연구동향 분석

과학적 글쓰기를 활용한 논의-기반 모델링 전략의 개발

조혜숙 ( Hey Sook Cho ) 남정희 ( Jeong Hee Nam ) 이동원 ( Dong Won Lee ) 2014년

논문상세정보
인용/피인용
' 과학적 글쓰기를 활용한 논의-기반 모델링 전략의 개발' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • abm
  • argument-basedmodeling
  • argumentation
  • model
  • modeling
  • multimodalrepresentation
  • writing
  • 글쓰기
  • 논의
  • 논의-기반모델링
  • 다중표상
  • 모델
  • 모델링
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
1,846 0

0.0%

' 과학적 글쓰기를 활용한 논의-기반 모델링 전략의 개발' 의 참고문헌

  • 혈액 순환 모형 기반 수업에서 고등학생들의 개념 변화 분석
    김미영 한국과학교육학회지 27 (5) : 379 ~ 393 [2007]
  • 지구과학의 한 탐구 방법으로서 귀추법에 대한 이론적 고찰
    오필석 한국과학교육학회지 25 (5) : 610 ~ 623 [2005]
  • 선언적 과학 지식의 생성 과정에 대한 과학철학적 연구: 귀납적, 귀추적, 연역적 과정을 중심으로
    권용주 한국과학교육학회지 23 (3) : 215 ~ 228 [2003]
  • 모델링 활동에 대한 과학고등학교 학생들의 인식
    하지희 영재교육연구 19 (1) : 187 ~ 205 [2009]
  • 논의를 강조한 탐구적 과학 글쓰기(Science Writing Heuristic)의 중학교 과학 수업에의 적용
    남정희 한국과학교육학회지 28 (8) : 922 ~ 936 [2008]
  • 과학적 모델에 대한 중.고등학생들의 견해
    차정호 대한화학회지 48 (6) : 638 ~ 644 [2004]
  • Working knowledge: How organizations manage what the know
    Davenport, T. H. Harvard business school press [1997]
  • What teachers of science need to know about models : An overview
    Oh, P. International Journal of Science Education 33 (8) : 1109 ~ 1130 [2011]
  • Using a science writing heuristic to enhance learning outcomes from laboratory activities in seventh-grade science : Quantitative and qualitative aspects
    Hand, B. International Journal of Science Education 26 (2) : 131 ~ 149 [2004]
  • Using a guided inquiry and modeling instructional framework(EIMA)to support preservice K-8science teaching
    Schwarz, C. V. Science Education 91 (1) : 158 ~ 186 [2007]
  • Understanding scientific reasoning
    Giere, R. Thoon Learning [2006]
  • Understanding models in earth and space science
    Gilbert, S. W. NSTA Press [2003]
  • Understanding mathematics and science matters
    Romberg, T. Erlbaum : 3 ~ 26 [2005]
  • Toward a modelling theory of physics instruction
    Hestenes, D. American Journal of Physics 55 (5) : 440 ~ 454 [1987]
  • Thinker Tools : Causal models, conceptual change, and science education
    White, B. Y. Cognition and Instruction 10 (1) : 1 ~ 100 [1993]
  • The role of models/and analogies in science education : Implications from research
    Coll, R. K. International Journal of Science Education 27 (3) : 183 ~ 198 [2005]
  • The international handbook of science education
    Gilbert, J. K. Kluwer : 53 ~ 66 [1997]
  • The implications of cognitive studies for teaching physics
    Redish, E. F. American Journal of Physics 62 (9) : 792 ~ 803 [1994]
  • The forgotten tool : The design and use of molecular models
    Francoeur, E. Social Studies of Science 27 (1) : 17 ~ 40 [1997]
  • The effect of different learning tasks on model-building in plate tectonics : Diagramming versus explaining
    Gobert, J. D. Journal of Geoscience Education 53 (4) : 444 ~ 455 [2005]
  • The difficult process of scientific modelling : An analysis of novices’reasoning during computer-based modelling
    Sins, P. H. M. International Journal of Science Education 27 (14) : 1695 ~ 1721 [2005]
  • The cognitive effects of simulation-modelling software and systems thinking on learning and achievement
    Mandinach, E. B. Paper presented at the annual meeting of the American Educational Research Association [1988]
  • The change of science teachers’ personal knowledge about teaching models and modelling in the context of science education reform
    Henze, I. International Journal of Science Education 29 (15) : 1819 ~ 1846 [2007]
  • Teachers’ responses to science writing
    Owens, C. V. Teaching and learning-grand forks- 15 (1) : 22 ~ 35 [2000]
  • Teachers’ knowledge of models and modeling in science
    van Driel, J. H. International Journal of Science Education 21 (11) : 1141 ~ 1153 [1999]
  • System dynamics in high school physics
    Schecker, H. P. Proceedings of the 1994 International System Dynamics Conference : 74 ~ 84 [1994]
  • Symbolizing and communicating in mathematics classrooms: Perspectives on discourse, tools, and instructional design
