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열역학 제2법칙과 가역과정에 대한 학생의 이해와 효과적 지도 방안

이주현 2012년

논문상세정보
인용/피인용
' 열역학 제2법칙과 가역과정에 대한 학생의 이해와 효과적 지도 방안' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • 공학, 공업일반
  • 가역과정
  • 단열과정
  • 엔트로피
  • 열기관
  • 열역학 제2법칙
  • 일반 물리
  • 학생의 이해
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
310 2

6.4%

' 열역학 제2법칙과 가역과정에 대한 학생의 이해와 효과적 지도 방안' 의 참고문헌

  • 학생의 물리 선개념. 물리 교육학 총론Ⅰ. 박종원, 최경희, 김영민 (pp. 13-69)
    박종원 학생의 물리 선개념. 물리 교육학 총론Ⅰ. 박종원 [2001]
  • 학생의 과학 오개념 연구의 이론적 기초. 송진웅, 김익균, 김영민, 권성기, 오원근, 박종원. 학생의 물리 오개념 지도 (pp. 1-30)
    송진웅 학생의 과학 오개념 연구의 이론적 기초. 송진웅 [2004]
  • 학생들이 물리를 재미없고 어렵다고 생각하는 이유에 대한 분석
    김희경 이봉우 학생들이 물리를 재미없고 어렵다고 생각하는 이유에 대한 분석 [2006]
  • 통계역학의 기초 다시 보기-메타동역학의 관점
    김재영 [2004]
  • 최무영 교수의 물리학 강의
    최무영 [2008]
  • 박사
    중학생의 전류 개념 변화에 미치는 체계적 비유 수업의 영향
    김영민 중학생의 전류개념 변화에 미치는 체계적 비유수업의 영향 [1991]
  • 일반화학 교재에 나타난 엔트로피 정의와 설명의 고찰
  • 일반물리학 교과서의 엔트로피 개념에 대한 설명 분석
  • 인지갈등과 개념변화의 필요조건과 충분조건
    권재술 김연수 이경호 한국과학교육학회지 [2003]
  • 왜 학생들은 물리학을 어려워하는가?: 지식 신념틀을 이용한 물리학습의 어려움에대한 구조적 분석을 향하여
    왜 학생들은 물리학을 어려워하는가?: 지식 신념틀을 이용한 물리학습의 어려움에 대한 구조적 분석을 향하여 [2007]
  • 박사
    열역학의 기본 개념 및 과정에 대한 대학생 이해의 특징과 어려움
    지영래 [2008]
  • 열과 에너지’의 물리 오개념. 송진웅, 김익균, 김영민, 권성기, 오원근, 박종원. 학생의 물리 오개념 지도 (pp. 229-274)
    권성기 열과 에너지’의 물리 오개념. 송진웅 [2004]
  • 연결주의적 관점의 개념학습 방안으로서 '전형적 인식상황(TPS)'의 변화 : 초등학생의 힘의 작용에 관한 생각을 중심으로
    정용재 [2004]
  • 엔트로피 개념 이해의 특징과 어려움: 물리 전공 학생들의 문제 풀이과정을 중심으로
    [2007]
  • 스털링 기관의 열효율에 대한 설명방식 및 대학생들의 사고과정 분석
  • 박사
    상대론 기초 개념 변화에 있어서 초인지의 역할
    박종원 서울대학교 대학원 박사 학위 논문 [1992]
  • 사회열역학 : 21세기 사회과학개론
    최동식 [2000]
  • 물리 전공 학생들의 엔트로피 개념에 대한 이해의 어려움
  • 물리 문제해결 학습과 지도. 물리 교육학 총론Ⅱ. 김익균, 박윤배, 박종원, 송진웅, 최경희 (pp. 69-136)
    박윤배 물리 문제해결 학습과 지도. 물리 교육학 총론Ⅱ. 김익균 [2002]
  • 문제의 특성에 따른 대학생들의 화학문제 해결과정의 차이 분석
    박윤배 홍미영 문제의 특성에 따른 대학생들의 화학 문제해결 과정의 차이 분석 [1995]
  • 고등학교 화학Ⅱ (pp. 136-143)
    [2012]
  • 고등학교 물리Ⅱ (pp. 99-103)
    [2011]
  • 고등학교 물리Ⅱ (pp. 90-96)
    [2011]
  • 고등학교 물리Ⅱ (pp. 169-175)
    [2002]
  • 고등학교 물리Ⅱ (pp. 147-155)
    [2002]
  • 고등학교 물리Ⅱ (pp. 126-133)
    [2002]
  • 고등학교 물리Ⅱ (pp. 122-129)
    [2003]
  • 고등학교 물리Ⅱ (pp. 119-127)
    [2002]
  • 고등학교 물리Ⅱ (pp. 119-123)
    [2004]
  • 고등학교 물리Ⅱ (pp. 116-121)
    [2003]
  • 고등학교 물리Ⅱ (pp. 113-119)
  • 고등학교 물리Ⅱ (pp. 106-109)
    [2004]
  • Why students choose physics, or reject it
    Woolnough Why students choose physics [1994]
  • When an adiabatic irreversible expansion or compression becomes reversible
  • What lies between a free adiabatic expansion and a quasi-static one?
