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This book provides practical platform to the readers for facile preparation of various forms of carbons in its nano format, investigate their structure-property relationship and finally realize them for a variety of applications taking the route of application engineering including properties and various factors associated with them.
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This book provides practical platform to the readers for facile preparation of various forms of carbons in its nano format, investigate their structure-property relationship and finally realize them for a variety of applications taking the route of application engineering including properties and various factors associated with them.
Produktdetails
- Produktdetails
- Verlag: CRC Press
- Seitenzahl: 336
- Erscheinungstermin: 13. Februar 2023
- Englisch
- Abmessung: 254mm x 178mm x 21mm
- Gewicht: 844g
- ISBN-13: 9781032329000
- ISBN-10: 1032329009
- Artikelnr.: 66266934
- Verlag: CRC Press
- Seitenzahl: 336
- Erscheinungstermin: 13. Februar 2023
- Englisch
- Abmessung: 254mm x 178mm x 21mm
- Gewicht: 844g
- ISBN-13: 9781032329000
- ISBN-10: 1032329009
- Artikelnr.: 66266934
Dr. Ashwini P. Alegaonkar is working in the areas of Materials Chemistry. She has obtained her M. Phil. degree in the year 2014 and Ph.D. degree in Chemistry in 2019 from Department of Chemistry, SP Pune University. Her area of research includes spin transport and magnetic correlations in nano-carbon systems, adatom doping in graphene, graphene derivatives, and 2D heterojunctions for energy storage and device applications. She has number of papers in the journals of international repute, and book chapters. Dr. Prashant S. Alegaonkar is working in the areas of Applied Physics. He obtained his Ph.D. from Department of Physics, SP Pune University in 2004, and postdoc from SAINT, SKKU, Korea in 2008. He served as the faculty of Physics in College of Engineering Pune (CoEP), Assistant Professor in Defence Institute of Advanced Technology, Pune and currently working as Associate Professor in Physics in Central University of Punjab at Bathinda. His research interest includes CVD synthesis and super-growth of carbon nanotubes, graphene, reduced graphene, graphene oxide for targeted applications of military and civil origin. He has more than 150 international papers, 75+ conference proceedings, 2100+ Google scholar citations with h- and i-10 index, respectively, 25 and 45.
1. Introduction and survey. 1.1. Status of carbon.1.2. Scope of
nano-carbons . References. 2. Preparation and evaluation of nano-carbons.
2.1. 0-D carbon systems: carbon nanoparticles (CNP) /spheres (CNS). 2.2.
Carbon nanotubes: 1-D format of carbon. 2.3. 2D graphene. 2.4. Foundry
processed 3D graphite: variable density effect. 2.5. 4D orthogonal carbon
fabric. References. 3. Hydrodynamics and shock absorption properties of
nano-carbon . 3.1. Explosion: Background. 3.2. Laboratory synthesis: the
survey. 3.3. Experimental simulation of blast: the instrumentation. 3.4.
GNF for shock absorbing application. 3.5. Surface interactions of transonic
shock wave with GLNR. 3.6. Hydrodynamics response of nanocarbons: CNS vs
GNF. 3.7. Blast mitigation parameters for PNCs. References. 4. Microwave
scattering and radar absorption coating properties of nanocarbon. 4.1.
Radar know-hows: the background. 4.2. Microwave scattering mechanism: the
Maxwellian formulation. 4.3. Shielding performance of materials architected
. 4.4. Graphene and graphene derivatives for shielding. References. 5. Heat
transfer and thermodynamics in micro graphitic nozzles. 5.1.
Thermo-physical assessments of variable density graphite. 5.2. High
temperature thermodynamics in rocket motor nozzles. References. 6.
Electrochemistry and energy storage devices made up of carbon nano
particles. 6.1. High performance tellurium-reduced graphene oxide
pseudo-capacitor. 6.2. Fabrication of flexible and durable supercell made
up of carbon-nano-sphere. 6.3. Self-assembled two-dimensional
heterostructure of rGO/MoS2/h-BN (GMH). References. 7. Magnetism in
otherwise non-magnetic nano-carbon and its derivatives. 7.1. Spin transport
and magnetic correlation in GNCs doped with nitrogen. 7.2. Spin dynamics in
GNCs vs graphene: role of adatom. 7.3. Molecular-spintronics in 2D carbon
with adatom. 7.4. Tetrakis(dimethylamino) ethylene induced magnetism .
References. 8. Multi-functional nano-carbons: from meta-materials to
non-liner optics and gas sensing to mechanically tough fibre mat
application. 8.1. Multi-functional aspect: optical gas sensing and EMI
shielding. 8.2. Split ring resonators: Ferro-nano-carbon metamaterials.
8.3. Mechanical properties of GNCs nano-composites. 8.4 . Mechanical
properties of electrospun PVA/CNT composite nanofibers. References. 9.
