Title :
Material Stack Design With High Tolerance to Process-Induced Damage in Domain Wall Motion Device
Author :
Honjo, Hiroaki ; Fukami, Shunsuke ; Ishihara, Koichi ; Kinoshita, Keizo ; Tsuji, Yukihide ; Morioka, Ayuka ; Nebashi, Ryusuke ; Tokutome, Keiichi ; Sakimura, Noboru ; Murahata, Michio ; Miura, Shun ; Sugibayashi, Tadahiko ; Kasai, Naoki ; Ohno, Hideo
Author_Institution :
Green Platform Res. Labs., NEC Corp., Tsukuba, Japan
Abstract :
We have developed a three-terminal domain wall motion (DWM) device. We found that its performance was significantly degraded by ion irradiation to the DWM materials under conventional etching conditions with Ar/NH3/CO gas mixture plasma for the device fabrication. To avoid this process-induced damage (PID), we fabricated and optimized a new material stack, in which a thin Ta layer is inserted on top of the capping layer of the DWM layer We found that the new stack effectively prevented a decrease in DWM layer coercivity, an increase in the critical current, and a decrease in the switching probability owing to the high-etch selectivity of Ta. As a result, the switching property of the DWM cell was greatly improved by the newly developed DWM stacks with high tolerance to PID.
Keywords :
etching; ion beam effects; magnetic domain walls; magnetoelectronics; tantalum; Ar-NH3-CO; Ta; coercivity; critical current; etching; high tolerance; ion irradiation; material stack design; process-induced damage; switching probability; three-terminal domain wall motion device; Etching; Fabrication; Integrated circuits; Magnetic tunneling; Materials; Plasmas; Switches; Domain wall motion (DWM); embedded memory; magnetic tunnel junction (MTJ); nonvolatile memory; process-induced damage (PID); three-terminal cell;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2014.2325019
