DEET, science teachers indicated a preference for traditional models
of inservice. Data related to preferred mode of inservice indicated significant gender differences.
Specializations: science teacher professional development.
Specializations: educational psychology and research design.
Specialization: constructivist approaches in science education. 相似文献
2.
Post-primary science teachers in Victoria were asked to express views about primary science curriculum design and implementation.
They were also asked about the value of continuity between primary and post-primary science education. The post-primary teachers
generally had favourable attitudes to primary science education and considered that cooperation would be useful-though it
is not common at the moment. However, the data revealed a considerable range of opinion. Post-primary science teachers' views
about primary science curriculum are similar to those of primary teachers themselves, but many post-primary teachers would
place more emphasis on formal or textbook knowledge. Post-primary teachers see a number of systemic problems in implementing
primary science education but their positive perceptions suggest the value of encouraging more structured links. The notion
of continuity across the two sectors was well supported.
Specializations: science education policy and practice, teacher education, school effectiveness.
Specializations: science education, teacher education in science. 相似文献
3.
Dr J. R. Baird Associate Professor R. F. Gunstone Mr C. Penna Professor P. J. Fensham Professor R. T. White 《Research in Science Education》1990,20(1):11-20
This paper is based on findings from a three year collaborative action research project on classroom teaching and learning.
The research, which involved 33 teachers, over two thousand students from six schools, and the authors, centred on exploring
how various features of the classroom context influence teaching and learning processes. We interpret project findings as
indicating the importance of balance between cognition and affect for effective teaching and learning. We advance the notion
of challenge as a way of conceptualising this balance. Challenge comprises a cognitive/metacognitivedemand component and an affectiveinterest component. Nine major features of a teaching/learning event were found to interact to influence these cognitive and affective
components of challenge.
Specializations: Collaborative research on science teaching and learning; staff development and school improvement; quality of science education.
Specializations: Learning and teaching science; pre-service teacher education.
Specializations: teacher development in science education; technology education.
Specializations: Science and teachnology curriculum, environmental education, educational disadvantage.
Specializations: learning theory, probing of understanding, conceptual change. 相似文献
4.
Carmel McNaught Dianne Raubenheimer Margaret Keogh Rob O'Donoghue Jim Taylor 《Research in Science Education》1992,22(1):291-298
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
5.
Towards a theoretical basis for students' alternative frameworks in science and for science teaching 总被引:1,自引:0,他引:1
Dr Brian L. Jones Professor Kevin F. Collis Dr Jane M. Watson 《Research in Science Education》1993,23(1):126-135
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
6.
Professor Dr. Reinders Duit Professor Dr. Peter Häussler Dr. Roland Lauterbach Professor Dr. Helmut Mikelskis Professor Dr. Walter Westphal 《Research in Science Education》1992,22(1):106-113
This paper outlines the design of a physics textbook that addresses issues of gender-inclusive physics teaching, STS and constructivism.
Difficulties of addressing these issues in a textbook for normal classes, which has to compete with other textbooks on the
market will be discussed.
Specializations: constructivist approaches in science education research and practice.
Specializations: gender issues in science instruction.
Specializations: primary education, integrated science.
Specializations: STS, phenomenological oriented physics instruction.
Specializations: peace education within science education. 相似文献
7.
This paper examines the ideology of one the best known figures in science education in the USA, and draws attention to the
relationship between the political climate and curriculum in national curriculum developments. We are mindful of the forces
shaping the schooling of science in Australia, and we present this analysis as an example of the social forces that dominate
education both here and overseas. Paramount is our desire to open the door for a socially responsible Australian school science
experience.
Social Responsibility of Science in Science Education Group.Specializations: sociology of science education, the nature of science and the production of scientific knowledge, comparative science education
and environmental education.
Social Responsibility of Science in Science Education Group.Specializations: comparative education with particular reference to China, the nature of science and the production of scientific knowledge. 相似文献
8.
Conclusion This study suggests that most students entering science or science education units in preservice primary teacher education
courses have a positive attitude to the teaching/learning of primary science and see value in all domains of science for children
at this stage. This was an unexpected finding. It was of concern however, that their interest in physical science topics was
so low. This may be due to previous specific experiences in secondary science. Science and science education units should
build on the positive attitudes of students and could develop physical science ideas through their significance in environmental
and social problems.