    Miranda [2008]
  • What is life? : And other scientific essays
    Schr?dinger [1956]
  • What is a reversible process?
    Samiullah [2007]
  • Weekly reports: a two-way feedback tool
    Etkina Weekly reports: A two-way feedback tool [2000]
  • Using the history of science to teach thermodynamics at the university level: The case of the concept of entropy
    Viard [2007]
  • University students explaining adiabatic compression of an ideal gas - A new phenomenon in introductory thermal physics
  • Understanding thermodynamics (pp. 15-25)
    Van Ness [1983]
  • Understanding of elementary concepts in heat and temperature among college students and K-12 teachers
  • Understanding and teaching important scientific thought processes
    Reif [1995]
  • Tutorials in introductory physics, Upper Saddle River
    McDermott Shaffer Tutorials in introductory physics [1998]
  • Thermodynamics of an irreversible quasi-static process
    Thomsen [1960]
  • Thermodynamics and ecology
    Yuri M [2000]
  • Thermodynamics : An engineering approach (5th ed.)
    Boles [2006]
  • Thermodynamics
  • Thermodynamic entropy: The spreading and sharing of energy
    Leff [1996]
  • Thermal physics in the introductory physics course: Why and how to teach it from a unified atomic perspective
    Reif [1999]
  • Thermal physics
  • The temperature concept
    Worthing [1940]
  • The statistical interpretation of entropy: An activity
    Timberlake [2010]
  • The second law of thermodynamics in a historical setting
    Strnad [1984]
  • The role of conceptual conflict in conceptual change and the design of science instruction
    [1984]
  • The psychology of learning science. 구성주의적 과학학습 심리학
    [1991]
  • The mechanical theory of heat: With its applications to the steam-engine and to the physical properties of bodies
    Clausius [1867]
  • The mechanical theory of heat
    Clausius [1879]
  • The meaning of temperature
    Baierlein [1990]
  • The kind of motion we call heat : A history of the kinetic theory of gases in the 19th century. Amsterdam;
    Brush [1976]
  • The efficiency of reversible heat engines
  • The effects of task contexts on pupils’ performance in science process skills
    Black Song [1991]
  • The distinction between heat and work: an approach based on a classical mechanical model
    Besson [2003]
  • The acquisition and retention of knowledge : a cognitive view
  • Teaching introductory physics : a sourcebook
  • Teaching introductory physics
    Arons, A. B [1997]
  • Teaching Entropy Analysis in the First-Year High School Course and Beyond
    Bindel [2004]
  • Surveying Students Conceptual knowledge of Electricity and Magnetism
    Maloney [2001]
  • Students’ reasonings in thermodynamics
  • Students' understanding of basic ideas of the second law of thermodynamics
  • Students' pre-knowledge as a guideline in the teaching of introductory thermal physics at university
  • Students' conceptions of the second law of thermodynamics - an interpretive study
  • Students do not overcome conceptual difficulties after solving 1000 traditional problems
    Kim Park [2002]
  • Student understanding of the work-energy and impulse-momentum theorems
  • Student understanding of the ideal gas law, Part II: A microscopic perspective
    Heron Kautz McDermott Shaffer Student understanding of the ideal gas law [2005]
  • Student understanding of the ideal gas law, Part I: A macroscopic perspective
    Student understanding of the ideal gas law [2005]
  • Student understanding of the first law of thermodynamics: Relating work to the adiabatic compression of an ideal gas
  • Student misconceptions in thermodynamics
    Granville [1985]
  • Student ideas regarding entropy and the second law of thermodynamics in an introductory physics course
  • Student conceptions and conceptual learning in science. In S. K. Abell and N. G. Lederman (Eds.)
