TY - JOUR

T1 - Electronic quantum trajectories in a quantum dot

AU - Yang, Ciann Dong

AU - Huang, Shih Ming

PY - 2014/7/15

Y1 - 2014/7/15

N2 - This article gives a quantum-trajectory demonstration of the observed electric, magnetic, and thermal effects on a quantum dot with circular or elliptic shape. By applying quantum trajectory method to a quantum dot, we reveal the quantum-mechanical meanings of the classical concepts of backscattering and commensurability, which were used in the literature to explain the peak locations of the magnetoresistance curve. Under the quantum commensurability condition, electronic quantum trajectories in a circular quantum dot are shown to be stationary like a standing wave, whose presence increases the electrical resistance. A hidden quantum effect called magnetic stagnation is discovered and shown to be the main cause of the observed jumps of the magnetoresistance curve. Quantum trajectories in an elliptic quantum dot are found to be chaotic and an index of chaos called Lyapunov exponent is proposed to measure the irregularity of the various quantum trajectories. It is shown that the response of the Lyapunov exponent to the applied magnetic field captures the main features of the experimental magnetoresistance curve. © 2014 Wiley Periodicals, Inc. Under quantum commensurability conditions, electronic quantum trajectories in a quantum dot are found to be stationary like a standing wave, whose presence increases the electrical resistance. The number of waves distributed on the circumference of the quantum dot can be controlled by the applied magnetic field. The quantum trajectory method elucidates how the electrical resistance of a quantum dot changes with respect to the applied magnetic field and temperature.

AB - This article gives a quantum-trajectory demonstration of the observed electric, magnetic, and thermal effects on a quantum dot with circular or elliptic shape. By applying quantum trajectory method to a quantum dot, we reveal the quantum-mechanical meanings of the classical concepts of backscattering and commensurability, which were used in the literature to explain the peak locations of the magnetoresistance curve. Under the quantum commensurability condition, electronic quantum trajectories in a circular quantum dot are shown to be stationary like a standing wave, whose presence increases the electrical resistance. A hidden quantum effect called magnetic stagnation is discovered and shown to be the main cause of the observed jumps of the magnetoresistance curve. Quantum trajectories in an elliptic quantum dot are found to be chaotic and an index of chaos called Lyapunov exponent is proposed to measure the irregularity of the various quantum trajectories. It is shown that the response of the Lyapunov exponent to the applied magnetic field captures the main features of the experimental magnetoresistance curve. © 2014 Wiley Periodicals, Inc. Under quantum commensurability conditions, electronic quantum trajectories in a quantum dot are found to be stationary like a standing wave, whose presence increases the electrical resistance. The number of waves distributed on the circumference of the quantum dot can be controlled by the applied magnetic field. The quantum trajectory method elucidates how the electrical resistance of a quantum dot changes with respect to the applied magnetic field and temperature.

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U2 - 10.1002/qua.24692

DO - 10.1002/qua.24692

M3 - Article

AN - SCOPUS:84901986685

VL - 114

SP - 920

EP - 930

JO - International Journal of Quantum Chemistry

JF - International Journal of Quantum Chemistry

SN - 0020-7608

IS - 14

ER -