Graphene and Carbon Nanotubes UltrafastRelaxation Dynamics and Optics
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More About This Title Graphene and Carbon Nanotubes UltrafastRelaxation Dynamics and Optics
English
A first on ultrafast phenomena in carbon nanostructures like graphene, the most promising candidate for revolutionizing information technology and communication
The book introduces the reader into the ultrafast nanoworld of graphene and carbon nanotubes, including their microscopic tracks and unique optical finger prints. The author reviews the recent progress in this field by combining theoretical and experimental achievements. He offers a clear theoretical foundation by presenting transparently derived equations. Recent experimental breakthroughs are reviewed.
By combining both theory and experiment as well as main results and detailed theoretical derivations, the book turns into an inevitable source for a wider audience from graduate students to researchers in physics, materials science, and electrical engineering who work on optoelectronic devices, renewable energies, or in the semiconductor industry.
The book introduces the reader into the ultrafast nanoworld of graphene and carbon nanotubes, including their microscopic tracks and unique optical finger prints. The author reviews the recent progress in this field by combining theoretical and experimental achievements. He offers a clear theoretical foundation by presenting transparently derived equations. Recent experimental breakthroughs are reviewed.
By combining both theory and experiment as well as main results and detailed theoretical derivations, the book turns into an inevitable source for a wider audience from graduate students to researchers in physics, materials science, and electrical engineering who work on optoelectronic devices, renewable energies, or in the semiconductor industry.
English
Ermin Malic graduated in Physics from Technical University (TU) Berlin. During his PhD thesis, he was a visiting researcher at the MIT and the University of Modena, Italy. From 2003 to 2008, he was a fellow of the Studienstiftung des Deutschen Volkes and the Friedrich-Ebert Stiftung. He received the DAAD and the Chorofas award for outstanding scientific research. After a post-doctoral stay at CIN2 in Barcelona, he is now leading the Einstein Junior Research Group on Microscopic Study of Carbon-based Hybrid Nanostructures at TU Berlin.
Professor Andreas Knorr works in the field of nonlinear optics and quantum electronics of nanostructured solids.
His research is focused on the interaction of light and matter, self-consistent solutions of Maxwell- and material equations and many body effects in open quantum systems. Since 2000 Andreas Knorr has a professorship at the Technical University of Berlin. His scientific career, which started at the Friedrich-Schiller-University Jena led him to the Universities of New Mexico, Arizona (College of Optical Sciences), Marburg, Göttingen and to Sandia National Labs Albuquerque and NTT Tokio.
Professor Andreas Knorr works in the field of nonlinear optics and quantum electronics of nanostructured solids.
His research is focused on the interaction of light and matter, self-consistent solutions of Maxwell- and material equations and many body effects in open quantum systems. Since 2000 Andreas Knorr has a professorship at the Technical University of Berlin. His scientific career, which started at the Friedrich-Schiller-University Jena led him to the Universities of New Mexico, Arizona (College of Optical Sciences), Marburg, Göttingen and to Sandia National Labs Albuquerque and NTT Tokio.
English
1. Introduction -
The Carbon Age
2. Theoretical Framework
3. Experimental techniques for the Study of Ultrafast Nonequilibrium Carrier Dynamics in Graphene
Part One: Electronic Properties -
Carrier Relaxation Dynamics
4. Relaxation dynamics in graphene
5. Carrier Dynamics in Carbon Nanotubes
Part Two: Optical Properties -
Absorption Spectra
6. Absorption Spectra of Carbon Nanotubes
7. Absorption Spectrum of Graphene
A Introduction to the Appendices
B Observables in Optical Experiments
C Second Quantization
D Equations of Motion
E Mean-Field and Correlation Effects
The Carbon Age
2. Theoretical Framework
3. Experimental techniques for the Study of Ultrafast Nonequilibrium Carrier Dynamics in Graphene
Part One: Electronic Properties -
Carrier Relaxation Dynamics
4. Relaxation dynamics in graphene
5. Carrier Dynamics in Carbon Nanotubes
Part Two: Optical Properties -
Absorption Spectra
6. Absorption Spectra of Carbon Nanotubes
7. Absorption Spectrum of Graphene
A Introduction to the Appendices
B Observables in Optical Experiments
C Second Quantization
D Equations of Motion
E Mean-Field and Correlation Effects
