Co/AlP/Co, Co/GaN/Co as magnetic tunnel junctions

Abstract

AlP and GaN are wide band-gap semiconductors (SC) uses in opto-electronic industry as light emitting diodes. Here we investigate it as future perspective candidate for insulating barrier in magnetic tunnel junctions. We employ density functional theory for ground state electronic properties and non-equilibrium Green's function method for quantum transport and examined Co/AlP/Co and Co/GaN/Co MTJs. We find that both AlP and GaN valance band maxima are predominantly made with pz-type orbitals while conduction band minima are s-type symmetry. We find that both AlP and GaN filter 1 symmetry of Bloch states at -point and transmission coefficient at any energy level in-between the band-gap of materials, is mostly driven by 1 symmetry of Bloch states tunnel via -point in first Brillouin zones. We find large magneto-resistance 300\% in Co/AlP/Co MTJs at zero-bias. In Co/GaN/Co MTJs we find 300\% TMR at 1.25 eV below the Fermi energy (EF-1.25)~eV, while 10\% TMR around EF in zero-bias calculations. We notice that both majority and minority 2' symmetry of Bloch states with rather different spd-orbitals compositions tunnel in Co[0001]/AlP[0001] MTJs and exhibit non-zero TMR, whereas in Co[111]/GaN[0001] MTJs, the both majority and minority 1 symmetry of Bloch states with different energy-gradient tunnels at Fermi energy level along [111] transport direction. Our work accentuate the process for systematic, efficient, accurate and versatile framework to design the semiconductors based MTJs for low power electronics.