  • Stu dent s ' concept ion s and th e learnin g of scien ce
    Driv er [1989]
  • Statistical mechanics(2nd ed.)
    Pathria [1996]
  • Sears and Zemansky's university physics (12th ed., pp. 646-701)
    Freedman Sears Young Sears and Zemansky's university physics (12th ed. [2008]
  • Science teaching and children's views of the world
  • Rudolf Clausius and the road to entropy
    Cropper [1986]
  • Resourceletter:PER-1:Physicseducationresearch
    McDermott Redish Resource letter: PER-1: physics education research [1999]
  • Research on science teacher knowledge. in S. K. Abell & N. G. Lederman(eds.)
    Abell [2007]
  • Representing Entropy with Dispersion Sets
    Kolarczyk [2010]
  • Removing the mystery of entropy and thermodynamics - Part II
    Leff [2012]
  • Reflexions sur la Puissance Motrice du Feu sur les machines propres a developper cette puissance [Reflections on the motive power of fire, and on machines fitted to develop that power]. In Thurston, R. H., & Mendosa, E. (Ed. and Trans.), Reflections on the motive power of fire: And other papers on the second law of thermodynamics (pp. 1-59)
    Carnot R?flexions sur la Puissance Motrice du Feu sur les machines propres a developper cette puissance [Reflections on the motive power of fire [1988]
  • Reflections on the pedagogic motive power of unconventional thermodynamic cycles
  • Pupils' alternative frameworks in science
    Driv er [1981]
  • Probability and thermodynamics:
    Daub [1969]
  • Pressure-volume work exercises illustrating the first and second laws
  • Pressure of an ideal gas on a moving piston
    Cockerham [1969]
  • Physics for scientists and engineers. New York: W. H
  • Physics for scientists and engineers, with modern physics
  • Physics for scientists & engineers (3rd ed, pp. 516-539)
    Giancoli Physics for scientists & engineers (3rd ed [2000]
  • Physics : Calculus (pp. 603-635)
    Hecht [1996]
  • Order out of chaos : man's new dialogue with nature
  • On theroleofanalogiesandmetaphors in learning science
    Duit [1991]
  • On the decrease of entropy in a thermodynamic system by the intervention of intelligent beings
    Szilard [1964]
  • Oersted medal lecture 2001: Physics education research - the key to student learning
    McDermott [2001]
  • Novice use of qualitative versus quantitative problem solving in electrostatics
  • More than misconceptions: Multiple perspectives on student knowledge and reasoning, and an appropriate role for education research
    Hammer More than misconceptions: Multiple perspectives on student knowledge and reasoning [1996]
  • Misconceptions in school thermodynamics
  • Meta Learning and ConceptualChange
    Gunstone White Meta learning and conceptual change [1989]
  • Meaningful learning: The essential factor for conceptual change in limited or inappropriate propositional hierarchies leading to empowerment of learners
    Novak [2002]
  • Matter & interactions (Vol1, pp. 342-375, 414-429)
    Chabay Sherwood Matter & interactions (Vol1 [2002]
  • Macroscopic laws, microscopic dynamics, time's arrow and Boltzmann's entropy
    Lebowitz Macroscopic laws [1993]
  • Knowledge structure and problem solving in physics
    Heller Rief [1982]
  • Knowledge and teaching: Foundations of the new reform
    Sulman Knowledge and teaching foundations of the new reform [1987]
  • Irreversible adiabatic compression of an ideal gas
    Mungan [2003]
  • Irreversibility, entropy production, and thermal efficiency
    Jones Leff Irreversibility [1975]
  • Irreversibility in Simple Systems
    Hobson [1966]
  • Investigation of students' reasoning regarding heat, work, and the first law of thermodynamics in an introductory calculus-based general physics course
    Meltzer Investigation of students' reasoning regarding heat [2004]
  • Investigating a grade11 student's evolving conceptions of heat and temperature
    Grayson Harrison Treagust Investigating a grade 11 student's evolving conceptions of heat and temperature [1999]
