Tuning of nonlinear optical characteristics of Mathieu quantum dot by laser and electric field
Abstract
In this work, for the first time, the total refractive index (TRICs) and total absorption coefficients (TACs) of
InxGa1−xAs/GaAs Mathieu quantum dot (MQD) with hydrogenic impurity under the influence of the external electric field and
laser field are probed. Within the framework of the Ehlotzky approximation, considering the Kramers–Henneberger transformation
and dipole approximation, the time-dependent in the wave equation is transferred from the kinetic energy operator to the potential
energy function. Then, the new Schrödinger equation for the MQD including the hydrogenic impurity under the external electric field
and monochromatic linearly polarized laser radiation is solved numerically by employing the tridiagonal matrix method. In order
to study the TRICs and TACs of MQD, the iterative method and compact-density-matrix formalism are employed. The influence
of structural parameters as well as the external factors on the TRICs and TACs of the MQD is examined. The effects of external
electric field, laser field, In-concentration, impurity atom position, the MQD depth and width parameters on the TRICs and TACs are
investigated in detail, and functional ranges of relevant parameters are also determined for the purpose. In addition, the alternatives
of these parameters to each other are also discussed. It is important for experimental research that all parameter values used are
accessible