Spin Transfer Torque Based Devices, Circuits, and Memory
Spin Transfer Torque Based Devices, Circuits, and Memory

Author: Brajesh Kumar Kaushik

Publisher: MICROTECHNOLOGY NANOTECHNOLOGY

Published: 2016

Total Pages: 0

ISBN-13: 9781630810917

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This first-of-its-kind resource is completely dedicated to spin transfer torque (STT) based devices, circuits, and memory. A wide range of topics including, STT MRAMs, MTJ based logic circuits, simulation and modeling strategies, fabrication of MTJ CMOS circuits, non-volatile computing with STT MRAMs, all spin logic, and spin information processing are explored. State-of-the-art modeling and simulation strategies of spin transfer torque based devices and circuits in a lucid manner are covered. Professional engineers find practical guidance in the development of micro-magnetic models of spin-torque based devices in object-oriented micro-magnetic framework (OOMMF) and compact modeling of STT based magnetic tunnel junctions in Verilog-A.The performance parameters and design aspects of STT MRAMs and MTJ based hybrid spintronic CMOS circuits are covered and case studies are presented demonstrating STT-MRAM design and simulation with a detailed analysis of results. The fundamental physics of STT based devices are presented with an emphasis on new advancements from recent years. Advanced topics are also explored including, micromagnetic simulations, multi-level STT MRAMs, giant spin Hall Effect (GSHE) based MRAMs, non-volatile computing, all spin logic and all spin information processing.

Next Generation Spin Torque Memories
Next Generation Spin Torque Memories

Author: Brajesh Kumar Kaushik

Publisher: Springer

Published: 2017-04-07

Total Pages: 107

ISBN-13: 981102720X

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This book offers detailed insights into spin transfer torque (STT) based devices, circuits and memories. Starting with the basic concepts and device physics, it then addresses advanced STT applications and discusses the outlook for this cutting-edge technology. It also describes the architectures, performance parameters, fabrication, and the prospects of STT based devices. Further, moving from the device to the system perspective it presents a non-volatile computing architecture composed of STT based magneto-resistive and all-spin logic devices and demonstrates that efficient STT based magneto-resistive and all-spin logic devices can turn the dream of instant on/off non-volatile computing into reality.

Spin Transfer Torque Based Devices, Circuits, and Memory
Spin Transfer Torque Based Devices, Circuits, and Memory

Author: Brajesh Kumar Kaushik

Publisher: Artech House

Published: 2016-10-31

Total Pages: 297

ISBN-13: 1630814369

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This first-of-its-kind resource is completely dedicated to spin transfer torque (STT) based devices, circuits, and memory. A wide range of topics including, STT MRAMs, MTJ based logic circuits, simulation and modeling strategies, fabrication of MTJ CMOS circuits, non-volatile computing with STT MRAMs, all spin logic, and spin information processing are explored. State-of-the-art modeling and simulation strategies of spin transfer torque based devices and circuits in a lucid manner are covered. Professional engineers find practical guidance in the development of micro-magnetic models of spin-torque based devices in object-oriented micro-magnetic framework (OOMMF) and compact modeling of STT based magnetic tunnel junctions in Verilog-A. The performance parameters and design aspects of STT MRAMs and MTJ based hybrid spintronic CMOS circuits are covered and case studies are presented demonstrating STT-MRAM design and simulation with a detailed analysis of results. The fundamental physics of STT based devices are presented with an emphasis on new advancements from recent years. Advanced topics are also explored including, micromagnetic simulations, multi-level STT MRAMs, giant spin Hall Effect (GSHE) based MRAMs, non-volatile computing, all spin logic and all spin information processing.