    Lesh, R. Lawrence Erlbaum Associates : 361 ~ 383 [2000]
  • Students’understanding of the role of scientific models in learning science
    Treagust, D. F. International Journal of Science Education 24 (4) : 357 ~ 368 [2002]
  • Sequencing and supporting complex scientific inquiry practices in instructional materials for middle school students
    Fortus, D. Annual Meeting of the National Association for Research in Science Teaching [2006]
  • Secondary students’ mental models of atoms and molecules : Implications for learning chemistry
    Harrison, A. G. Science Education 80 (5) : 509 ~ 534 [1996]
  • Scientific and engineering practices in K–12 classrooms : Understanding a framework for K-12 science education
    Bybee, R. W. Science and Children 49 (4) : 10 ~ 16 [2011]
  • Science teachers’ knowledge about and attitudes toward the use of models and modeling in learning sciences
    Justi, R. International Journal of Science Education 24 (12) : 1273 ~ 1292 [2002]
  • Science for the people: The origins of the school science curriculum in england
    Layton, D. Allen & Unwin [1973]
  • Science as model building : Computers and high-school genetics
    Stewart, J. Educational Psychologist 27 (3) : 317 ~ 336 [1992]
  • Schematic modeling for meaningful learning of physics
    Halloun, I. A. Journal of Research in Science Teaching 33 (9) : 1 ~ 26 [1996]
  • Rhetorical features of student science writing in introductory university oceanography
    Kelly, G. J. Routledge Publishers : 265 ~ 282 [2002]
  • Reading science: Critical and functional perspectives on discourses of science
    Lemke, J. L. Routledge : 87 ~ 113 [1998]
  • Re-thinking old ways : Towards a more critical approach to practical work in school science
    Hodson, D. Studies in Science Education 22 : 85 ~ 142 [1993]
  • Promoting biological knowledge generation using model-based inquiry instruction
    Chabalengula, V. International Journal of Biology Education 2 (1) : 1 ~ 24 [2012]
  • Principles and methods of teaching writing; Process-oriented approach
    Lee, J. S. Teaching the history of science Publishers [2002]
  • On understanding the nature of scientific knowledge
    Carey, S. Educational Psychologist 28 (3) : 235 ~ 251 [1993]
  • On looking into the black box : Prospects and limits in the search for mental models
    Rouse, W. B. Psychological Bulletin 100 (3) : 349 ~ 363 [1986]
  • Models in explanations, part 1: Horses for courses
    Gilbert, J. K. International Journal of Science Education 20 (1) : 83 ~ 87 [1998]
  • Models as mediators. Perspectives on natural and social sciences
    Morgan, M. Cambridge University Press [1999]
  • Models and modelling in theoretical chemistry
    Tomasi, J. Journal of Molecular Structure 179 (1) : 273 ~ 292 [1988]
  • Models and modeling in physics education: A critical re-analysis of philosophical underpinnings and suggestions for revisions
    Tapio, I. Science & Education 16 (7) : 751 ~ 773 [2007]
  • Modeling, teachers’ views on the nature of modeling, and implications for the education of modelers
    Justi, R. International Journal of Science Education 24 (4) : 369 ~ 387 [2002]
  • Modeling theory in science education
    Halloun, I. A. Springer [2006]
  • Modeling theory applied: Modeling instruction in introductory physics
    Brewe, E. American Journal of Physics 76 (12) : 1155 ~ 1160 [2008]
  • Modeling instruction : An effective model for science education
    Jackson, J. Science Educator 17 (1) : 11 ~ 17 [2008]
  • Modeling biology: Structures, behaviors, evolution
    Laubichler, M. MIT [2007]
  • Model-based reasoning: Science, technology, values
    Magnani, L. Kluwer Academic Publishers [2002]
  • Model-based learning as a key research area of science education
    Clement, J. J. International Journal of Science Education 22 (9) : 1041 ~ 1053 [2000]
  • Model building for conceptual change
    Jonassen, D. Interactive Learning Environments 13 (1) : 15 ~ 37 [2005]
  • Model building and a definition of science
    Gilbert, S. W. Journal of Research in Science Teaching 28 (1) : 73 ~ 79 [1991]
