Trend of tunnel magnetoresistance and variation in threshold voltage for keeping data load robustness of metal-oxide-semiconductor/magnetic tunnel junction hybrid latches

T. Ohsawa; S. Ikeda; T. Hanyu; H. Ohno; T. Endoh

doi:10.1063/1.4867129

Trend of tunnel magnetoresistance and variation in threshold voltage for keeping data load robustness of metal-oxide-semiconductor/magnetic tunnel junction hybrid latches

T. Ohsawa, S. Ikeda, T. Hanyu, H. Ohno, T. Endoh

Research output: Contribution to journal › Article › peer-review

12 Citations (Scopus)

Abstract

The robustness of data load of metal-oxide-semiconductor/magnetic tunnel junction (MOS/MTJ) hybrid latches at power-on is examined by using Monte Carlo simulation with the variations in magnetoresistances for MTJs and in threshold voltages for MOSFETs involved in 90 nm technology node. Three differential pair type spin-transfer-torque-magnetic random access memory cells (4T2MTJ, 6T2MTJ, and 8T2MTJ) are compared for their successful data load at power-on. It is found that the 4T2MTJ cell has the largest pass area in the shmoo plot in TMR ratio (tunnel magnetoresistance ratio) and V_dd in which a whole 256 kb cell array can be powered-on successfully. The minimum TMR ratio for the 4T2MTJ in 0.9 V < V_dd < 1.9 V is 140%, while the 6T2MTJ and the 8T2MTJ cells require TMR ratio larger than 170%.

Original language	English
Article number	17C728
Journal	Journal of Applied Physics
Volume	115
Issue number	17
DOIs	https://doi.org/10.1063/1.4867129
Publication status	Published - 2014 May 7
Externally published	Yes

ASJC Scopus subject areas

Physics and Astronomy(all)

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title = "Trend of tunnel magnetoresistance and variation in threshold voltage for keeping data load robustness of metal-oxide-semiconductor/magnetic tunnel junction hybrid latches",

abstract = "The robustness of data load of metal-oxide-semiconductor/magnetic tunnel junction (MOS/MTJ) hybrid latches at power-on is examined by using Monte Carlo simulation with the variations in magnetoresistances for MTJs and in threshold voltages for MOSFETs involved in 90 nm technology node. Three differential pair type spin-transfer-torque-magnetic random access memory cells (4T2MTJ, 6T2MTJ, and 8T2MTJ) are compared for their successful data load at power-on. It is found that the 4T2MTJ cell has the largest pass area in the shmoo plot in TMR ratio (tunnel magnetoresistance ratio) and Vdd in which a whole 256 kb cell array can be powered-on successfully. The minimum TMR ratio for the 4T2MTJ in 0.9 V < Vdd < 1.9 V is 140%, while the 6T2MTJ and the 8T2MTJ cells require TMR ratio larger than 170%.",

author = "T. Ohsawa and S. Ikeda and T. Hanyu and H. Ohno and T. Endoh",

year = "2014",

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doi = "10.1063/1.4867129",

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T1 - Trend of tunnel magnetoresistance and variation in threshold voltage for keeping data load robustness of metal-oxide-semiconductor/magnetic tunnel junction hybrid latches

AU - Ohsawa, T.

AU - Ikeda, S.

AU - Hanyu, T.

AU - Ohno, H.

AU - Endoh, T.

PY - 2014/5/7

Y1 - 2014/5/7

N2 - The robustness of data load of metal-oxide-semiconductor/magnetic tunnel junction (MOS/MTJ) hybrid latches at power-on is examined by using Monte Carlo simulation with the variations in magnetoresistances for MTJs and in threshold voltages for MOSFETs involved in 90 nm technology node. Three differential pair type spin-transfer-torque-magnetic random access memory cells (4T2MTJ, 6T2MTJ, and 8T2MTJ) are compared for their successful data load at power-on. It is found that the 4T2MTJ cell has the largest pass area in the shmoo plot in TMR ratio (tunnel magnetoresistance ratio) and Vdd in which a whole 256 kb cell array can be powered-on successfully. The minimum TMR ratio for the 4T2MTJ in 0.9 V < Vdd < 1.9 V is 140%, while the 6T2MTJ and the 8T2MTJ cells require TMR ratio larger than 170%.

AB - The robustness of data load of metal-oxide-semiconductor/magnetic tunnel junction (MOS/MTJ) hybrid latches at power-on is examined by using Monte Carlo simulation with the variations in magnetoresistances for MTJs and in threshold voltages for MOSFETs involved in 90 nm technology node. Three differential pair type spin-transfer-torque-magnetic random access memory cells (4T2MTJ, 6T2MTJ, and 8T2MTJ) are compared for their successful data load at power-on. It is found that the 4T2MTJ cell has the largest pass area in the shmoo plot in TMR ratio (tunnel magnetoresistance ratio) and Vdd in which a whole 256 kb cell array can be powered-on successfully. The minimum TMR ratio for the 4T2MTJ in 0.9 V < Vdd < 1.9 V is 140%, while the 6T2MTJ and the 8T2MTJ cells require TMR ratio larger than 170%.

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Trend of tunnel magnetoresistance and variation in threshold voltage for keeping data load robustness of metal-oxide-semiconductor/magnetic tunnel junction hybrid latches

Abstract

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