Magnetic Memory Technology
Magnetic Memory Technology

Author: Denny D. Tang

Publisher: John Wiley & Sons

Published: 2021-01-07

Total Pages: 352

ISBN-13: 1119562236

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STAY UP TO DATE ON THE STATE OF MRAM TECHNOLOGY AND ITS APPLICATIONS WITH THIS COMPREHENSIVE RESOURCE Magnetic Memory Technology: Spin-Transfer-Torque MRAM and Beyond delivers a combination of foundational and advanced treatments of the subjects necessary for students and professionals to fully understand MRAM and other non-volatile memories, like PCM, and ReRAM. The authors offer readers a thorough introduction to the fundamentals of magnetism and electron spin, as well as a comprehensive analysis of the physics of magnetic tunnel junction (MTJ) devices as it relates to memory applications. This book explores MRAM's unique ability to provide memory without requiring the atoms inside the device to move when switching states. The resulting power savings and reliability are what give MRAM its extraordinary potential. The authors describe the current state of academic research in MRAM technology, which focuses on the reduction of the amount of energy needed to reorient magnetization. Among other topics, readers will benefit from the book's discussions of: An introduction to basic electromagnetism, including the fundamentals of magnetic force and other concepts An thorough description of magnetism and magnetic materials, including the classification and properties of magnetic thin film properties and their material preparation and characterization A comprehensive description of Giant magnetoresistance (GMR) and tunneling magnetoresistance (TMR) devices and their equivalent electrical model Spin current and spin dynamics, including the properties of spin current, the Ordinary Hall Effect, the Anomalous Hall Effect, and the spin Hall effect Different categories of magnetic random-access memory, including field-write mode MRAM, Spin-Torque-Transfer (STT) MRAM, Spin-Orbit Torque (SOT) MRAM, and others Perfect for senior undergraduate and graduate students studying electrical engineering, similar programs, or courses on topics like spintronics, Magnetic Memory Technology: Spin-Transfer-Torque MRAM and Beyond also belongs on the bookshelves of engineers and other professionals involved in the design, development, and manufacture of MRAM technologies.

Spintronics-based Computing
Spintronics-based Computing

Author: Weisheng Zhao

Publisher: Springer

Published: 2015-05-11

Total Pages: 259

ISBN-13: 3319151800

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This book provides a comprehensive introduction to spintronics-based computing for the next generation of ultra-low power/highly reliable logic. It will cover aspects from device to system-level, including magnetic memory cells, device modeling, hybrid circuit structure, design methodology, CAD tools, and technological integration methods. This book is accessible to a variety of readers and little or no background in magnetism and spin electronics are required to understand its content. The multidisciplinary team of expert authors from circuits, devices, computer architecture, CAD and system design reveal to readers the potential of spintronics nanodevices to reduce power consumption, improve reliability and enable new functionality.

Nanoscale Nonvolatile Memory Circuit Design Using Emerging Spin Transfer Torque Magnetic Random Access Memory
Nanoscale Nonvolatile Memory Circuit Design Using Emerging Spin Transfer Torque Magnetic Random Access Memory

Author: Lohith Kumar Vemula

Publisher:

Published: 2016

Total Pages: 72

ISBN-13:

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The spin transfer torque magnetic random access memory (STT-MRAM) is suitable for embedded and second level cache memories in the mobile CPUs. STT-MRAM is a highly potential nonvolatile memory (NVM) technology. There has been a growing demand to improve the efficiency and reliability of the NVM circuits and architectures. we present a modified STT MRAM cell design, where each cell is comprised of one magnetic tunneling junction (MTJ) device and a regular access transistor. We provide analysis of device, circuit and memory architecture level issues of STT-MRAM. The Modified 1M1T STT-MRAM bit cell circuit offers simpler and more area- and power- efficient design compared to the existing STT-MRAM cell design. Some device-circuit co-design issues are investigated to demonstrate ways to reduce delay in MRAM circuits based on MTJ. An 8x8 conventional MRAM array is implemented using the existing 2M2T cell and the Modified 1M1T cell to perform a comparative analysis at the architecture level. The non-volatile nature of the proposed STT-MRAM is verified through SPICE simulation. The circuit implementations and simulations are performed for 45nm technology node. As the transistor scales down it is prone to subthreshold leakage, gate-dielectric leakage, Short channel effect and drain induced barrier lowering. Now alternative of Access transistor is needed. We are using FinFET as access transistor in the STT-MRAM bit cell. FinFET based bit cell is designed to get an advantage of scaling down. Analysis is done and proven that the power consumption, standalone leakage current is less when compared to NMOS based STT-MRAM bit cell. Also determined FinFET based bit cell produces less access time to access the logic value from MTJ. Now, Industry is looking to have computational and storage capability together and that can be achieved through STT-MRAM. Addition to that there is a possibility to reduce power consumption and leakage more. So replacing FinFET technology with Carbon Nano Tube Field Effect Transistor (CNTFET) is required. As the conventional STT-MRAM requires certain current to reverse the magnetization of MTJ and one CNTFET alone cannot produce sufficient current required to store the logic value into MTJ. So new Bit cell is proposed using 3 CNTFET and 1 MTJ, this bit cell is capable of storing 3 logic values at a time that is capable of doing computation and act as AND gate. Also it utilizes less power to be in active region. Sensing of any memory system is one of the main challenge in industry to get better performance with less resources. Conventional Sense Amplifier (SA) used to sense the value from SRAM, DRAM memory system is also used to sense the STT-MRAM memory. But use of conventional SA is prone to some error. Modified Sense Amplifier is designed to overcome the error produced from the conventional SA. It is compared with all the existing SA to get the performance details of the modified SA.

