L10 FePd-based perpendicular magnetic tunnel junctions with 65% tunnel magnetoresistance and ultralow switching current density

L1(0) FePd is increasingly recognized as a potential candidate for magnetic tunnel junctions (MTJs), yet there remains room for enhancing device performance. In this work, we fabricated fully-integrated L1(0) FePd-based perpendicular MTJ devices and achieved a significant increase in tunnel magnetoresistance, reaching similar to 65%, compared to the previous record of 25%. Notably, we observed bi-directional switching with a low switching current density of about 1.4 x 10(5) A/cm(2), which outperforms the typical spin-transfer torque (STT) MTJ by about one order of magnitude. We propose two possible mechanisms to elucidate the switching process and associated device performance: (1) The voltage-controlled exchange coupling-driven switching of the bottom CoFeB layer; (2) The STT-driven switching of the exchange-coupled L1(0) FePd-CoFeB composite. While additional research is necessary, these findings may further advance the integration of L1(0) FePd into spintronic devices, potentially enabling low-energy memory and logic technologies.