Theoretical Study of the Optical Manipulation of Semiconductor Nanoparticles under an Excitonic Resonance Condition
- 5 February 2003
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 90 (5), 057403
- https://doi.org/10.1103/PhysRevLett.90.057403
Abstract
We theoretically study the mechanical interaction between radiation and a semiconductor nanoparticle, based on a microscopic model of confined excitons. The exerted force is calculated by using the Maxwell stress tensor expressed in terms of the microscopic response field. The numerical demonstrations clarify the following: (1) The enhancement of the force by using electronic resonance is remarkable for a particle with a radius of less than 100 nm for semiconductor materials. (2) The spectral peak position of the exerted force is considerably sensitive to nanoscale-size changes which would be useful for highly accurate size-selective manipulation.Keywords
This publication has 13 references indexed in Scilit:
- Large Four-Wave Mixing of Spatially Extended Excitonic States in Thin GaAs LayersPhysical Review Letters, 2002
- Electromagnetic force on a metallic particle in the presence of a dielectric surfacePhysical Review B, 2000
- Coupled dipole method determination of the electromagnetic force on a particle over a flat dielectric substratePhysical Review B, 2000
- Ultranarrow homogeneous broadening of confined excitons in quantum dots: Effect of the surrounding matrixPhysical Review B, 2000
- Radiation Force Exerted on Subwavelength Particles near a NanoaperturePhysical Review Letters, 1999
- Theory of Nanometric Optical TweezersPhysical Review Letters, 1997
- Forces of a single-beam gradient laser trap on a dielectric sphere in the ray optics regimeBiophysical Journal, 1992
- Optical absorption by excitons in microcrystalsJournal of Physics and Chemistry of Solids, 1989
- Observation of a single-beam gradient force optical trap for dielectric particlesOptics Letters, 1986
- Anomalous wave interference at Z3-exciton resonance of CuClSolid State Communications, 1982