Specializations: science education, teacher education in science.
Specializations: science education policy and practice, teacher education, school effectiveness. 相似文献
9.
This paper reports an empirical study of science education in Australian primary schools. The data show that, while funding
is seen as a major determinant of what is taught and how it is taught, teacher-confidence and teacher-knowledge are also important
variables. Teachers are most confident with topics drawn from the biological sciences, particularly things to do with plants.
With this exception there is no shared body of science education knowledge that could be used to develop a curriculum for
science education. There was evidence that most teachers see a need for a hands-on approach to primary science education involving
the use of concrete materials. A substantial proportion of teachers agree that some of the problems would be alleviated by
having a set course together with simple, prepared kits containing sample learning experiences. Any such materials must make
provision for individual teachers to capitalise on critical teaching incidents as they arise and must not undermine the professional
pride that teachers have in their work.
Specializations: science education, school effectiveness, teacher education
Specializations: science education, teacher education in science 相似文献
10.
This paper is based on interviews with seventy-five science teachers in twelve schools across Australia. The interviews were
conducted as part of a D.E.E.T. Project of National Significance. The purpose of the project was to develop a strategy for
the professional development of science teachers. The main purpose of our interviews was to listen to teachers' views on what
such a strategy should try to achieve. We asked them to talk about conditions affecting the quality of their work, their attitudes
to teaching, their professional development, their careers, the evaluation of teaching, and Award Restructuring. Through these
interviews we came to understand how many science teachers are loosely connected with potentially valuable sources of support
for their professional development. In this paper we focus on one group of “loose connections”; those between science teachers
and scientists in other fields, research in science education, and their colleagues within science departments in schools.
Specializations: Science education, reflective practice, teaching and learning.
Specializations: Professional development, educational evaluation. 相似文献
11.
The potential of informal sources of science learning to supplement and interact with formal classroom science is receiving
increasing recognition and attention in the research literature. In this study, a phenomenographic approach was used to determine
changes in levels of understanding of 27 grade 7 primary school children as a result of a visit to an interactive science
centre. The results showed that most students did change their levels of understanding of aspects of the concept “sound”.
The study also provides information which will be of assistance to teachers on the levels of understanding displayed by students
on this concept.
Specializations: informal science learning, science curriculum
Specializations: science education, science teacher education, conceptual change, learning environments. 相似文献
12.
Intuition was one of the four key themes for science education that emerged from the Woods Hole Conference in 1957. Despite
the considerable influence of this conference on a generation of curriculum projects the intuition theme was almost completely
ignored. Recent studies of intuition, including an analysis of Nobel laureates' views of scientific intuition, are considered.
This enables several conceptions of the nature and role of intuition in science to be defined, and its importance to be assessed.
The assumption that it is also important in science education is examined by considering conditions in science teaching and
learning that may encourage intuitive thinking in the light of current research developments that could lead to a new agenda
for school science.
Specializations: science and technology curriculum, environmental education, educational disadvantage.
Specializations: phenomenography, ways of knowing, higher education—teaching and learning. 相似文献
13.
Dr. Campbell J. McRobbie Dr. Barry J. Fraser Dr. Geoffrey J. Giddings 《Research in Science Education》1991,21(1):244-252
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. 相似文献
14.
This paper relates to a study commissioned by the Department of Employment, Education and Training to evaluate the impact
of the Discipline Review of Teacher Education in Mathematics and Science. The major datagathering strategies employed in that
study have been to visit every higher education institution in Australia involved in teacher education to interview relevant
staff and to seek information by mail from other bodies to whom recommendations of the Review were addressed. This paper reports
a supplementary activity, the analysis of citations of the Report of the Discipline Review in the journal of the Australasian
Science Education Research Association,Research in Science Education. This research reveals that there has been relatively little critical analysis of the Review, somewhat surprising in the
light of its significance for science teacher education. Further the citations in the journal suggest that the Review Report
has struck a responsive chord with those involved in the science education of primary school teachers. Its impact on secondary
teacher education would appear to be less significant. This difference is explored in the context of professional education.
Specializations: science education, teacher education.
Specializations: international education, educational measurement, science education. 相似文献
15.
