Peter Nordlander, Ned S. Wingreen, Yigal Meir, David C. Langreth
Published 1998-01-23Version 1
Using a time-dependent Anderson Hamiltonian, a quantum dot with an ac voltage applied to a nearby gate is investigated. A rich dependence of the linear response conductance on the external frequency and driving amplitude is demonstrated. At low frequencies the ac potential produces sidebands of the Kondo peak in the spectral density of the dot, resulting in a logarithmic decrease in conductance over several decades of frequency. At intermediate frequencies, the conductance of the dot displays an oscillatory behavior due to the appearance of Kondo resonances of the satellites of the dot level. At high frequencies, the conductance of the dot can vary rapidly due to the interplay between photon-assisted tunneling and the Kondo resonance.
Comments: 4 pages, 4 figures
Time-Dependent Transport Through Quantum-Impurity Systems with Kondo Resonance
Measurement of the shot noise in a single electron transistor
Fano and Kondo resonance in electronic current through nanodevices
