| Description |
1 online resource (368 pages). |
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text file |
| Series |
Renewable Energy: Research, Development and Policies Ser.
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Renewable Energy: Research, Development and Policies Ser.
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| Contents |
Intro; Contents; Introduction; Acronyms; Chapter 1; Hybrid Organo-Inorganic Perovskite Solar Cells: Architecture Evolution, Materials of Functional Layers, Photoelectric Characteristics, Properties, and Efficiency; Abstract; 1. Introduction; 2. The Architecture of Hybrid Organo-Inorganic Perovskite Solar Cells; 2.1. Architecture with Bulk Heterojunction; 2.2. Planar Architecture; 2.3. The Architecture with One Selective Conducting Buffer Layer; 2.4. Fully Mesoscopic Architecture without a Hole Carrier; 2.5. Tandem Organic-Inorganic Perovskite Photovoltaic Systems |
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3. Materials and Formation Methods of the Main Functional Layers of Hybrid Organo-Inorganic Perovskite Solar Cells3.1. Hybrid Organo-Inorganic Perovskite Absorbers; 3.2. Buffer Layers of Hybrid Organo-Inorganic Solar Cells; 3.2.1. Electron-Conducting Buffer Layers (Anodes); 3.2.2. Hole-Conducting Buffer Layers (Cathodes); 3.2.2.1. Organic and Polymeric P-Type Conducting Materials; 3.2.2.2. Inorganic P-Type Conducting Materials; 3.2.2.2.1. Hole-Conducting Materials Based on Copper (I) Iodide (Cui) and Copper (I) Thiocyanate (Cuscn); 3.2.2.2.2. Iodide of Copper (I) (CuI) |
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3.2.2.2.3. The Copper (I) Thiocyanate (CuSCN)3.2.2.2.4. Methods for Obtaining CuI and CuSCN Thin Films; Spin-Coating Application; Vacuum Methods of Application; Method of Molecular Layering; 3.2.2.2.5. Hole-Conducting Materials Based on Copper (I) and (II) Oxide (Cu2O and CuO); 3.2.2.2.6. Hole-Conducting Materials Based on Nickel Oxide (NiO); 3.2.2.2.7. Hole-Conducting Materials Based on Molybdenum (VI) Oxide (MoO3); 3.2.2.2.8. Hole-Conducting Materials Based on Vanadium Oxide (VOx); 3.3. Selection of Materials of Buffer Layers and Ohmic Contacts |
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4. Electronic Processes, Photoelectric Characteristics and Stability of Hybrid Organo-Inorganic Perovskite Solar Cells4.1. Parameters and Characteristics of Solar Cells; 4.2. Electronic Processes in Hybrid Organic-Inorganic Perovskite Solar Cells; 4.2.1. Principles of Photoelectric Conversion in Semiconductor Heterostructures and Analysis of Real Achievable Photoelectric Conversion Results in Perovskite Systems; 4.3. Efficiency of Hybrid Organic-Inorganic Perovskite Solar Cells; 4.4. Stability and Photoelectric Hysteresis; Conclusion; References; Chapter 2 |
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Mechanisms of Radiation-Induced Degradation of Hybrid Perovskites Based Solar Cells and Ways to Increase Their Radiation ToleranceAbstract; 1. Introduction; 2. General Methodology of Radiation Physics; 3. Mechanisms of Degradation Under the Effect of Solar Radiation; 4. Mechanism of Degradation under the Action of High Energy Particles (A Special Role of an Organic Molecule); 5. Features of Radiation Degradation of SCs with Fractal Interfaces; 6. Degradation Macroeffects in Perovskites; 6.1. Radiation-Stimulated Diffusion; 6.2. Quasi-Chemical Reactions; 6.3. Radiation Annealing |
| Note |
7. The Hoke Effect in Hybrid Perovskites |
| Local Note |
eBooks on EBSCOhost EBSCO eBook Subscription Academic Collection - North America |
| Subject |
Perovskite solar cells.
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Perovskite solar cells. |
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Solar cells -- Materials.
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Solar cells -- Materials. |
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Solar cells. |
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Photovoltaic cells -- Materials.
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Photovoltaic cells -- Materials. |
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Photovoltaic cells. |
| Genre/Form |
Electronic books.
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| Other Form: |
Print version: Banavoth, Murali. Perovskite Solar Cells: Properties, Application and Efficiency. New York : Nova Science Publishers, Incorporated, ©2019 9781536158588 |
| ISBN |
1536158593 |
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9781536158595 (electronic book) |
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