Reducing error rates in straintronic multiferroic nanomagnetic logic by pulse shaping

Munira, Kamaram; Xie, Yunkun; Nadri, Souheil; Forgues, Mark B.; Fashami, Mohammad Salehi; Atulasimha, Jayasimha; Bandyopadhyay, Supriyo; Ghosh, Avik W.

doi:10.1088/0957-4484/26/24/245202

Cited by 30 publications

(27 citation statements)

References 41 publications

(63 reference statements)

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“…The latter are more energy-efficient, but also more error-prone. Theoretical estimates of switching errors in magneto-elastic switching (straintronics) range from 10 -3 [8] to as low as 10 -8 [9], but experiments show a much larger error probability exceeding 0.1 [10,11]. Recently, we showed that this large difference between theory and experiments accrues from the fact that real nanomagnets used in experiments invariably have structural defects and they exacerbate the switching error [12].…”

Section: Introductionmentioning

confidence: 94%

Low Energy Barrier Nanomagnet Design for Binary Stochastic Neurons: Design Challenges for Real Nanomagnets With Fabrication Defects

Abeed

Bandyopadhyay

2019

IEEE Magn. Lett.

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Much attention has been focused on the design of low barrier nanomagnets (LBM), whose magnetizations vary randomly in time owing to thermal noise, for use in binary stochastic neurons (BSN) which are hardware accelerators for machine learning. The performance of BSNs depend on two important parameters: the correlation time c associated with the random magnetization dynamics in a LBM, and the spin-polarized pinning current Ip which stabilizes the magnetization of a LBM in a chosen direction within a chosen time. Here, we show that common fabrication defects in LBMs make these two parameters unpredictable since they are strongly sensitive to the defects. That makes the design of BSNs with real LBMs very challenging. Unless the LBMs are fabricated with extremely tight control, the BSNs which use them could be unreliable or suffer from poor yield.Index Terms-Low barrier magnets, binary stochastic neurons, correlation time, pinning currents, effect of defects.

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Section: Introductionmentioning

confidence: 94%

Low Energy Barrier Nanomagnet Design for Binary Stochastic Neurons: Design Challenges for Real Nanomagnets With Fabrication Defects

Abeed

Bandyopadhyay

2019

IEEE Magn. Lett.

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“…The effect of thermal noise is incorporated by adding an equivalent field   thermal Ht to the total effective field [11,12,15,[20][21][22]:…”

Section:  mentioning

confidence: 99%

“…The Achilles' heel of strain-clocked DC-NML is its poor reliability due to high switching error rates at room temperature [10][11][12][13][14]. In this paper, we explore ways of mitigating the poor reliability, particularly through the use of appropriate geometry of the nanomagnets, and identify the metrics that have to be sacrificed to attain increased robustness.…”

Section: Introductionmentioning

confidence: 99%

Effect of Nanomagnet Geometry on Reliability, Energy Dissipation, and Clock Speed in Strain-Clocked DC-NML

Al-Rashid

Bhattacharya

Bandyopadhyay

et al. 2015

IEEE Trans. Electron Devices

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Abstract-Strain-clocked dipole-coupled nanomagnetic logic is an energy-efficient Boolean logic paradigm whose progress has been stymied by its propensity for high error rates. In an effort to mitigate this problem, we have studied the effect of nanomagnet geometry on error rates, focusing on elliptical and cylindrical geometries. We had previously reported that in elliptical nanomagnets, the out-of-plane excursion of the magnetization vector during switching creates a precessional torque that plays a dual role -it speeds up the switching but is also responsible for the high switching error probability. The absence of this torque in cylindrical magnets portends lower error rates, but our simulations show that the error rate actually does not improve significantly compared to elliptical magnets while the switching becomes unacceptably slow. Here, we show that dipole coupled nanomagnetic logic employing elliptical nanomagnets can offer relatively high reliability for nanomagnetic logic (switching error probability < 10 -8 ), moderate clock speed (~ 100 MHz) and 2-3 orders of magnitude energy saving compared to CMOS devices, provided the shape anisotropy energy barrier of the nanomagnet is increased to at least ~5.5 eV to allow engineering a stronger dipole coupling between neighboring nanomagnets.

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“…Due to its crucial importance, the effect of thermal noise on the dynamic behavior of the magnetization in a nanomagnet has been the subject of study in the literature. [24][25][26][27] A general study of the dynamics in a single domain magnet under Langevin thermal noise has been published previously, 24 providing a comprehensive statistical analysis on the magnetization dynamics with and without the effect of external magnetic field. Analysis of the dynamics in strain-induced multiferroics has also been the subject of study recently.…”

Section: Introductionmentioning

confidence: 99%

Effect of temperature variations and thermal noise on the static and dynamic behavior of straintronics devices

Barangi

Mazumder

2015

Journal of Applied Physics

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A theoretical model quantifying the effect of temperature variations on the magnetic properties and static and dynamic behavior of the straintronics magnetic tunneling junction is presented. Four common magnetostrictive materials (Nickel, Cobalt, Terfenol-D, and Galfenol) are analyzed to determine their temperature sensitivity and to provide a comprehensive database for different applications. The variations of magnetic anisotropies are studied in detail for temperature levels up to the Curie temperature. The energy barrier of the free layer and the critical voltage required for flipping the magnetization vector are inspected as important metrics that dominate the energy requirements and noise immunity when the device is incorporated into large systems. To study the dynamic thermal noise, the effect of the Langevin thermal field on the free layer's magnetization vector is incorporated into the Landau-Lifshitz-Gilbert equation. The switching energy, flipping delay, write, and hold error probabilities are studied, which are important metrics for nonvolatile memories, an important application of the straintronics magnetic tunneling junctions.

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Reducing error rates in straintronic multiferroic nanomagnetic logic by pulse shaping

Cited by 30 publications

References 41 publications

Low Energy Barrier Nanomagnet Design for Binary Stochastic Neurons: Design Challenges for Real Nanomagnets With Fabrication Defects

Low Energy Barrier Nanomagnet Design for Binary Stochastic Neurons: Design Challenges for Real Nanomagnets With Fabrication Defects

Effect of Nanomagnet Geometry on Reliability, Energy Dissipation, and Clock Speed in Strain-Clocked DC-NML

Effect of temperature variations and thermal noise on the static and dynamic behavior of straintronics devices

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