First-principles study on magnetic tunneling junctions with semiconducting CuInSe2 and CuGaSe2 barriers

Abstract

We theoretically investigate two different magnetic tunneling junctions (MTJs) with semiconductor barriers, CuInSe2 (CIS) and CuGaSe2 (CGS), which are the terminal compounds of recently reported mixed semiconductor barrier, CuIn1-xGa xSe2. To discuss the transport properties of these systems, we analyze complex band structures, magnetoresistance (MR) ratios, and resistance-area products (RA) by using first-principles based calculations in combination with the Landauer formula. It is found that the 1 wave functions have dominant contributions to the spin-dependent tunneling transport in both CIS- and CGS-based MTJs. We also find that the CGS-based MTJ has a much larger MR ratio and slightly higher RA than those of the CIS-based MTJ, which indicates that a larger MR ratio is expected for a higher Ga concentration x in the CuIn1-xGaxSe2-based MTJs. We further study the relationship between the band gaps in the barriers and MR ratios by changing the Coulomb repulsions in the Cu 3d states of the CIS and CGS. It is shown that the barrier with a larger band gap yields a larger MR ratio. The comparison of MR ratios and RA between the CIS-, CGS-, and MgO-based MTJs are also given.