Influence of heavy ion irradiation on perpendicular-anisotropy CoFeB-MgO magnetic tunnel junctions

Kobayashi, Daisuke; Kakehashi, Yuya; Hirose, Katsumi; Onoda, Shinobu; Makino, Takahiro; Ohshima, Takeshi; Ikeda, Shoji; Yamanouchi, Michihiko; Sasaki, Hideo; Enobio, Eli Christopher I.; Endoh, Tetsuo; Ohno, Hideo

doi:10.1109/radecs.2013.6937425

Cited by 10 publications

(10 citation statements)

References 13 publications

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“…In particular, spintronics devices have been gaining attention as an appropriate substrate for PRC because of their compactness, high-speed processing, and energy efficiency while being able to function at normal temperatures [73][74][75][76][78][79][80][81][82][83][84][85]. These assets are somewhat common in the computer science field, but spintronics devices also contain an inter- esting additional property: they show high durability in radioactive environments [183] (Fig. 7B).…”

Section: Exploiting Physical Dynamics For Computational Purposesmentioning

confidence: 99%

Physical reservoir computing—an introductory perspective

Nakajima

2020

Jpn. J. Appl. Phys.

311

174

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Understanding the fundamental relationships between physics and its information-processing capability has been an active research topic for many years. Physical reservoir computing is a recently introduced framework that allows one to exploit the complex dynamics of physical systems as information-processing devices. This framework is particularly suited for edge computing devices, in which information processing is incorporated at the edge (e.g., into sensors) in a decentralized manner to reduce the adaptation delay caused by data transmission overhead. This paper aims to illustrate the potentials of the framework using examples from soft robotics and to provide a concise overview focusing on the basic motivations for introducing it, which stem from a number of fields, including machine learning, nonlinear dynamical systems, biological science, materials science, and physics.

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Section: Exploiting Physical Dynamics For Computational Purposesmentioning

confidence: 99%

Physical reservoir computing—an introductory perspective

Nakajima

2020

Jpn. J. Appl. Phys.

311

174

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“…2 shows two main soft-error mechanisms of the MTJ device. The state of the MTJ device is quite robust against direct particle strikes [10], but might be flipped by a current pulse signal generated at peripheral transistors due to particle strikes at low probability [11]. In the example shown in Fig.…”

Section: Soft-error Tolerant Mtj/mos Hybrid Tcam Cellmentioning

confidence: 99%

“…The MTJ device stores one-bit information as a resistance value [7] and has recently been exploited for nonvolatile memories (MRAM) and TCAMs [8], [9]. The stored bit is quite robust against direct particle strikes [10], but might be flipped by a current pulse signal generated at peripheral transistors due to particle strikes [11]. In the proposed cell, one-bit information is redundantly represented using three MTJ devices to mask one-bit error per cell.…”

Section: Introductionmentioning

confidence: 99%

Design of a soft-error tolerant 9-transistor/6-magnetic-tunnel-junction hybrid cell based nonvolatile TCAM

Onizawa

Matsunaga

Hanyu

2014

2014 IEEE 12th International New Circuits and Systems Conference (NEWCAS)

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This paper introduces a soft-error tolerant ternary content-addressable memory (TCAM) cell based on a transistor/magnetic-tunnel-junction (MTJ) hybrid structure. The MTJ device stores one-bit information as a resistance value and is often used for non-volatile memories. In the proposed nine-transistor (9T)/six-MTJ (6MTJ) cell, one-bit information is redundantly represented using three MTJs to mask a one-bit error per cell that might be occurred due to particle strikes. Thanks to the stackability of the MTJ device over a CMOS layer, there is no area overhead due to the redundancy compared to a conventional 9T-2MTJ cell. A 256-word 64-bit TCAM based on the proposed cell is designed under a 90nm CMOS/MTJ process and is evaluated using HSPICE simulation. The simulation resultsshow that the proposed TCAM properly operates under a one-bit error per cell with comparable energy, area and a 14% delay overhead compared to the conventional TCAM. Compared to a CMOS-based TCAM with an error-correction code that masks a one-bit error per word, the proposed TCAM reduces the nubmer of transistors by 81% while masking a one-bit error per cell.

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“…Regarding write errors, data bits might be incorrectly written to MTJ devices due to the probabilistic switching behavior of MTJ devices. [9][10][11][12][13] Regarding soft errors, the MTJ device itself is robust against soft errors 14,15) due to alpha particle and neutron strikes, whereas these strikes induce single-event transients (SETs) and single-event upsets (SEUs) in MOS transistors. 16,17) As a result, data bits flipped by a SET or SEU in MOS transistors are written to MTJ devices, causing soft errors in CMOS=MTJ circuits.…”

Section: Introductionmentioning

confidence: 99%

Soft/write-error-resilient CMOS/magnetic tunnel junction nonvolatile flip-flop based on majority-decision shared writing

Onizawa

Hanyu

2017

Jpn. J. Appl. Phys.

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A soft/write-error-resilient nonvolatile flip-flop (NVFF) using three-terminal magnetic tunnel junctions (MTJs) is presented. The proposed NVFF exploits a redundant structure with a majority bit implicitly stored, which is tolerant to soft errors including both single-event transients (SETs) and single-event upsets (SEUs). For write-error resilience, all the bits of the redundant MTJs are written using the majority bit with a shared writecurrent path, exhibiting 1-bit soft-error correction and 1-bit write-error masking. In addition, the shared writing scheme reduces the number of writecurrent paths to one-third of that with a redundant NVFF with 1-bit soft/write-error masking. Using 65 nm CMOS/MTJ technologies, the proposed NVFF achieves a few orders-of-magnitude reduction in the failure in time (FIT), a 31% reduction in the transistor count, and a 65% reduction in the write energy in comparison with the redundant NVFF.

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Influence of heavy ion irradiation on perpendicular-anisotropy CoFeB-MgO magnetic tunnel junctions

Cited by 10 publications

References 13 publications

Physical reservoir computing—an introductory perspective

Physical reservoir computing—an introductory perspective

Design of a soft-error tolerant 9-transistor/6-magnetic-tunnel-junction hybrid cell based nonvolatile TCAM

Soft/write-error-resilient CMOS/magnetic tunnel junction nonvolatile flip-flop based on majority-decision shared writing

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