• 한국지구과학회:학술대회논문집
• /
• 2010.04a
• /
• pp.68-69
• /
• 2010

본 연구의 목적은 서울시 소재 과학영재교육원에서 운영하는 프로그램에서 개발된 일부 모듈들에 구현되어있는 과학탐구과정 및 사고과정의 특징이 과학영재프로그램의 목적에 따른 목표를 성취할 수 있는지를 평가하고, 과학탐구과정이나 사고과정의 각 항목을 구현한 탐구의 실제를 알기 위한 것이다. 또, 본 연구의 결과를 토대로 모듈들에 대해 반성하고 개선점을 찾으려는 것이다. 연구 참여자들은 13명이며 연구 목적을 위해 첫째, 영재교육과정 및 평가에 관한 문헌을 근거로 과학영재프로그램의 목적과 목표를 설정, 둘째, 목적과 목표를 근거로 문헌에 제시된 분석틀들을 수정 개발, 셋째, 참여자들이 각자 모듈을 1개 선정하여 분석하고 이를 수정한 후 다시 분석하여 해석, 넷째, 분석결과의 해석을 토대로 반성을 하였다. 각 단계마다 각자 해결한 내용을 공개하고 모든 참여자들이 공개된 내용에 대해 비판하면서 합의하는 과정을 거쳤다. 합의 도출에 의해 첫째, 과학영재프로그램의 목적은 '탐구적 사고과정을 함양하고 지역사회에 유익한 새로운 지식을 창출한다.', 이에 대한 목표는 '자기 주도적인 탐구 계획 능력을 향상한다.'와 '숙달된 탐구 기능을 사용하여 실제문제를 해결할 수 있다.'로 설정하였다. 둘째, 분석틀은 '과학탐구과정' 과 '사고과정'의 두 범주로 구성하였으며, '과학탐구과정'에 해당하는 항목은 '사전탐구, 탐구방법, 해석적 탐구기술, 의사소통능력, 탐구평가, 과학의 본성'으로, '사고과정'에 해당하는 항목들은 '논리적 사고, 창의적 사고'로 구성하였다. 셋째, 선정된 모듈들을 분석한 결과 모듈들은 대체로 탐구방법과 해석적 탐구기술을 많이 강조하였는데, 수정된 모듈들에서는 이 두 항목이 더욱 강조되었다. 특히, 해석적 탐구기술에서 의사소통능력, 탐구평가, 과학의 본성, 창의적 사고를 강조하는 탐구의 실제가 증가하였다. 수정후 증가된 항목들은 앞에서 설정한 두 가지 목표에 도달하는데 도움이 되는 항목들이라고 합의 선정되었던 것이므로, 이에 따라 수정 전 모듈보다 수정 후 모듈이 보다 더 영재프로그램의 목표에 도달하기에 적합한 것으로 판단하였다. 넷째, 연구결과를 토대로 반성한 점은 '목표' 에 '창의적 사고'와 '과학의 본성'에 대한 강조가 부족하다는 것, '목표'에서 '실제문제를 해결'할 수 있어야 한다는 것에 비해 '모듈'에서 다루는 주제는 '실제문제'가 아니라 학문적인 질문에 치우쳐 있다는 것, '자기 주도적인 탐구 계획 능력'을 향상시키는 탐구의 실제가 대체로 적게 제시되어 있다는 것이다. 이러한 반성을 영재프로그램의 각 모듈에서 모두 구현할 수 있는 것은 아니지만 본 연구에서 설정한 목적과 목표에 따라 프로그램을 개발하는 경우 이러한 반성점을 고려하여 모듈을 개발한다면 영재프로그램 전체적으로 볼 때는 모두 구현되어 있을 것이다. 본 연구는 서울시에 소재하는 과학영재교육원들에서 개발하여 사용하는 많은 모듈 중 극히 일부를 대상으로 하였으므로 연구 결과를 모든 과학영재프로그램에 적용하기에는 한계가 있다. 그러나 본 연구처럼 프로그램이나 모듈을 평가하려는 연구자들에게 일련의 평가단계에 대한 시사점을 제공할 수 있을 것으로 생각한다.

