Abstract

Electron tunneling in ZnO/ZnCdO double-barrier trilayer semiconductor heterostructure is theoretically examined using the transfer matrix method. The effect of well width influences the energy of resonance transmission and the full width at half maximum of the resonance peak. The Dresselhaus spin-orbit interaction causes the separation between the spin components, and the increasing in-plane wave vector enhances the spin separation. The dwell time of electrons in the heterostructure is high at a high well width. The full width at half maximum of the barrier transparency peak is examined, and hence, the tunneling lifetime for various in-plane wave vectors is reported. The difference between the tunneling lifetime of spin-up and spin-down electrons is high at higher values of the in-plane wave vector.