  • Introduction of entropy via the Boltzmann distribution in undergraduate physical chemistry: A molecular approach
    Kozliak [2004]
  • Insight into entropy
    Styer [2000]
  • Implications of cognitive studies for teaching physics
    Redish [1994]
  • How to teach statistical thermal physics in an introductory physics course
    Lee [2001]
  • Heat energy and temperature concepts of adolescents, adults, and experts: Implications for curricular improvements
    Lewis Linn Heat energy and temperature concepts of adolescents [1994]
  • Fundamentals of physics (pp. 401-417)
  • Fundamentals of physics (8th ed., pp. 476-555)
    Halliday Resnick Walker Fundamentals of physics (8th ed. [2008]
  • Fundamentals of physics (4th ed., pp.605-628)
    Halliday Resnick Walker Fundamentals of physics (4th ed. [1993]
  • From free expansion to abrupt compression of an ideal gas
  • Force Concept Inventory
  • Explaining irreversibility
    Swendsen [2008]
  • Expert and novice performance in solving physics problems
    Larkin Simon Expert and novice performance in solving physics problems [1980]
  • Evaluating an electricity and magnetism assessment tool: Brief electricity and magnetism assessment
    [2006]
  • Entropy: Conceptual disorder
    Lowe [1988]
  • Entropy production and the second law of thermodynamics: An introduction to second law analysis
    Marcella [1992]
  • Entropy is simple, qualitatively
    Lambert Entropy is simple [2002]
  • Entropy and the second law: A pedagogical alternative
    Baierlein [1994]
  • Entropy and homogeneity
    Rodewald [1990]
  • Entropy and disorder
    Wright [1970]
  • Entropy : a new world view
  • Enhancing the understanding of entropy through computation
  • Engine efficiencies and the second law of thermodynamics
    Tobin [1969]
  • Energy, entropy and exergy concepts and their roles in thermal engineering
    Cengel Dincer Energy [2001]
  • Efficiency' in the teaching of energy
    Viglietta [1990]
  • Economics, ecology, and entropy
    Swaney Economics [1985]
  • Development and assessment of research-based tutorials on heat engines and the second law of thermodynamics
  • Demonstration experiments with a Stirling engine
    [1994]
  • Critical mass: How one thing leads to another. New York: Farrar, Straus and Giroux. 물리학으로 보는 사회: 임계 질량에서 이어지는 사건들
    Ball 이덕환 Critical mass: How one thing leads to another. New York: Farrar [2006]
  • College physical chemistry students' conceptions of equilibrium and fundamental thermodynamics
  • Categorization and representation of physics problems by experts and novices
  • Atkins' physical chemistry (8th ed., pp. 870-875)
    Atkins De Paula Atkins' physical chemistry (8th ed. [2006]
  • Approach to thermal equilibrium in a system with adiabatic constraints
  • An economic analogy to thermodynamics
    Saslow [1999]
  • An approach to equilibrium
    Frisch [1958]
  • An Integrated Approach to Thermodynamics in the Introductory Physics Course
    Alonso Finn [1995]
  • Alternative frameworks, conceptual conflict and accommodation : toward a principled teaching strategy
    Novick Nussbaum Alternative frameworks [1985]
  • All about work
  • A thermodynamic consideration of mechanical equilibrium in the presence of thermally insulating barriers
    Curzon [1969]
  • A study of Turkish chemistry undergraduates' understandings of entropy
  • A statistical development of entropy for the introductory physics course
    Schoepf [2002]
  • A simple model of irreversibility
    Baker [1986]
  • A method for investigating concept understanding in science
  • A different approach to introducing statistical mechanics
  • A close examination of the motion of an adiabatic piston
    Gislason [2010]
  • A Mathematical Theory of Communication
    Shannon W.Weaver A mathematical theory of communication [1948]
  • A Comment on Boltzmann's H-theorem and time reversal
    Eggarter [1973]