Anjana Bagga, P. K. Chattopadhyay, Subhasis Ghosh
Published 2005-03-25Version 1
The mechanism of Stokes shift in semiconductor quantum dots is investigated by calculating the energy of the excitonic states. We have taken into account all possible contributions to the total electronic energy in the dot, i.e, dielectric mismatch between dot and surrounding medium, the effects of finite barrier height and electron-hole exchange interaction. The Stokes shift is calculated as a function of radius of dot and compared with experimental data on two different semiconductor based quantum dots. These results provide evidence for exchange splitting of excitonic states, as the mechanism of Stokes shift in quantum dot
Spin-flip transitions between Zeeman sublevels in semiconductor quantum dots
Optically induced spin gates in coupled quantum dots using the electron-hole exchange interaction
Quantum Mechanics of Semiconductor Quantum Dots and Rings
