Effect of hydrostatic pressure and temperature on the ballistic conductance under the influence of Rashba spin-orbit coupling

Abstract

In semiconductors, the exploration of electron quantum transport on the nanoscale has become feasible due to the electric field as well as magnetic field impact. The existence of spin-orbit coupling in the quantum wire has set up a propitious stage for the development of apparatus for electron transportation. Here, we analyse the impact of hydrostatic pressure and temperature on the energy band structure as well as on the ballistic conductivity. The Energy eigenvalues and eigenvectors are found by using the diagonalization method and the ballistic conductance is computed by Landuer-B u¨ ttiker formalism. Also, we have studied the behaviour of energy concerning an external electric field, magnetic field and temperature. The system is expressed by parabolic confinement to the normal intense magnetic field and RSOI causes the collaborative impact of interior and exterior agents leading to downward/upward and lateral/vertical shifts in the dispersion. The oddity of the energy subbands results in oscillatory patterns in the ballistic conductance.