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1.
Preparing student teachers to teach thoughtfully and to consider carefully the consequences of their work involves creating
opportunities for these beginning teachers to learn the skills and attitudes required for reflective practive. The case study
described here explores one model of developing reflective practice and the congruent role that the source and use of knowledge
of good teaching practice has in the process of developing the reflective practices of a post-graduate pre-service science
teacher. Of particular interest are the facilitators and barriers she sees as affecting this development.
Specializations: Science education, science teacher education
Specializations: science education, science teacher education, conceptual change, learning environments, science reasoning. 相似文献
2.
Stephen J. Norton Campbell J. McRobbie Ian S. Ginns 《Research in Science Education》2007,37(3):261-277
Little research has been conducted on how students work when they are required to plan, build and evaluate artefacts in technology
rich learning environments such as those supported by tools including flow charts, Labview programming and Lego construction. In this study, activity theory was used as an analytic tool to examine the social construction
of meaning. There was a focus on the effect of teachers’ goals and the rules they enacted upon student use of the flow chart
planning tool, and the tools of the programming language Labview and Lego construction. It was found that the articulation of a teacher’s goals via rules and divisions of labour helped to
form distinct communities of learning and influenced the development of different problem solving strategies. The use of the
planning tool flow charting was associated with continuity of approach, integration of problem solutions including appreciation
of the nexus between construction and programming, and greater educational transformation. Students who flow charted defined
problems in a more holistic way and demonstrated more methodical, insightful and integrated approaches to their use of tools.
The findings have implications for teaching in design dominated learning environments. 相似文献
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4.
The research reported in this article makes two distinctive contributions to the field of classroom environment research. First, because existing instruments are unsuitable for science laboratory classes, the Science Laboratory Environment Inventory (SLEI) was developed and validated. Second, a new Personal form of the SLEI (involving a student's perceptions of his or her own role within the class) was developed and validated in conjunction with the conventional Class form (involving a student's perceptions of the class as a whole), and its usefulness was investigated. The instrument was cross-nationally fieldtested with 5,447 students in 269 senior high school and university classes in six countries, and cross-validated with 1,594 senior high school students in 92 classes in Australia. Each SLEI scale exhibited satisfactory internal consistency reliability, discriminant validity, and factorial validity, and differentiated between the perceptions of students in different classes. A variety of applications with the new instrument furnished evidence about its usefulness and revealed that science laboratory classes are dominated by closed-ended activities; mean scores obtained on the Class form were consistently somewhat more favorable than on the corresponding Personal form; females generally held more favorable perceptions than males, but these differences were somewhat larger for the Personal form than the Class form; associations existed between attitudinal outcomes and laboratory environment dimensions; and the Class and Personal forms of the SLEI each accounted for unique variance in student outcomes which was independent of that accounted for by the other form. 相似文献
5.
This interpretive study of the teaching and learning of chemistry in an Australian high school examines the beliefs about the nature of science of a teacher and his class in relation to the enacted curriculum. Although the teacher and students tended to see science as an evolving discipline that was uncertain and changed over time, the manner in which the curriculum was implemented was a direct contrast. In the enacted curriculum science was represented as a catalogue of facts to be memorised and as algorithmic solutions to problems. The beliefs that had greatest impact on shaping the curriculum were the teachers beliefs about the nature of student learning, his beliefs about the distribution of power between himself and the students, and the extent to which restraints were accepted by the teacher as reasons for maintaining a traditional approach to teaching and learning chemistry. 相似文献
6.
Mr Jeffrey P. Dorman Dr Campbell J. McRobbie Dr Barry J. Fraser 《Research in Science Education》1993,23(1):61-67
Much Catholic school and church rhetoric suggests that Catholic schools possess distinctive learning environments. Research
into this aspect of Catholic schooling has been hampered by the lack of an appropriate assessment instrument. By drawing on
contemporary church literature, the perceptions of personnel involved in Catholic education and existing classroom environment
questionnaires, a new instrument was developed to assess student perceptions of classroom psychosocial environment in Catholic
schools. The use of this instrument in 64 classrooms in Catholic and Government schools indicated significant differences
on some scales. The distinctive nature of Catholic schooling did not extend to all classroom environment dimensions deemed
important to Catholic education.
