Non-Equilibrium Electrons in a Ballistic Quantum Dot

In 1957, Landauer revolutionized the approach to the treatment of transport in condensed matter systems through the concept that the conductance could be directly related to the transmission coefficient through the system. Recently, this idea has become all pervasive in the study of mesoscopic syste

Recent experiments have examined the magnetoconductance properties of mesoscopic quantum dots, defined in high mobility GaAs/AlGaAs heterojunctions utilizing split-gate techniques. Here, we report on a submicron, square quantum dot defined in a pseudomorphic InGaAs/GaAs single quantum well through a

We have observed conductance fluctuations due to electron interference in a split-gate quantum dot, fabricated in the two-dimensional electron gas of a GaAs/Al x Ga 1-x As heterojunction. We have determined the phase breaking time of electrons by two independent analyses, using the correlation field

Nonlinear electron transport through a semiconductor quantum dot in the low-temperature Kondo regime is studied theoretically. Particular emphasis is put on examining the effects of the inherent multilevel electronic structure of the semiconductor dot. Combining the nonequilibrium Green function met