  • Model based learning and instruction in science
    Clement, J. J. Springer [2008]
  • Model and modelling : Routes to more authentic science education
    Gilbert, J. K. International Journal of Science and Mathematics Education 2 (2) : 115 ~ 130 [2004]
  • Middle school students' open physics inquiry emphasizing peer argumentation: Its conditions, features, and roles
    Kim, H. G. Seoul National University [2003]
  • Metamodeling knowledge : Developing students’ understanding of scientific modeling
    Schwarz, C. V. Cognition and Instruction 23 (2) : 165 ~ 205 [2005]
  • Mental, physical, and mathematical models in the teaching and learning of Physics
    Greca, I. M. Science Education 85 (6) : 106 ~ 121 [2002]
  • Mental models: Towards a cognitive science of language, inference and consciousness
    Johnson-Laird, P. N. Cambridge University Press [1983]
  • Mental models, conceptual models, and modelling
    Greca, I. M. International Journal of Science Education 22 (1) : 1 ~ 11 [2000]
  • Mental models
    Norman, D. N. Erlbaum : 7 ~ 14 [1983]
  • Mediated modeling in science education
    Halloun, I. A. Science and Education 16 (7) : 653 ~ 697 [2007]
  • Learning with artificial worlds: Computer based modelling in the curriculum
    Bliss, J. The Falmer Press : 27 ~ 33 [1994]
  • Learning physics by making models
    Schecker, H. P. Physics Education 28 (2) : 102 ~ 106 [1993]
  • Investigation of secondary school, undergraduate, and graduate learners’ mental models of ionic bonding
    Coll, R. K. Journal of Research in Science Teaching 40 (5) : 464 ~ 486 [2003]
  • Introduction to model-based teaching and learning in science education
    Gobert, J. D. International Journal of Science Education 22 (9) : 891 ~ 894 [2000]
  • Interaction in an open-inquiry physics laboratory
    Roychoudhury, A. International Journal of Science Education 18 (4) : 423 ~ 445 [1996]
  • Inquiry, modeling, and metacognition : Making science accessible to all students
    White, B. Y. Cognition and Instruction 16 (1) : 3 ~ 118 [1998]
  • Inquiry and the national science education standards
    National Research Council National Academy Press [2000]
  • Inquiry Island: Affordances of a multi-agent environment for scientific inquiry and reflective learning
    White, B. Y. Proceedings of the 5th international conference of the learning sciences (ICLS) [2002]
  • How students learn
    Stewart, J. National Research Council : 515 ~ 565 [2005]
  • How novice science teachers appropriate epistemic discourses around model-based inquiry for use in classrooms
    Windschitl M. Cognition and Instruction 26 (3) : 310 ~ 378 [2008]
  • Handbook of research on science education
    Lederman, N. G. Lawrence Erlbaum Associates : 831 ~ 879 [2007]
  • Handbook of child psychology Vol. 4
    Lehrer, R. John Wiley and Sons [2006]
  • Explanations with models in science education. Developing Models in Science Education
    Gilbert, J. K. Kluwer [2000]
  • Explanation and evidence in informal argument
    Sarah K. B. Cognitive Science 24 (4) : 573 ~ 604 [2000]
  • Explaining science
    Giere, R. University of Chicago Press [1988]
  • Experienced teachers’ knowledge of teaching and learning of models and modeling in science education
    van Driel, J. H. International Journal of Science Education 24 (12) : 1255 ~ 1272 [2002]
  • Examining the impact of student use of multiple-mode representations in constructing science arguments
    Hand, B. Annual International Conference of National Association for Research in Science Teaching [2008]
  • Examining the elationship between students’ understanding of the nature of models and conceptual learning in biology, physics, and chemistry
    Gobert, J. D. International Journal of Science Education 33 (5) : 653 ~ 684 [2011]
  • Epistemic levels in argument : An analysis of university oceanography students’ use of evidence in writing
    Kelly, G. J. Science Education 86 (3) : 314 ~ 342 [2001]
  • Effects of model-based teaching on preservice physics teachers' conceptions of the moon, moon phrases, and other lunar phenomena
