Search Results - Chemical Reviews

LITHIUM-ION BATTERIES AND SOLAR CELLS; PHYSICAL, CHEMICAL, AND MATERIALS PROPERTIES

Taylor & Francis
OCLC metadata license agreement

Carbon nanomaterials : modeling, design, and applications /

Taylor & Francis
OCLC metadata license agreement

Separation process essentials / by Lane, Alan M.

Taylor & Francis
OCLC metadata license agreement

Green energy materials handbook / by Lin, Ming-Fa, Hsu, Wen-Dung

Table of Contents: “…<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. …”
Taylor & Francis
OCLC metadata license agreement

Corrosion protection for the oil and gas industry : pipelines, subsea equipment, and structures / by Okyere, Mavis Sika

Taylor & Francis
OCLC metadata license agreement

The handbook of polyhydroxyalkanoates.

Taylor & Francis
OCLC metadata license agreement

Structure- and adatom-enriched essential properties of graphene nanoribbons / by Lin, Shih-Yang

Taylor & Francis
OCLC metadata license agreement

Carbon nanotubes and nanoparticles : current and potential applications /

Table of Contents: “…Panda, and Anujit Ghosal -- Carbon nanotubes and their applications in chemical engineering science : a far-reaching review / Sukanchan Palit -- The hydrogen batteries based on carbon nanotubes / I.A. …”
Taylor & Francis
OCLC metadata license agreement

Advanced fracture mechanics and structural integrity / by Saxena, A. (Ashok)

Taylor & Francis
OCLC metadata license agreement

Testing of construction materials by A., Bahurudeen

Taylor & Francis
OCLC metadata license agreement

Autofrettage Processes Technology and Modelling. by Dixit, Uday S.

Taylor & Francis
OCLC metadata license agreement