Preface |
Introduction to carbon materials / 1: |
Introduction / 1.1: |
Graphite / 1.1.1: |
Diamond / 1.1.2: |
Fullerene / 1.1.3: |
The graphite family / 1.2: |
Graphite and turbostratic carbon / 1.2.1: |
Carbon fibers and nanofibers / 1.2.2: |
Carbon nanotubes / 1.2.3: |
Intercalated graphite / 1.2.4: |
Graphite oxide / 1.2.5: |
Exfoliated graphite / 1.2.6: |
Flexible graphite / 1.2.7: |
Graphene / 1.2.8: |
Activated carbon / 1.2.9: |
Carbon black / 1.2.10: |
Carbon-carbon composites / 1.2.11: |
The diamond family / 1.3: |
Diamond-like carbon / 1.3.1: |
Graphane |
The fullerene family / 1.4: |
References |
Structure of graphite and carbon in the graphite family / 2: |
Fabrication of graphite / 2.2: |
Polycrytalline graphite / 2.2.1: |
Graphite flakes / 2.2.2: |
Pyrolytic graphite / 2.2.3: |
Properties of graphite / 2.3: |
Reciprocal lattice / 2.4: |
Electronic energy bands / 2.5: |
Magnetic energy levels / 2.6: |
Electrical properties / 2.7: |
Lattice vibrations / 2.8: |
Graphite intercalation compounds / 2.9: |
Classification of graphite intercalation compounds / 2.9.1: |
Covalent intercalation compounds / 2.9.2: |
Graphite oxide (graphitic acid) / 2.9.2.1: |
Carbon monofluoride (graphite monofluoride) / 2.9.2.2: |
Tetracarbon monofluoride / 2.9.2.3: |
Ionic intercalation compounds / 2.9.3: |
Graphite-halogens / 2.9.3.1: |
Graphite-alkali metals / 2.9.3.2: |
Graphite-acid compounds / 2.9.3.3: |
Graphite-halide compounds / 2.9.3.4: |
Intercalated graphite fibers / 2.9.4: |
Structure and formation / 2.10: |
Viscoelastic and elastomeric properties / 2.10.2: |
Dielectric properties / 2.10.3: |
Thermal and electrical conductivities / 2.10.4: |
Adsorption and filtration behavior / 2.10.5: |
Electronic structure of graphene / 2.11: |
Optical behavior / 3.3: |
Defects in graphene / 3.4: |
Mechanical behavior / 3.5: |
Preparation of graphene / 3.6: |
Preparation of graphene by the cleavage of graphite / 3.6.1: |
Preparation of graphene by the mechanical disintegration of intercalated graphite / 3.6.2: |
Preparation of graphene by the chemical reduction of graphene oxide / 3.6.3: |
Preparation of graphene by nonoxidizing liquid exfoliation / 3.6.4: |
Preparation of graphene by chemical vapor deposition / 3.6.5: |
Graphene yarns / 3.7: |
Graphene paper / 3.8: |
Graphene foam / 3.9: |
Graphene ink / 3.10: |
Graphene quantum dots / 3.11: |
Doping of graphene / 3.12: |
Hybrids of graphene and carbon nanotubes / 3.13: |
Hybrids of graphene and carbon fibers / 3.14: |
Hybrids of graphene and electrochemical electrode materials / 3.15: |
Fabrication / 4: |
Structure / 4.3: |
Squish ability and compaction / 4.4: |
Application in thermal interface materials / 4.5: |
Application as an electrically conductive additive / 4.6: |
Dielectric behavior / 4.7: |
Viscoelastic behavior / 4.8: |
Nanoindentation behavior / 4.8.1: |
Dynamic mechanical properties / 4.8.2: |
Carbon black composites / 4.9: |
Competing materials / 4.10: |
Market and applications / 4.11: |
Structure of activated carbon / 5: |
Adsorption / 5.2: |
Forms of activated carbon / 5.3: |
Granular activated carbon / 5.3.1: |
Powdered activated carbon / 5.3.2: |
Extruded activated carbon / 5.3.3: |
Bead activated carbon / 5.3.4: |
Activated carbon assemblies / 5.4: |
Honeycomb carbon filters / 5.4.1: |
Activated carbon blocks with hollow channels / 5.4.2: |
Activated carbon foam / 5.4.3: |
Activated carbon foam assemblies / 5.4.4: |
Activated carbon fiber fabric / 5.4.5: |
Activated carbon composites / 5.4.6: |
Fabrication of activated carbon / 5.5: |
Steam activation / 5.5.1: |
Gas activation / 5.5.2: |
Chemical activation / 5.5.3: |
Regeneration of activated carbon / 5.6: |
Processing-structure-properly relationships of activated carbon / 5.7: |
Applications of activated carbon / 5.8: |
Water purification / 5.8.1: |
Air purification / 5.8.2: |
Gas purification / 5.8.3: |
Waste treatment / 5.8.4: |
Carbon dioxide capture / 5.8.5: |
Heat pumps and refrigeration / 5.8.6: |
Electrochemical components / 5.8.7: |
Catalyst support / 5.8.8: |
Market of activated carbon / 5.9: |
Carbon fibers / 6: |
Applications and market / 6.1: |
Continuous fiber assemblies / 6.3: |
Discontinuous fibers / 6.4: |
Microstructure / 6.5: |
Continuous carbon fibers vs. other materials / 6.6: |
Carbon fiber composites / 6.8: |
Carbon nanofibers and nanotubes / 7: |
Structure of carbon nanofibers and nanotubes / 7.1: |
Properties of carbon nanofibers and nanotubes / 7.3: |
Mats and yams of CNFs/CNTs / 7.4: |
Mats / 7.4.1: |
Fabrication of mats / 7.4.1.1: |
Electrical and electromagnetic behavior of mats / 7.4.1.2: |
Mechanical behavior of mats / 7.4.1.3: |
Electrochemical behavior of mats / 7.4.1.4: |
Yarns / 7.4.2: |
Fabrication of yarns / 7.4.2.1: |
Mechanical behavior of yarns / 7.4.2.2: |
Assemblies involving CNTs/CNFs / 7.5: |
Vertically aligned CNTs / 7.5.1: |
CMF/CNT with filled core channel / 7.5.2: |
CNFs/CNTs grown on carbon fibers / 7.5.3: |
CNTs grown on carbon black / 7.5.4: |
CNTs grown on graphene, reduced graphene oxide or exfoliated graphite / 7.5.5: |
Carbon deposited on CNTs / 7.5.6: |
CNTs grown on alumina / 7.5.7: |
CNTs grown on silica fibers / 7.5.8: |
CNFs grown on cordierite / 7.5.9: |
CNTs grown on metals / 7.5.10: |
CNTs attached to polymers / 7.5.11: |
CNFs/CNTs mixed with electrochemical electrode material / 7.5.12: |
Fabrication of carbon nanofibers and nanotubes / 7.6: |
Fabrication of carbon nanofibers/nanotubes from carbonaceous gases / 7.6.1: |
Fabrication of carbon nanofibers from electro spun polymer nanofibers / 7.6.2: |
Graphitization of carbon nanofibers / 7.6.4: |
Index / 7.7: |
Preface |
Introduction to carbon materials / 1: |
Introduction / 1.1: |