연구동향 분석

A new simple route to grow Cu(In,Ga)Se2 thin films with large grains in the co-evaporation process

김승태 김기환 윤재호 안병태 2018년

논문상세정보
    • 저자 김승태 김기환 윤재호 안병태
    • 제어번호 105894374
    • 학술지명 Current Applied Physics
    • 권호사항 Vol. 18 No. 8 [ 2018 ]
    • 발행처 한국물리학회
    • 자료유형 학술저널
    • 수록면 912-918
    • 언어 English
    • 출판년도 2018
    • 등재정보 KCI등재
    • 판매처
    유사주제 논문( 0)
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' A new simple route to grow Cu(In,Ga)Se2 thin films with large grains in the co-evaporation process' 의 참고문헌

  • Velumani, Structural properties of <TEX>$In_2Se_3$</TEX> precursor layers deposited by spray pyrolysis and physical vapor deposition for CuInSe2 thin-film solar cell applications
  • The equilibrium phase diagram of the copper-indium system:a new investigation
  • The Cu-ln (Copper-Indium) system
  • Surface modification of CIGS film by annealing and its effect on the band structure and photovoltaic properties of CIGS solar cells
    신영민 [2015]
  • Structure crystalline du seleniured Indium <TEX>$In_2Se_3$</TEX>
  • Review of progress toward 20% efficiency flexible CIGS solar cells and manufacturing issues of solar modules
    P. Reinhard [2012]
  • Reduction of point defects and Cu surface composition in Cu(In,Ga)Se2 film by Se annealing with a NaF overlayer at intermediate temperatures
  • Raman investigations of <TEX>$Cu(In,Ga)Se_2$</TEX> thin films with various copper contents
    W. Witte [2008]
  • Raman investigation of InSe and GaSe single-crystals oxidation
  • Polycrystalline thin film solar cells: present status and future potential
  • Microstructural properties of <TEX>$(In,Ga)_2Se_3$</TEX> precursor layers for efficient CIGS thin-film solar cells
    T. Mise [2009]
  • Interdependence of absorber composition and recombination mechanism in Cu <TEX>$(In,Ga)(Se,S)_2$</TEX> heterojunction solar cells
    M. Turcu [2002]
  • Improved photocurrent in <TEX>$Cu(In,Ga)Se_2$</TEX> solar cells: from 20.8% to 21.7% efficiency with CdS buffer and 21.0% Cd-free
  • Highly Efficient <TEX>$Cu(In,Ga)Se_2$</TEX> Solar Cells Grown on Flexible Polymer Films
    A. Chirila [2011]
  • Fabrication of a smooth, large-grained <TEX>$Cu(In,Ga)Se_2$</TEX> thin film using a Cu/<TEX>$(In,Ga)_2Se_3$</TEX> stacked precursor at low temperature for CIGS solar cells
    G.S. Jung [2015]
  • Effects of the incorporation of alkali elements on <TEX>$Cu(In,Ga)Se_2$</TEX> thin film solar cells
    D. Shin [2016]
  • Effects of heavy alkali elements in <TEX>$Cu(In,Ga)Se_2$</TEX> solar cells with efficiencies up to 22.6%
    P. Jackson [2016]
  • Effects of CdS buffer layers on photoluminescence properties of <TEX>$Cu(In,Ga)Se_2$</TEX> solar cells
  • Defect physics of the <TEX>$CuInSe_2$</TEX> chalcopyrite semiconductor
    S.B. Zhang [1998]
  • Defect formation in <TEX>$Cu(In,Ga)Se_2$</TEX> thin films due to the presence of potassium during growth by low temperature co-evaporation process
    F. Pianezzi [2013]
  • Co-evaporation of <TEX>$Cu(In,Ga)Se_2$</TEX> at low temperatures: an in-situ x-ray growth analysis
  • Characterization of CuInse2 and InxSey thin film by co-evaporation method
    S.H. Kwon [1997]
  • Change in crystalline morphologies of polycrystalline silicon films prepared by radio-frequency plasmaenhanced chemical vapor deposition using <TEX>$SiF_4$</TEX>+<TEX>$H_2$</TEX> gas mixture at 350<TEX>$^{\circ}C$</TEX>
    T. Kaneko [1994]
  • A new approach to high-efficiency solar cells by band gap grading in <TEX>$Cu(In,Ga)Se_2$</TEX> chalcopyrite semiconductors