TUM Library

Green Energy Materials Handbook gives a systematic review of the development of reliable, low-cost, and high-performance green energy materials, covering mainstream computational and experimental studies as well as comprehensive literature on green energy materials, computational methods, experimental fabrication and characterization techniques, and recent progress in the field. This work presents complete experimental measurements and computational results as well as potential applications. Among green technologies, electrochemical and energy storage technologies are considered as the most practicable, environmentally friendly, and workable to make full use of renewable energy sources. This text includes 11 chapters on the field, devoted to 4 important topical areas: computational material design, energy conversion, ion transport, and electrode materials. This handbook is aimed at engineers, researchers, and those who work in the fields of materials science, chemistry, and physics. The systematic studies proposed in this book can greatly promote the basic and applied sciences.

<OL><LI>Introduction</LI><P><LI>Molecular effects of functional polymer binders on Li<SUP>+</SUP> transport on the cathode surface within lithium ion battery</LI><P></P><P>2.1 Introduction</P><P>2.2 Molecular dynamics simulation details</P><P>2.3 Results and discussion</P><P>2.4 Summary and future perspectives</P><P><LI>Essential properties of Li/Li<SUP>+</SUP> graphite intercalation compounds</LI><P></P><P>3.1 Introduction</P><P>3.2 The theoretical model</P><P>3.3 Rich geometric structures of graphites and graphite intercalation compounds</P><P>3.4 Unusual band structures of graphite-related systems</P><P>3.5 van Hove singularities in density of states</P><P>3.6 Chemical bondings and charge distributions</P><P>3.7 Summary</P><P><LI>Defective and amorphous graphene as anode materials for Li-ion batteries: a first-principles study</LI><P></P><P>4.1 Introduction</P><P>4.2 Computational methods</P><P>4.3 Results and discussions</P><P>4.4 Conclusion</P><P><LI>Rich Essential Properties of Si-Doped Graphene</LI><P></P><P>5.1 Introduction</P><P>5.2 Computational methods</P><P>5.3 Geometric structures of Si-adsorbed and Si-substituted graphene</P><P>5.4 Rich electronic structures</P><P>5.5 Spatial charge densities</P><P>5.6 The diverse density of states</P><P>5.7 Summary</P><P><LI>Diversified essential properties in transition metals adsorbed Graphene</LI><P></P><P>6.1 Introduction</P><P>6.2 The theoretical model</P><P>6.3 Results and discussions</P><P>6.4 Summary</P><P><LI>Combining neural network with first-principles calculations for computational screening of electrolyte additives in lithium ion batteries</LI><P></P><P>7.1 Introduction</P><P>7.2 Materials and methods</P><P>7.3 Results and disscussions</P><P>7.4 Conclusion</P><P><LI>Metal oxide-reduced graphene oxide (MO-RGO) nanocomposite as high performance anode materials in Lithium ion batteries </LI><P></P><P>8.1 Introduction</P><P>8.2 Potential binary metal oxides asanode materials in LIBs</P><P>8.3 Complex metal oxides as anode materials in LIBs</P><P>8.4 Metal oxide-graphene/reduced graphene oxide nanocomposite as anode materials in LIBs</P><P>8.5 Our research contribution toward LIB</P><P>8.6 Conclusions</P><P><LI>In-situ X-ray and Neutron Analysis Techniques on Lithium/Sodium ion batteries</LI><P></P><P>9.1 Introduction</P><P>9.2 Methodology for in-situ X-ray and neutron scattering experiments</P><P>9.3 In-situ X-ray analysis on synergistic effects of Si anode materials</P><P>9.4 In-operando X-ray diffraction -- a quantitative analysis on Si-graphite negative electrode</P><P>9.5 In-situ X-ray diffraction analysis of lithiation-induced crystal restructuring of Sn/TiO2 nanocrystallites</P><P>9.6 In-operando neutron diffraction analysis on low temperature lithium diffusion behaviors in 18650 Li-ion battery</P><P>9.7 In-operando neutron diffraction Studies on P2-Na2/3Fe1/3Mn2/3O2 cathode in a sodium ion battery</P><P>9.8 Summary</P><P><LI>Micro-Phase Separated poly(VdF-co-HFP)/Ionic Liquid/Carbonate as Gel Polymer Electrolytes for Lithium-Ion Batteries</LI><P></P><P>10.1 Introduction</P><P>10.2 Experimental</P><P>10.3 Results and discussion</P><P>10.4 Conclusion</P><P><LI>Gel and solid electrolytes for Lithium ion batteries</LI><P></P><P>11.1 Introduction</P><P>11.2 Solid-state electrolytes (SSEs)</P><P>11.3 Gel Polymer Electrolytes (GPEs)</P><P>11.4 Summary</P><P><LI>Silicon-Nanowire Based Hybrid Solar Cells</LI><P></P><P>12.1 Introduction</P><P>12.2 Silicon nanowires fabrication</P><P>12.3 PEDOT: PSS polymer as the p-type layer of hybrid solar cell application</P><P>12.4 Silicon Nanowire based Hybrid Solar Cells</P><P>12.5 Conclusion</P><P><LI>Characterization and Performance of Li-ZnO Nanofiber and Nanoforest Photoanodes for Dye-sensitized Solar Cell</LI><P></P><P>13.1 Introduction</P><P>13.2 Experimental</P><P>13.3 Results and discussion</P><P>13.4 Conclusion</P><P><LI>Review of monolithic dye-sensitized solar cells and perovskite solar cells</LI><P></P></OL><P>14.1 Introduction</P><P>14.2 Monolithic dye-sensitized solar cells</P><OL><OL><P><LI>Mesoporous electrode for monolithic perovskite solar cells</LI><P></P><P><LI>Conclusion</LI></OL></OL><P>15. High-Performance Quasi-Solid-State Polymer Electrolytes for Dye-Sensitized Solar Cell Applications</P><P>16. Concluding Remarks </P><P>17. Perspective on Battery Research </P><P>Index</P>

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