Specializations: Catholic education, learning environments.
Specializations: conceptual change in students, science teacher professional development, scientific reasoning, learning environments.
Specializations: learning environments, science education, educational evaluation, curriculum. 相似文献
7.
Professor Wolff-Michael Roth Campbell J. McRobbie Keith B. Lucas 《Research in Science Education》1998,28(1):107-118
We analyse and explore, in the form of dialogues and metalogues questions about the dialogic nature of beliefs and students
belief talk about the nature of science and scientific knowledge. Following recent advances in discursive psychology, this
study focuses not on students' claims but on the discursive resources and dialogical practices that support the particular
claims they make. We argue that students' discourse is better understood as a textual bricolage that is sensitive to conversational
context, common sense, interpretive repertoires, and textual resources available in the conversational situation. Our text
is reflexive as it embodies the discursive construction of knowledge and undercuts any claims to authoritative knowledge.
The very conception of “belief” is itself an expression or construction from within the mundane idiom.... We learn to use
“belief” in conditions when the “objective facts” are unknown or problematic and we want to indicate the tenuous character
of our claim.... The notion of “real world” or “objective reality” is embedded in an extensive, pervasive language game which
includes as an intelligible move or possibility the use of the very concept of “belief” itself. (Pollner, 1987, p. 21) 相似文献
8.
Dr Sarah J. Stein Cambell J. McRobbie Ian S. Ginns 《Research in Science Education》1999,29(4):501-514
This paper explores the issues and concems identified by a small group of teachers implementing technology ideas using the
national document,A Statement on Technology for Australian Schools (Curriculum Corporation, 1994a), represented in four key questions they posed as a result of reflection upon their existing
ideas and practices, early in the study. These same issues and concerns framed their later experiences as the study progressed.
The case study of one of the teachers is used, to illustrate how the teachers implemented technology education working from
their own perspectives and tackling issues and concerns that made sense to them. By reviewing the teachers' own questions
about technology implementation, it is becoming, clear that what may be important for professional development in technology
education is related to the questions that the teachers themselves are asking about their own, beliefs and practices. 相似文献
9.
Teachers' failure to use the microcomputer‐based laboratory (MBL) more widely may be a result of not recognizing its capacity to transform laboratory activities. This research aimed to increase understanding of how MBL activities designed to be consistent with a constructivist theory of learning support or constrain student construction of understanding. The first author conducted the research with his Year 11 physics class of 15 students. Dyads addressed 10 tasks in thermal physics using a predict–observe–explain format. Data sources included video and audio recordings of students and teacher during four 70‐minute sessions, students' computer data and written notes, semistructured student interviews, and the teacher's journal. Analysis of students' discourse identified many instances in which students' initial understandings of thermal physics were mediated in multiple ways by the screen display. The findings are presented as eight assertions. Recommendations are made for developing pedagogical strategies incorporating MBL activities that will likely catalyze student construction of understanding. © 2004 Wiley Periodicals, Inc. J Res Sci Teach 41: 165–185, 2004 相似文献
10.
Concern is increasingly being expressed about the teaching of higher order thinking skills in schools and the levels of understanding
of scientific concepts by students. Metaphors for the improvement of science education have included science as exploration
and science as process skills for experimentation. As a result of a series of studies on how children relate evidence to their
theories or beliefs, Kuhn (1993a) has suggested that changing the metaphor to science as argument may be a fruitful way to
increase the development of higher order thinking skills and understanding in science instruction. This report is of a case
study into the coordination of evidence and theories by a grade 7 primary school student. This student was not able to coordinate
these elements in a way that would enable her to rationally consider evidence in relation to her theories. It appeared that
the thinking skills associated with science as argument were similar for her in different domains of knowledge and context.
Specializations: science learning, scientific reasoning, learning environments, science teacher education.
Specializations: cognition, reasoning in science and mathermatics. 相似文献