Derives multiphoton cross sections for stimulated bremsstrahlung in doped bilayer graphene with coherent radiation, showing nonlinear response and differences from monolayer graphene due to parabolic dispersion.
Direct observa- tion of a widely tunable band gap in bilayer graphene
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Graphene's high conductivity, fast carrier dynamics, and tunability enable engineering of THz-frequency photodetectors, modulators, and sources.
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Multiphoton cross sections of conductive electrons stimulated bremsstrahlung in doped bilayer graphene
Derives multiphoton cross sections for stimulated bremsstrahlung in doped bilayer graphene with coherent radiation, showing nonlinear response and differences from monolayer graphene due to parabolic dispersion.
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Engineering THz-frequency light generation, detection and manipulation through graphene
Graphene's high conductivity, fast carrier dynamics, and tunability enable engineering of THz-frequency photodetectors, modulators, and sources.