Application engineering of nano-carbon-reinforced composites. 9.1 Field
electron emission aspects of CNTs: the paste approach. 9.2. TiO2 coated
CNTs: dye sensitized solar cells. 9.3. CNT embedded nylon nanofiber bundles
by electrospinning. References. 10. Poly-nano-carbons: ion-track membranes
for devices and nuclear radiation induced modifications for
opto-electronics . 10.1. Emergence of nano-ion track membrane for flat
flexible devices. 10.2. Opto-electronic properties of radiation induced
modified poly-carbon. References. 11. Summary and outlook
nano-carbons . References. 2. Preparation and evaluation of nano-carbons.
2.1. 0-D carbon systems: carbon nanoparticles (CNP) /spheres (CNS). 2.2.
Carbon nanotubes: 1-D format of carbon. 2.3. 2D graphene. 2.4. Foundry
processed 3D graphite: variable density effect. 2.5. 4D orthogonal carbon
fabric. References. 3. Hydrodynamics and shock absorption properties of
nano-carbon . 3.1. Explosion: Background. 3.2. Laboratory synthesis: the
survey. 3.3. Experimental simulation of blast: the instrumentation. 3.4.
GNF for shock absorbing application. 3.5. Surface interactions of transonic
shock wave with GLNR. 3.6. Hydrodynamics response of nanocarbons: CNS vs
GNF. 3.7. Blast mitigation parameters for PNCs. References. 4. Microwave
scattering and radar absorption coating properties of nanocarbon. 4.1.
Radar know-hows: the background. 4.2. Microwave scattering mechanism: the
Maxwellian formulation. 4.3. Shielding performance of materials architected
. 4.4. Graphene and graphene derivatives for shielding. References. 5. Heat
transfer and thermodynamics in micro graphitic nozzles. 5.1.
Thermo-physical assessments of variable density graphite. 5.2. High
temperature thermodynamics in rocket motor nozzles. References. 6.
Electrochemistry and energy storage devices made up of carbon nano
particles. 6.1. High performance tellurium-reduced graphene oxide
pseudo-capacitor. 6.2. Fabrication of flexible and durable supercell made
up of carbon-nano-sphere. 6.3. Self-assembled two-dimensional
heterostructure of rGO/MoS2/h-BN (GMH). References. 7. Magnetism in
otherwise non-magnetic nano-carbon and its derivatives. 7.1. Spin transport
and magnetic correlation in GNCs doped with nitrogen. 7.2. Spin dynamics in
GNCs vs graphene: role of adatom. 7.3. Molecular-spintronics in 2D carbon
with adatom. 7.4. Tetrakis(dimethylamino) ethylene induced magnetism .
References. 8. Multi-functional nano-carbons: from meta-materials to
non-liner optics and gas sensing to mechanically tough fibre mat
application. 8.1. Multi-functional aspect: optical gas sensing and EMI
shielding. 8.2. Split ring resonators: Ferro-nano-carbon metamaterials.
8.3. Mechanical properties of GNCs nano-composites. 8.4 . Mechanical
properties of electrospun PVA/CNT composite nanofibers. References. 9.
Application engineering of nano-carbon-reinforced composites. 9.1 Field
electron emission aspects of CNTs: the paste approach. 9.2. TiO2 coated
CNTs: dye sensitized solar cells. 9.3. CNT embedded nylon nanofiber bundles
by electrospinning. References. 10. Poly-nano-carbons: ion-track membranes
for devices and nuclear radiation induced modifications for
opto-electronics . 10.1. Emergence of nano-ion track membrane for flat
flexible devices. 10.2. Opto-electronic properties of radiation induced
modified poly-carbon. References. 11. Summary and outlook
1. Introduction and survey. 1.1. Status of carbon.1.2. Scope of
nano-carbons . References. 2. Preparation and evaluation of nano-carbons.
2.1. 0-D carbon systems: carbon nanoparticles (CNP) /spheres (CNS). 2.2.
Carbon nanotubes: 1-D format of carbon. 2.3. 2D graphene. 2.4. Foundry
processed 3D graphite: variable density effect. 2.5. 4D orthogonal carbon
fabric. References. 3. Hydrodynamics and shock absorption properties of
nano-carbon . 3.1. Explosion: Background. 3.2. Laboratory synthesis: the
survey. 3.3. Experimental simulation of blast: the instrumentation. 3.4.
GNF for shock absorbing application. 3.5. Surface interactions of transonic
shock wave with GLNR. 3.6. Hydrodynamics response of nanocarbons: CNS vs
GNF. 3.7. Blast mitigation parameters for PNCs. References. 4. Microwave
scattering and radar absorption coating properties of nanocarbon. 4.1.
Radar know-hows: the background. 4.2. Microwave scattering mechanism: the
Maxwellian formulation. 4.3. Shielding performance of materials architected
. 4.4. Graphene and graphene derivatives for shielding. References. 5. Heat
transfer and thermodynamics in micro graphitic nozzles. 5.1.
