Renormalization Mass of Polaron in Cylindrical Quantum Dot

ZHAO Cui-lan; DING Zhao-hua; XIAO Jing-lin

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Renormalization Mass of Polaron in Cylindrical Quantum Dot

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- Renormalization Mass of Polaron in Cylindrical Quantum Dot
- Chinese Journal of Luminescence Vol. 26, Issue 2, Pages: 159-162(2005)
- 作者机构：
  
  内蒙古民族大学物理与机电学院,内蒙古通辽,028043
- 作者简介：
- 基金信息：
- DOI：
  CLC： O482.3
- Received：20 August 2004，
  
  Revised：25 September 2004，
  
  Published：20 March 2005
- 稿件说明：
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赵翠兰, 丁朝华, 肖景林. 柱型量子点中极化子的重整化质量[J]. 发光学报, 2005,26(2): 159-162

ZHAO Cui-lan, DING Zhao-hua, XIAO Jing-lin. Renormalization Mass of Polaron in Cylindrical Quantum Dot[J]. Chinese Journal of Luminescence, 2005,26(2): 159-162
赵翠兰, 丁朝华, 肖景林. 柱型量子点中极化子的重整化质量[J]. 发光学报, 2005,26(2): 159-162 DOI：

ZHAO Cui-lan, DING Zhao-hua, XIAO Jing-lin. Renormalization Mass of Polaron in Cylindrical Quantum Dot[J]. Chinese Journal of Luminescence, 2005,26(2): 159-162 DOI：

摘要

应用线性组合算符方法和幺正变换方法

研究在量子阱和抛物势作用下的柱型量子点中极化子的重整化质量.结果表明

量子点中极化子的重整化质量随量子点高度的增加而减小;随耦合强度的增加而增加

这是由于电子与晶格振动之间的相互作用增强所致.而基态能量与量子点的尺度、特征频率、耦合强度、磁场等均有关

当极化子运动速度不变时

基态能量随量子点柱高的增加而减小;随特征频率和磁场强度的增加而增加.

Abstract

Because nanometer materials is smaller

they possess rich scientific meaning and quantum effect. Base on quantum effect of these materials

develop a series new materials on photoelectron

photon and related quantum parts

bring about new trend on study and development of materials science. Quantum dot is very special because it's confined in three-dimension

quantum effect is more obvious

and become a new study realm. The structures of quantum dots were studied by perturbation method

varational method

and a few bodies method

base on effective mass approximation. E. Peter

et al

. report on the observation of asymmetric phonon sidebands on both the exciton and biexciton emission lines in single GaAs monolayer fluctuation quantum dot

and indicate that the contribution of phonon sidebands to the emission line is larger for the biexciton than for the exciton. R. P. Wang

et al

. studied Raman spectra of InO power and free-standing nanowires prepared by ablation. They found that the coupling strength determined by the ratio of second-to first-order Raman scattering cross sections diminishes with decreasing nanowire diameter

and the Frohlich interaction plays the main role in electron-phonon coupling in InO. J. L. Chen

et al

. studied the spin-relaxation time due to the electron-acoustic phonon scattering in GaAs quantum dots by exact diagonalized the electron Hamiltonian with the spin-orbit coupling

and discussed different effects such as the magnetic field

the quantum dot size

and the temperature on the spin-relaxation time.In this paper

the properties of polaron with electron-LO-phonon weak-coupling in cylindrical quantum dot

which was in quantum well and parabolic potential

were investi-gated by using the linear combination operator and unitary transformation methods. The results indicated that the renormalization mass of polaron in quantum dot decrease with increasing cylinder height

and increase with increasing coupling strength because of interaction between electron and crystal vibration. Ground state energy has something to do with size of quantum dot

characteristic frequency

coupling strength

and magnetic-field strength

etc

it increased with decreasing cylinder height and increasing characteristic frequency

magnetic-field strength.

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Related Institution

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School of Chemistry and Chemical Engineering， Anshun University

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