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1.
Dr Denis Goodrum MS Judith Cousins Dr Adrianne Kinnear 《Research in Science Education》1992,22(1):163-169
The study attempts to identify the factors which affect teacher's reluctance to teach science, then explains an approach to
help teachers teach science in a worthwhile manner over the school year while monitoring any changes in their confidence and
competence. It was found that the condidence and competence of the teachers improved during the year such that they were able
to teach successful science lessons on a regular basis.
Specializations: primary science and technology education, curriculum development and implementation, teacher education.
Specializations: primary science curriculum, early childhood education, gender and science.
Specializations: primary science and technology education, issues related to girls in science and technology. 相似文献
2.
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
3.
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
4.
DR. Paul Gardner 《Research in Science Education》1992,22(1):140-148
The notion that technology is the application of science to the making of artefacts is a widely-held, persistent and influential
view. Considerable scholarly work has been done during the past quarter century to refute it on the grounds that it is historically
and ontologically inaccurate. It is a view which fails to recognise the contribution of non-scientific factors to technological
development,which neglects the reverse contribution of technology to science, and which offers a superficial account of the
process of application. This paper focusses on this last point, and argues that in those cases where science is applied to
technology, the application process is usually exceedingly complex. The process involves the selection of appropriate knowledge,
the adoption of differing criteria and the translation and re-shaping of knowledge to make it amenable to the technologist.
The issue has important implications for the school curriculum.
Specializations: science/technology education, technology teacher education, educational evaluation. 相似文献
5.
Dr Tim Hardy Ms Margaret Bearlin Dr Valda Kirkwood 《Research in Science Education》1990,20(1):142-151
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
6.
Dr Paul L Gardner 《Research in Science Education》1990,20(1):124-133
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. 相似文献
7.
Deborah Corrigan Peter Fensham Jennifer Sheed Rosemary Hutchinson 《Research in Science Education》1992,22(1):403-405
Conclusion The difficulty of sharing meaning of curriculum intentions between different groups is highlighted in this study. The acceptance
of the novel features of the Chemistry Study Design is mixed. The longitudinal nature of the study helped to identify the
difficulty teachers had in understanding the meaning of these novel features although the experiences of teaching units in
the VCE chemistry course have enabled some teachers to shift in their construction of the meaning of the words and messages
around them.
Specializations: chemistry and science education, technology and industry links with sicence in schools.
Specializations: science and technology curriculum, environmental education, educational disadvantage.
Specializations: curriculum change, science career paths.
Specializations: science education, computers in schools. 相似文献
8.
What is written in reports to parents can provide insight into the perceptions of teachers of the various areas of the primary
school curriculum. This paper reports the first stage of a research project focussing on reports as a guide to teachers' views
of the relative importance of, and desired student outcomes in, key areas of the curriculum. Teacher comments in the end-of-the-year
reports in one primary school were analysed.
Specializations: science education, teacher education.
Specializations: science education, teacher education. 相似文献
9.
Gender-inclusive technology materials for the primary school: A case study in curriculum development
Dr. Adrianne Kinnear Dr. David Treagust Dr. Leonie Rennie 《Research in Science Education》1991,21(1):224-233
This paper describes how an idea for technology education materials developed into a process for producing unique curriculum
modules for teaching technology in a gender-inclusive way to primary children. Using a case-study format, the paper describes
the interaction between participants, the sequential evolution of the materials themselves and the degree to which success
was achieved in terms of the original goals. The study demonstrates how an awareness of gender bias needs to be a feature
from the earliest stages of curriculum development, through to the trialling and modification stages. The curriculum materials
were a product of effective cooperation between teachers, science educators and community representatives. They utilise a
“process” approach to the teaching of technology and in this presentation, we demonstrate how this same approach is a useful
framework for describing this particular curriculum development.
Specializations: primary science and technology education, gender issues.
Specializations: diagnosis of student learning and teaching for conceptual change, technology education, curriculum evaluation.
Specializations: affective aspects of science and technology education, gender issues. 相似文献
10.
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
11.
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
12.
Rapid advances in technology are changing the structure of the workforce. There are elite highly-paid hi-tech occupations
and low status poorly-paid jobs. Women are unfortunately more likely to be found in the latter category. To allow them to
qualify and compete for the higher-status positions, girls need to participate in the physical sciences and in technology
studies. However, they are rarely attracted to them in secondary school, possibly because they are already alienated from
them by the time they leave primary school.
This paper reports some of the outcomes of a curriculum unit taught in two primary school classes in an independent school
for girls. The unit was cross-curricular, involving technology, science and other fields of knowledge; it made extensive use
of LEGO Technic materials. The evaluation of the unit, based on observations, a teacher journal and pupil questionnaires,
focussed upon the issue of whether it assisted the girls to feel happier about working with unfamiliar technology and feel
more capable of doing so. Implications for teaching technology are also discussed.
M.Ed. St student, Monash University.Specializations: primary school science and technology for girls.
Dr. Paul Gardner, Reader in Education, Monash University, 3168.Specializations: science and technology education, technology teacher education, educational evaluation, measurement of attitudes and interests. 相似文献
13.
Professor John K. Gilbert 《Research in Science Education》1992,22(1):157-162
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 相似文献
14.
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
15.
Despite the almost mandatory inclusion of a laboratory component in the school curriculum very little has been reported about
the effects of laboratory instruction upon student learning and attitudes. The present study was undertaken to investigate
the thinking of students in a chemistry laboratory. An interpretive research method was adopted in collecting and analysing
data gathered from observations, general interviews and stimulated recall interviews. Four high school students were studied
during their participation in a week-long university summer school program. This study reports how the four students responded
differently to the same laboratory experience.
Specializations: chemistry and biochemistry education, thinking in science and industry.
Specializations: science education, teacher learning and preparation, teaching thinking. 相似文献
16.
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. 相似文献
17.
Dr. Marilyn Fleer 《Research in Science Education》1992,22(1):132-139
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. 相似文献
18.
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
19.
Ian A. Simpson Dr. Kevin P. Singer Dr. David Treagust Dr. Marjan G. Zadnik 《Research in Science Education》1990,20(1):316-323
This paper describes the development and evaluation of a course in physiotherapy whereby the physics fundamental to the modalities
of cold, heat and ultrasound therapies was integrated in lectures and actual physiotherapy activities. The design of the course
is described together with the perceptions of physiotherapy students regarding the organisation of the course, safety aspects
and how well the integration contributed to their understanding of the physics involved in electrotherapy.
Specialization: Physics education.
Specialization: electrotherapy.
Specializations: Diagnosis of student learning difficulties and teaching for conceptual change, technology education, curriculum evaluation.
Specializations: Material science, isotope studies, physics education. 相似文献
20.
Professor Peter Fensham Dr. Kathiravelu Navaratnam Dr. Warren Jones Professor Leo West 《Research in Science Education》1991,21(1):80-89
One set of measures of the quality of courses for the preparation of science teachers stems from the perceptions exit students
have of their knowledge with respect to that teaching. The Discipline Review of Teacher Education in Mathematics and Science
surveyed these students late in 1988 on three broad types of knowledge-science content knowledge, curriculum knowledge, and
pedagogical knowledge. Some of these findings of the Review are described. In addition, the base for developing items to measure
these three types of knowledge is discussed in this paper. The variety in the data that emerged is also presented and the
consistency of the findings with other measures of quality is described.
Specialisations: science and technology curriculum, environmental education, educational disadvantage.
Specialisations: research and evaluation in teacher education, technical and further education and total quality management.
Specialisations: research in educational systems. 相似文献