Title :
FeMn Exchange Biased Storage Layer for Thermally Assisted MRAM
Author :
Gapihan, Erwan ; Sousa, Ricardo C. ; Hérault, Jeremy ; Papusoi, Christian ; Delaye, Marie Therese ; Dieny, Bernard ; Prejbeanu, I. Lucien ; Ducruet, Clarisse ; Portemont, Céline ; Mackay, Ken ; Nozières, Jean-Pierre
Author_Institution :
CNRS, UJF, Grenoble, France
fDate :
6/1/2010 12:00:00 AM
Abstract :
Thermally assisted MRAM cells with FeMn exchange biased storage layers were successfully written using 50 ns current pulses with write power densities below 10 mW/¿m2 and current densities below 1.3 ×10 6 A/cm2. These low power density values were achieved without using thermal barriers to confine the heat in the cell. Introducing thermal barriers would even further lower the write power density by increasing the heating efficiency. The storage layer coercivity increased upon anneal at 340 C. This could be related to manganese diffusion or to a texture incompatibility between the CoFe and the FeMn antiferromagnetic layer, a problem which can be fixed by insertion of appropriate diffusion barrier or texture control layer. Successful writing was observed for repeated write attempts with heating pulse power densities in the 7-12.5 mW/¿m2 range.
Keywords :
MRAM devices; annealing; antiferromagnetic materials; cobalt alloys; coercive force; current density; diffusion barriers; exchange interactions (electron); iron alloys; manganese alloys; FeMn-CoFe; antiferromagnetic layer; coercivity; current densities; diffusion barrier; exchange biased storage layers; temperature 340 degC; texture control layer; texture incompatibility; thermal barriers; thermally assisted MRAM cells; time 50 ns; write power densities; Annealing; Antiferromagnetic materials; Electrodes; Heating; Magnetic fields; Magnetic hysteresis; Plasma temperature; Space vector pulse width modulation; Thermal stability; Writing; Magnetic hysteresis; magnetic semiconductors;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2010.2041198
