TY  - GEN
N2  - Graphene Nanomaterials is expected to fill a void in knowledge among practitioners generated by the discovery of graphene as a distinct allotrope of carbon (2010 Nobel Prize in Physics) with the potential to affect further increases in speed of microprocessors beyond 30 petahertz. It has other interesting performance properties. Identified in 2004, currently the number of patents in graphene is 7,351 and the number is rising rapidly. This book provides information on the synthesis, characterization, application development, scale-up, stability analysis using a pencil and paper, and structure-property relations. With less than 24,000 atoms/25 nm, the nanosheet form is metastable. Thirty-nine different nanostructuring methods were reviewed in an earlier book including epitaxy, lithography, deposition, exfoliation, etc. With the thickness of only a few atomic layers, graphene has superior field emitter properties, is 100 times stronger than steel, flexible as rubber, tougher than diamond, and is 13 times more conductive than copper. Electron mobility in graphene has been found to be 200,000 cm2V-1s-1.
DO  - doi
AB  - Graphene Nanomaterials is expected to fill a void in knowledge among practitioners generated by the discovery of graphene as a distinct allotrope of carbon (2010 Nobel Prize in Physics) with the potential to affect further increases in speed of microprocessors beyond 30 petahertz. It has other interesting performance properties. Identified in 2004, currently the number of patents in graphene is 7,351 and the number is rising rapidly. This book provides information on the synthesis, characterization, application development, scale-up, stability analysis using a pencil and paper, and structure-property relations. With less than 24,000 atoms/25 nm, the nanosheet form is metastable. Thirty-nine different nanostructuring methods were reviewed in an earlier book including epitaxy, lithography, deposition, exfoliation, etc. With the thickness of only a few atomic layers, graphene has superior field emitter properties, is 100 times stronger than steel, flexible as rubber, tougher than diamond, and is 13 times more conductive than copper. Electron mobility in graphene has been found to be 200,000 cm2V-1s-1.
T1  - Graphene nanomaterials /
AU  - Sharma, Kal Renganathan.,
CN  - QD181.C1
ID  - 841740
KW  - Graphene.
KW  - Nanostructured materials.
KW  - single-layer graphenes
KW  - barristor
KW  - ultracapacitor
KW  - carbon allotrope
KW  - thinnest material
KW  - deposition
KW  - milling
KW  - scotch tape
KW  - honey comb structure
KW  - 2D lattice
KW  - unscrolled CNT
KW  - industrial electronics
KW  - nanomaterials
KW  - transparent electrodes and other applications
KW  - cost of production
KW  - roll-to-roll transfer and other fabrication processes
KW  - APFR
KW  - diffusion times
KW  - Raman spectroscopy
KW  - TEM, HeIM and other characterization methods
KW  - hexagonal anion rings
KW  - magnetic, surface, electrical, and mechanical properties
KW  - quantum hall effect
KW  - electrorheological properties
KW  - catalysts
KW  - thermodynamic stability-free energy of reaction
KW  - scroll stability
KW  - surface reactivity
KW  - interfacial stability
KW  - edge stability
KW  - metastability
KW  - defects
SN  - 9781606504772
TI  - Graphene nanomaterials /
LK  - https://univsouthin.idm.oclc.org/login?url=https://ebookcentral.proquest.com/lib/usiricelib-ebooks/detail.action?docID=3017292
UR  - https://univsouthin.idm.oclc.org/login?url=https://ebookcentral.proquest.com/lib/usiricelib-ebooks/detail.action?docID=3017292
ER  -