Thermo-physical assessments of variable density graphite. 5.2. High
temperature thermodynamics in rocket motor nozzles. References. 6.
Electrochemistry and energy storage devices made up of carbon nano
particles. 6.1. High performance tellurium-reduced graphene oxide
pseudo-capacitor. 6.2. Fabrication of flexible and durable supercell made
up of carbon-nano-sphere. 6.3. Self-assembled two-dimensional
heterostructure of rGO/MoS2/h-BN (GMH). References. 7. Magnetism in
otherwise non-magnetic nano-carbon and its derivatives. 7.1. Spin transport
and magnetic correlation in GNCs doped with nitrogen. 7.2. Spin dynamics in
GNCs vs graphene: role of adatom. 7.3. Molecular-spintronics in 2D carbon
with adatom. 7.4. Tetrakis(dimethylamino) ethylene induced magnetism .
References. 8. Multi-functional nano-carbons: from meta-materials to
non-liner optics and gas sensing to mechanically tough fibre mat
application. 8.1. Multi-functional aspect: optical gas sensing and EMI
shielding. 8.2. Split ring resonators: Ferro-nano-carbon metamaterials.
8.3. Mechanical properties of GNCs nano-composites. 8.4 . Mechanical
properties of electrospun PVA/CNT composite nanofibers. References. 9.
Application engineering of nano-carbon-reinforced composites. 9.1 Field
electron emission aspects of CNTs: the paste approach. 9.2. TiO2 coated
CNTs: dye sensitized solar cells. 9.3. CNT embedded nylon nanofiber bundles
by electrospinning. References. 10. Poly-nano-carbons: ion-track membranes
for devices and nuclear radiation induced modifications for
opto-electronics . 10.1. Emergence of nano-ion track membrane for flat
flexible devices. 10.2. Opto-electronic properties of radiation induced
modified poly-carbon. References. 11. Summary and outlook
nano-carbons . References. 2. Preparation and evaluation of nano-carbons.
2.1. 0-D carbon systems: carbon nanoparticles (CNP) /spheres (CNS). 2.2.
Carbon nanotubes: 1-D format of carbon. 2.3. 2D graphene. 2.4. Foundry
processed 3D graphite: variable density effect. 2.5. 4D orthogonal carbon
fabric. References. 3. Hydrodynamics and shock absorption properties of
nano-carbon . 3.1. Explosion: Background. 3.2. Laboratory synthesis: the
survey. 3.3. Experimental simulation of blast: the instrumentation. 3.4.
GNF for shock absorbing application. 3.5. Surface interactions of transonic
shock wave with GLNR. 3.6. Hydrodynamics response of nanocarbons: CNS vs
GNF. 3.7. Blast mitigation parameters for PNCs. References. 4. Microwave
scattering and radar absorption coating properties of nanocarbon. 4.1.
Radar know-hows: the background. 4.2. Microwave scattering mechanism: the
Maxwellian formulation. 4.3. Shielding performance of materials architected
. 4.4. Graphene and graphene derivatives for shielding. References. 5. Heat
transfer and thermodynamics in micro graphitic nozzles. 5.1.
Thermo-physical assessments of variable density graphite. 5.2. High
temperature thermodynamics in rocket motor nozzles. References. 6.
Electrochemistry and energy storage devices made up of carbon nano
particles. 6.1. High performance tellurium-reduced graphene oxide
pseudo-capacitor. 6.2. Fabrication of flexible and durable supercell made
up of carbon-nano-sphere. 6.3. Self-assembled two-dimensional
heterostructure of rGO/MoS2/h-BN (GMH). References. 7. Magnetism in
otherwise non-magnetic nano-carbon and its derivatives. 7.1. Spin transport
and magnetic correlation in GNCs doped with nitrogen. 7.2. Spin dynamics in
GNCs vs graphene: role of adatom. 7.3. Molecular-spintronics in 2D carbon
with adatom. 7.4. Tetrakis(dimethylamino) ethylene induced magnetism .
References. 8. Multi-functional nano-carbons: from meta-materials to
non-liner optics and gas sensing to mechanically tough fibre mat
application. 8.1. Multi-functional aspect: optical gas sensing and EMI
shielding. 8.2. Split ring resonators: Ferro-nano-carbon metamaterials.
8.3. Mechanical properties of GNCs nano-composites. 8.4 . Mechanical
properties of electrospun PVA/CNT composite nanofibers. References. 9.
Application engineering of nano-carbon-reinforced composites. 9.1 Field
electron emission aspects of CNTs: the paste approach. 9.2. TiO2 coated
CNTs: dye sensitized solar cells. 9.3. CNT embedded nylon nanofiber bundles
by electrospinning. References. 10. Poly-nano-carbons: ion-track membranes
for devices and nuclear radiation induced modifications for
opto-electronics . 10.1. Emergence of nano-ion track membrane for flat
flexible devices. 10.2. Opto-electronic properties of radiation induced
modified poly-carbon. References. 11. Summary and outlook