• Journal of The Korean Association For Science Education
• /
• v.33 no.1
• /
• pp.30-45
• /
• 2013

In this study, we developed a model for analyzing scientists' creative thinking processes, and analyzed Archimedes' thinking process in solving the golden crown problem. As results show, scientists' complex problem solving processes could be represented as a repeating circular model, and the fusion of processes of diverse thinking required for scientists' creativity could be analyzed from the case. Also in this study, we represented the role of experiments in scientists' creative discovery, and investigated the reasons for the difference between the viewpoints of textbooks and historic facts. We found the importance of abductive reasoning and advance knowledge in creative thinking. Archimedes solved the golden crown problem creatively by crossing the scientific thought of dynamics and the daily thought of baths. In this process, abductive reasoning and advance knowledge played an important role. Besides Archimedes' case, if we would reconstruct the creative discovery processes of diverse scientists' in textbooks, students could raise their creative thinking ability by experiencing these processes as educational steps.

• Journal of the Korean earth science society
• /
• v.42 no.3
• /
• pp.344-364
• /
• 2021

The study explored how two elementary school teachers perceived computational thinking, reflected them into curriculum revision, and taught them in the classroom during longitudinal professional developed program (PDP) for nine months. Computational thinking is a new direction in educational policy-making including science education; therefore we planned to investigate participating teachers' perception of computational thinking to provide their fundamental understandings. Nine meetings, lasting about two hours each, were held with the participating teachers and they developed 11 lesson plans for one unit each, as they formed new understandings about computational thinking. Data were collected through PDP program while two teachers started perceiving computational thinking, revising their curriculum, and implementing it into their class for nine months. The results were as follows; first, elementary school teachers' perception of computational thinking was that the definition of scientific literacy as the purpose of science education was extended, i.e., it refers to scientific literacy to prepare students to be creative problem solvers. Second, STEAM (science, technology, engineering, arts, and mathematics) lessons were divided into two stages; concept formation stage where scientific thinking is emphasized, and concept application, where computational thinking is emphasized. Thirdly, computational thinking is a cognitive thinking process, and ICT (informational and communications technology) is a functional tool. Fourth, computational thinking components appear repeatedly and may not be sequential. Finally, STEAM education can be improved by utilizing computational thinking. Based on this study, we imply that STEAM education can be activated by computational thinking when teachers are equipped with competencies of understanding and implementing computational thinking within the systematic PDPs, which is very essential for newly policies.

• Proceedings of the Korea Contents Association Conference
• /
• 2003.05a
• /
• pp.74-87
• /
• 2003

A model of STS (Science-Technology-Society) creativity education program for the gifted and talented children has been developed, based on GENEPLORE thinking process and Knowledge development theory. The GENEPLORE creative thinking process, developed by Finke et al. (1990, 1992), has two phases such as generative phase and exploratory phase. And The knowledge development theories of Piaget (1977) and Gallagher(1981) assume that knowledge-bases are developed on the basis of empirical as well as reflective abstraction, which could imply that knowledge-bases are crucial in creative thinking process. The creativity education model for the gifted and talented of the present study attempted to integrate 'the individual, creative thinking process, and social/scientific technology' by employing topics of the science-technology-society such as computer, network, biotech, robot, e-business, e-education, e-health, nanotech and entertainment and the structure and contents of the program are proposed

• Journal of The Korean Association For Science Education
• /
• v.27 no.1
• /
• pp.70-83
• /
• 2007

Reflection in teacher education is one reform effort that has taken hold in many teacher preparation programs. However, how to define it and how to foster it in a teacher's education are problematic issues. In this study, on the basis of literature review, science teachers' reflective thinking is defined as a process of thinking that deliberates on alternatives to solve conflict between one's previous knowledge/belief/practice and internal/external factors in science teaching context. Based on this definition, three types of science teachers' reflective thinking (i.e. technical reflection, professional reflection and critical reflection) were proposed. In addition, a framework of classifying the reflective thinking's types was also developed. To investigate science teachers' reflective thinking, two pre-service science teachers who majored in physics education participated in this study. The participants presented the monthly report on reflective practice, pre/post questionnaire, and education practicum journals. Individual interviews with them were conducted before and after their teaching activities. From the analysis of the data, it was possible to categorize the reflective thinking of the participants into three types. The major type of their reflective thinking was the technical reflection. However, it was difficult to find examples of the critical reflection.

