Linked e-resources
Details
Table of Contents
Preface; Contents; 1 Hybrid Solar Cells: Effects of the Incorporation of Inorganic Nanoparticles into Bulk Heterojunction Organic Solar Cells; 1 Introduction; 2 Organic Solar Cells; 3 Semiconductor Nanoparticles in Organic Solar Cells; 3.1 Cd-Based Inorganic Nanoparticles; 3.2 Pb-Based Inorganic Nanoparticles; 4 Metal Nanoparticles in Organic Solar Cells; 5 Conclusions and Perspectives; Acknowledgements; References; 2 Nanomaterials for Solar Energy Conversion: Dye-Sensitized Solar Cells Based on Ruthenium(II) tris-Heteroleptic Compounds or Natural Dyes; 1 Aims and Scope; 2 Introduction.
2.1 Dye-Sensitized Solar Cells-Principles and Operation2.2 Performance Experiments; 3 Current-Voltage (I × V) Curves; 4 Photocurrent Action Spectra; 4.1 Molecular Engineering; 5 Ruthenium tris-Heteroleptic Complexes; 5.1 2,22 Bipyridine Derivative Ligands; 6 Amphiphilic Compounds; 7 Donor Antenna Compounds; 8 Thiophene Compounds; 8.1 1,10-Phenanthroline Derivative Ligands; 9 Natural Dyes; 10 Conclusion; Acknowledgements; References; 3 Photocatalytic Water Splitting by Suspended Semiconductor Particles; 1 Introduction; 2 An Overview of Semiconductor Materials Applied to Solar Water Splitting.
2.1 UV Light Active Photocatalysts2.2 Visible Light Active Photocatalysts; 2.2.1 Native Visible Light Absorber Materials; 2.2.2 Metal Doping of Wide Band Gap Semiconductors; 2.2.3 Nonmetal Doping of Wide Band Gap Semiconductors; 2.2.4 Self-doped Photocatalyst; 2.2.5 Heterojunctions Photocatalysts; 3 The Tandem Concept for Water Splitting on Particulate Photocatalysts; 4 Efficiency Determination in Solar Water Splitting; 4.1 STH (Solar-to-Hydrogen) Efficiency; 4.2 Apparent Quantum Efficiency (AQE); 5 Conclusion; References.
4 Latest Advances on the Columnar Nanostructure for Solar Water Splitting1 Introduction; 2 Colloidal Deposition; 3 Hydrothermal-Assisted Synthesis; 4 Conclusion and Perspectives; References; 5 Biofuel Cells; 1 Introduction; 2 Fundamental Aspects in BFCs Development; 3 Power Energy and Thermodynamics in BFCs; 4 Nanostructured Materials Applied to Modified Electrodes and BFCs; 5 Enzyme-Based Modified Electrodes Applied to BFCs; 6 Microbial-Based Modified Electrodes Applied to BFCs; 7 Implantable BFCs; 8 Bio-inspired Catalysts; 9 Perspectives on Green Energy Generation and Future Applications.
2.1 Dye-Sensitized Solar Cells-Principles and Operation2.2 Performance Experiments; 3 Current-Voltage (I × V) Curves; 4 Photocurrent Action Spectra; 4.1 Molecular Engineering; 5 Ruthenium tris-Heteroleptic Complexes; 5.1 2,22 Bipyridine Derivative Ligands; 6 Amphiphilic Compounds; 7 Donor Antenna Compounds; 8 Thiophene Compounds; 8.1 1,10-Phenanthroline Derivative Ligands; 9 Natural Dyes; 10 Conclusion; Acknowledgements; References; 3 Photocatalytic Water Splitting by Suspended Semiconductor Particles; 1 Introduction; 2 An Overview of Semiconductor Materials Applied to Solar Water Splitting.
2.1 UV Light Active Photocatalysts2.2 Visible Light Active Photocatalysts; 2.2.1 Native Visible Light Absorber Materials; 2.2.2 Metal Doping of Wide Band Gap Semiconductors; 2.2.3 Nonmetal Doping of Wide Band Gap Semiconductors; 2.2.4 Self-doped Photocatalyst; 2.2.5 Heterojunctions Photocatalysts; 3 The Tandem Concept for Water Splitting on Particulate Photocatalysts; 4 Efficiency Determination in Solar Water Splitting; 4.1 STH (Solar-to-Hydrogen) Efficiency; 4.2 Apparent Quantum Efficiency (AQE); 5 Conclusion; References.
4 Latest Advances on the Columnar Nanostructure for Solar Water Splitting1 Introduction; 2 Colloidal Deposition; 3 Hydrothermal-Assisted Synthesis; 4 Conclusion and Perspectives; References; 5 Biofuel Cells; 1 Introduction; 2 Fundamental Aspects in BFCs Development; 3 Power Energy and Thermodynamics in BFCs; 4 Nanostructured Materials Applied to Modified Electrodes and BFCs; 5 Enzyme-Based Modified Electrodes Applied to BFCs; 6 Microbial-Based Modified Electrodes Applied to BFCs; 7 Implantable BFCs; 8 Bio-inspired Catalysts; 9 Perspectives on Green Energy Generation and Future Applications.