    Ogan-Bekiroglu, F. International Journal of Science Education 29 (5) : 555 ~ 593 [2007]
  • Effects of constructivistic learning strategy on middle school students' learning of scientific conception learning and scientific attitudes: Focused on science writing
    Lee, K. N. Chonbuk National University [2007]
  • Educators’ handbook: A research perspective
    Anderson, C. W. Longman : 84 ~ 111 [1987]
  • Education reason: Rationality, critical thinking and education
    Seigel, H. Routledge [1988]
  • Developing preservice elementary teachers' knowledge and practices through modeling‐centered scientific inquiry
    Schwarz, C. V. Science Education 93 (4) : 720 ~ 744 [2009]
  • Developing models in science education
    Buckley, B. C. Kluwer Academic : 119 ~ 135 [2000]
  • Developing models in Science Education
    Boulter, C. J. Kluwer Academic Publisher : 41 ~ 57 [2000]
  • Developing a learning progression for science modeling : making scientific modeling accessible and meaningful for learners
    Schwarz, C. V. Journal of Research in Science Teaching 46 (6) : 632 ~ 654 [2009]
  • Designing a web-based science learning environment for model-based collaborative inquiry
    Sun D. Journal of Science Education and Technology 22 (1) : 73 ~ 89 [2013]
  • Defending science-within reason: Between scientism and cynicism
    Haack, S. Prometheus Books [2003]
  • Creative model construction in scientists and students
    Clement, J. J. Springer [2008]
  • Common sense concepts about motion
    Halloun, I. A. American Journal of Physics 53 (11) : 1056 ~ 1065 [1985]
  • Collaborative inquiry learning : models, tools, and challenges
    Bell, T. International Journal of Science Education 32 (3) : 349 ~ 377 [2010]
  • Cognitive comparisons of students’ systems modelling in ecology
    Hogan, K. Journal of Science Education and Technology 10 (4) : 319 ~ 345 [2001]
  • Children's mental models of the free-fall of objects
    Lee, M. J. Journal of the Korean Association for Research in Science Education 19 (3) : 389 ~ 399 [1999]
  • Children and adults as intuitive scientists
    Kuhn, D. Psychological Review 96 (4) : 674 ~ 689 [1989]
  • Chemistry through models. Concepts and applications of modeling in chemical science, technology and industry
    Suckling, C. J. Cambridge University Press [1978]
  • Categorization and representation of physics problems by experts and novices
    Chi, M. T. H. Cognitive Science 5 (2) : 121 ~ 152 [1991]
  • Capturing and modeling the process of conceptual change
    Vosnadiu, S. Learning and Instruction 4 (1) : 45 ~ 69 [1994]
  • Beyond the scientific method : Model-Based Inquiry as a new paradigm of preference for school science investigations
    Windschitl M. Science Education 92 (5) : 941 ~ 967 [2008]
  • Beginning computer-based modelling in primary schools
    Webb, M. E. Computers in Education 22 (1) : 129 ~ 144 [1994]
  • A typology of school science models
    Harrison, A. G. International Journal of Science Education 22 (9) : 1011 ~ 1026 [2000]
  • A new definition of models and modeling in chemistry’teaching
    Chamizo, J. A. Science & Education 22 (7) : 1613 ~ 1632 [2013]
  • A modeling method for high school physics instruction
    Wells, M. American Journal of Physics 63 (7) : 606 ~ 619 [1995]
  • A model for multimodal reference resolution
    Pineda, L. Computational Linguistics 26 (2) : 139 ~ 193 [2000]
  • A history of ideas in science education: Implications for practice
    DeBoer, G. E. Teachers College Press [1991]
  • A framework for K-12Science education: Practices, crosscutting concepts, and core ideas
    National Research Council The National Academies Press [2012]
  • A framework for K-12 Science Education:Practices, cross-cutting concepts, and core ideas. Committee on a Conceptual Framework for New K-12 Science Education Standards
    National Research Council National Academy Press [2012]
  • A brief reflection on cognitive and social constructivism
    Kang, I. A. Journal of Educational Technology 11 (2) : 3 ~ 20 [1997]