• Journal of The Korean Association For Science Education
• /
• v.20 no.2
• /
• pp.329-343
• /
• 2000

The purpose of this study is to develop the middle school science curriculum to enhance creative problem-solving abilities. The reconstructed curriculum consisted of three big components, that is, scientific knowledge, process skills, and creative thinking skills. Five themes have been selected to incorporate with four areas of the middle school science curriculum, namely, physics, chemistry, biology, earth science. The five themes are structure, change, interaction, energy, and stability. Based upon these five themes, the individual or separated scientific knowledges of learners can be put into the unified knowledges. The process skills were observing, measuring, classifying, communicating, inferring, predicting, variable differentiating controling, data gathering analysis, establishing hypotheses, experiment design, and experimenting. Creative thinking skills include divergent and critical thinking. The finally developed curriculum is presented in the form of matrix.

• Archives of design research
• /
• v.21
• /
• pp.1-12
• /
• 1997

This research is that it could use a theory from a .cognitive science, making a hypothesis to explain the thingking steps of designing, adapting the problem solving of the design from knowledge of a cognitive science, to meet the possiblity which it can be developed the new way of the thinking. Design is a field where it needs a complexity with hi-brain activities. And cognitive science is a science which it study human brain activities. However, it is also quite possible to bo adaped over all design by linking with design and cognitive science. I explaned the ideation of the thinking steps on this study by the knowledge of cognitive science, to observe to be possible. I found out the new ways of possibilities from design thinking process. It is a result that I've been interpretated the design process and the thinking process out of the theory of knowledge structure.

• Journal of Science Education
• /
• v.43 no.3
• /
• pp.329-341
• /
• 2019

The purpose of this study is to investigate the effects of instructional strategies using the process of procedural thinking in elementary science classes on students' computational thinking and creative problem solving ability. For this purpose, instructional strategies using the process of procedural thinking for science class were developed and applied. The objects of this study were 6th graders from an experimental class (29 students) and a comparative class (29 students) at S elementary school in Gimpo City. The results of the study are as follows: First, as a result of examining the difference in the computational thinking ability between experimental group and comparative group, the experimental group scored higher than the comparative group, but there was no statistically significant difference. Second, the creative problem solving ability of the experimental group after applying this program was higher, and statistically significant differences were observed (p < .05).

• Journal of the Korean Chemical Society
• /
• v.55 no.5
• /
• pp.846-856
• /
• 2011

In this study, we analyzed the characteristics of imagery thinking in the processes of generating analogy of seventh grade science-gifted students in terms of the information-processing of imagery. The analyses of the results revealed that science-gifted students' information-processing of imagery in the processes of generating analogy consisted of image generation, image operation, and image representation. The types of imagery used by science-gifted students were classified into perception imagery, memory imagery, and imagination imagery, and there were some differences in the patterns of information-processing of imagery. In the bases of these results, we suggested the information-processing model of imagery by the types of imagery used in generating analogy. The results of this study may provide useful implication to develop effective methods for a strategy of generating analogy emphasizing the interaction between analogy thinking and imagery thinking which promotes imagery thinking of science-gifted students.

• Journal of The Korean Association For Science Education
• /
• v.31 no.2
• /
• pp.198-209
• /
• 2011

In this study, pre-service science teachers' reflective thinking in their journal writing was investigated. To do this, the authors used pre-service science teachers' journal writing abilities, wherein they not only reported data and result formally, but also wrote their feelings and reflections about an inquiry-based physics experiment they performed. Pre-service science teachers' writings were decomposed into sentences and each sentence was analyzed into a framework with 4 dimensions: knowledge, procedure, orientation and attitude. Reflective thinking in knowledge dimension included reflection on what they know before the experiment, what they still do not know and what they learned from the experiment. Reflective thinking in procedure dimension included recalls of experiences about general experimental procedures and specific experimental skill. Reflective thinking in orientation dimension included their views about the nature of science and science teaching and learning, and reflective thinking in attitude dimension consisted of interests, motives and values about the experiment they performed. While there were some variations in frequency distribution of reflective thinking by the topic of experiments, pre-service science teachers' reflective thinking in journal writings revealed their metacognition on their knowledge and learning, epistemological belief about science and science learning, and affective domain related to experiment. This study can infer that such kind of writing with 'their own language' in an informal way followed by formal 'scientific' reports in a scientific experiment has a significance not only as a mediator representing reflective thinking but also as an instructional activity to facilitate reflective thinking in science learning and teaching.