Conclusion Currently the 26 films in the Science Territory series have been shown to audiences who watch Channel 8 commercial television
in the vicinity of Darwin. They are still being shown to audienc who watch Imparja Television. There are no plans at the moment
to shown Science Territory for any extra time on either Channel 8 or Imparja, once the Imparja programmes are completes. There
are plans however to develop materials to complement the programmes, which could be used in schools and there are also plans
to repeat the success of Science Territory and to expand it on a national basis to a series of programmes to be called “Science
Oz”.
This research note has described of the Scienc Territory project which has attempted to improve students' and parents' attitudes
to science. It has alo attempted to explain how the issue of determining the effectiveness of the project has been addressed.
Overall, Science Territory proved to be an interesting, exciting, successful and whorthwhile venture, particularly for the
small scientific community of the Northern Territory. It also appears to be unique both in Australia and worldwide. There
are therefore lessons that science educators can learn from this about new ways of improving students' attitudes to science.
Specializations: Science education policy, curriculum development and science education development projects with industry.
Specializations: Science teacher education, chemical education, science education in developing countries, educational Issues. 相似文献
16.
Alison Grindrod Andrea Klindworth Dr. Marjory-Dore Martin Russell Tytler 《Research in Science Education》1991,21(1):151-160
In 1990, a large proportion of third year primary trainee teachers at Victoria College had observed or taught very few or
no science lessons during the first two years of their course. The students felt that a lack of content knowledge, a crowded
school curriculum, and problems associated with managing resources and equipment, were the main factors contributing to the
low level of science being taught in schools. By the end of their third year significantly more students had taught science
than after the second year. There was also a change in approach to teaching science with more practical activities being included
than previously. The science method unit taught to the students in the third year of their course contributed to this increase.
The students considered the hands-on activities in class to have been the most effective aspect of the unit in their preparation
for the teaching of primary science.
Specializations: children's learning in science, primary teacher education.
Specializations: student understanding of biology, evaluation of formal and informal educational settings.
Specializations: gender, science and technology, environmental education.
Specializations: children's learning in science, language and science. 相似文献
17.
Peter Aubusson 《Research in Science Education》1994,24(1):21-30
This paper reports on a study of the mismatch between science teachers' stated purposes and their actual teaching of science
in a secondary school. Factors affecting teachers' practices include their personal beliefs about teaching, learning and the
purposes of science education, the school program and the school culture.
Specializations: science and technology education, professional development. 相似文献
18.
Dr Campbell J. McRobbie Dr Geoffrey J. Giddings Dr Barry J. Fraser 《Research in Science Education》1990,20(1):200-209
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
19.
Constructivist views of learning have been applied to science education largely as a response to attempts to understand the
origins of students' misconceptions in science, and therefore the learning process. As part of this effort to understand learning
in science lessons, Appleton (1989) proposed a learning model drawn mainly from Piagetian (1978) ideas and generative learning
theory (Osborne & Wittrock, 1983). This paper explores the development and evolution of the learning model as other constructivist
view were applied, and as the model was tested against students' responses in science lessons. The revised model finally arrived
at is then examined. It was found to be a useful means of describing student's learning processes during a science lesson.
Specializations: primary teacher education, teaching strategies in science, cognitive change and learning theories.
Specializations: secondary science teacher education, chemical education. 相似文献
20.
Olugbemiro J. Jegede James C. Taylor Peter Akinsola Okebukola 《Research in Science Education》1991,21(1):198-207
Most of the curriculum design models within the technical-scientific approach utilise the rational and sequential process
of designing and inter-relating the various elements of the design process. While this procedure may be efficient and adequate
for conventional education in which the designers are professional science educators, there is doubt if it satisfies the particular
needs of distance education.
The experience accumulated through a multi-disciplinary team approach to distance learning courseware development for higher
education at the University of Southern Queensland Distance Education Centre motivated this study which primarily focused
on a search for an alternative approach to curriculum development with a more satisfactory functional value.
Using selected units in Engineering as a focus, an experiment was designed in which a variant of the classical Wheeler model
was used. This paper reports the results of this experiment. The implications for contemporary curriculum development initiatives
in science especially within distance education settings are pointed out.
Specializations: science education, learning strategies, curriculum development, instructional design, research and development in distance
education.
Specializations: Cognitive Science, curriculum development, instructional design, expert systems, research and development in distance education.
Specializations: science education, learning strategies, curriculum development, instructional design, research and development in distance
education. 相似文献