High-efficiency technology for solar cells through near-infrared and ultraviolet wavelength conversion and increased light absorption.
A basic explanation of the wavelength conversion and light absorption enhancement technology that is not being effectively utilized, along with an explanation of the mechanisms that are being newly elucidated and the points necessary for practical application.
Chapter 1: Ultraviolet Light - Improving the Power Generation Efficiency of Solar Cells through Conversion of Ultraviolet to Visible and Near-Infrared Light Section 1: Near Ultraviolet to Visible and Near-Infrared Light Conversion Using Nanophosphors and Its Application to Crystalline Silicon Solar Cells Section 2: Development of Organic-Inorganic Composite Ultraviolet-Visible Light Conversion Materials and Their Application to Solar Cells Section 3: Luminescent Supramolecular Gels: Polymerization and Application as Wavelength Converters Section 4: Development of Wavelength Conversion Films Using Sol-Gel Processes and Colloidal Techniques for Solar Cells Section 5: Fabrication of Wavelength Conversion Materials Using Complex Phosphor-Containing Paints and Their Application to Solar Cells Section 6: Development of Rare Earth Complexes with Improved Light Resistance and Their Application to Silicon Solar Cells Section 7: Improving the Power Generation Efficiency of Solar Cells through Ultraviolet-Wavelength Conversion
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Chapter 2: Near-Infrared - Improving Solar Cell Efficiency through Visible Light Conversion Section 1: Development of Ru Complex Dyes Showing Spin-Reversal Excitation and Application to Broad-Band Dye-Sensitized Solar Cells Section 2: Lead-Free Perovskite Solar Cells and Near-Infrared Photoconversion Function Section 3: Infrared to Visible Wavelength Conversion Using Upconversion Phosphors and Application to Solar Cells Section 4: Development of Near-Infrared Harvesting Antenna Technology and Application to Solar Cells Section 5: High-Efficiency Wavelength Conversion of Weak Light Using Optical Antennas Section 6: Development of Dye-Sensitized Solar Cells Incorporating Photosynthesis-Type Concentrating Antenna Structures Chapter 3: Improving Solar Cell Efficiency Using Quantum Dots Section 1: Challenge to High-Efficiency Solar Cells Utilizing Carrier Many-Body Effects in Quantum Nanostructures Section 2: Development of Ultra-High-Efficiency Solar Cell Devices Using Colloidal Quantum Dots Section 3: High-Yield Photonic Energy Conversion Materials and Nanophotonic Droplets
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61560
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P2
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Iso Yuki / Keio University Isobe Tetsuhiko / Keio University Tsujiuchi Yutaka / Akita University Ihara Hirotaka / Kumamoto University Takatou Makoto / Kumamoto University Kuwahara Yutaka / Kumamoto University Kandoku Hirokuni / Kumamoto University Fukuda Takeshi / Saitama University Inoue Koji / Mie Prefectural Industrial Research Institute Tanizawa Yoshihiko / Mie Prefectural Industrial Research Institute Fujiwara Motoyoshi / Mie Prefectural Industrial Research Institute Kato Masataka / Kureha Corporation Segawa Masashi / Sanbic Corporation Kinoshita Takumi / The University of Tokyo Segawa Koji / The University of Tokyo Hayase Shuji / Kyushu Institute of Technology Tomita Tsunezuki / Tokai University Mizusawa Hiroaki / Hokkaido University Ueno Mitsuo / Hokkaido University Oshikiri Tomoya / Hokkaido University Ishihara Hajime / Osaka Prefecture University Yokoe Nobuhiko / Osaka Prefecture University Oisaka Yoshiki / Osaka Prefecture University Asaoka Sadayuki / Kyoto Institute of Technology Kanemitsu Yoshihiko / Kyoto University Omata Takahisa / Osaka University Asano Hiroshi / Osaka University Tate Naoya / Kyushu University
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S&T Publishing publishes technical books aimed at researchers and engineers.