Scalable Spin Torque Driven Devices and Circuits for High Performance Memory and Computing
Scalable Spin Torque Driven Devices and Circuits for High Performance Memory and Computing

Author: Mohammad Kazemi

Publisher:

Published: 2019

Total Pages: 128

ISBN-13:

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"As CMOS technology approaches the intrinsic limits of scalability, higher performance requires more power consumption and circuit area. Employing the spin degree of freedom of electrons alone or in combination with the charge of electrons provides opportunities to reduce the power dissipation, enhance the performance of operation, and increase the integration density of computing systems. This dissertation describes studies of nanomagnetic spinbased devices and associated CMOS circuits for scalable, high performance memory and computing systems. The power, speed, and area tradeoffs associated with the magnetoresistive random access memory (MRAM) operating on the spin-transfer torque (STT) mechanism are investigated. Then, a memory system is presented which effectively addresses the challenges associated with the STT-MRAM by providing a hybrid dynamic/nonvolatile platform for data retention. The focus is next turned to memory and logic devices operating on spin-orbit torques (SOTs). To pave the way toward very-large-scale-integration (VLSI) systems delivering high performance operation with low power dissipation, mechanisms are described to effectively address three fundamental challenges in spin-orbitronics: (a) All-electrical deterministic switching, (b) Intrinsic logic operation, and (c) scalability. It is shown that shaping the magnetic energy landscape of perpendicularanisotropy devices breaks the symmetry of the SOT operation on the magnetization, thus enabling all-electrical switching using unipolar current pulses. It is also shown that the capability to switch magnetic devices with unipolar current pulses leads to a spin-orbit MRAM cell which, in contrast to state-of-the-art cells, provides read/write access via a single transistor. For spin-based computing to be adopted widely, energy efficient, high performance logic gates comprised of as few devices as possible are required. A universal logic gate is presented that can be implemented using the minimum possible number of spin-orbit devices. The gate performs logic operations in a ?stateful' manner, that is, the same devices retaining the logic operands simultaneously perform the logic operations and latch the outcome. Such universal logic gates greatly increase on-chip computational resources which can be effectively utilized thanks to the low energy dissipation. Finally, it is shown that scalability is not a fundamental limitation in spin-orbitronics. Design rules are derived that indicate the path to building deeply scalable spin-orbit devices exhibiting sub-nanosecond switching time at room temperature. Accordingly, we show that the spin-orbitronics may serve as a universal memory technology capable of implementing multiple levels of memory hierarchy."--Pages xii-xiii.

Introduction to Magnetic Random-Access Memory
Introduction to Magnetic Random-Access Memory

Author: Bernard Dieny

Publisher: John Wiley & Sons

Published: 2016-11-14

Total Pages: 264

ISBN-13: 1119079357

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Magnetic random-access memory (MRAM) is poised to replace traditional computer memory based on complementary metal-oxide semiconductors (CMOS). MRAM will surpass all other types of memory devices in terms of nonvolatility, low energy dissipation, fast switching speed, radiation hardness, and durability. Although toggle-MRAM is currently a commercial product, it is clear that future developments in MRAM will be based on spin-transfer torque, which makes use of electrons’ spin angular momentum instead of their charge. MRAM will require an amalgamation of magnetics and microelectronics technologies. However, researchers and developers in magnetics and in microelectronics attend different technical conferences, publish in different journals, use different tools, and have different backgrounds in condensed-matter physics, electrical engineering, and materials science. This book is an introduction to MRAM for microelectronics engineers written by specialists in magnetic materials and devices. It presents the basic phenomena involved in MRAM, the materials and film stacks being used, the basic principles of the various types of MRAM (toggle and spin-transfer torque; magnetized in-plane or perpendicular-to-plane), the back-end magnetic technology, and recent developments toward logic-in-memory architectures. It helps bridge the cultural gap between the microelectronics and magnetics communities.

Normally-Off Computing
Normally-Off Computing

Author: Takashi Nakada

Publisher: Springer

Published: 2017-01-18

Total Pages: 137

ISBN-13: 4431565051

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As a step toward ultimate low-power computing, this book introduces normally-off computing, which involves inactive components of computer systems being aggressively powered off with the help of new non-volatile memories (NVMs). Because the energy consumption of modern information devices strongly depends on both hardware and software, co-design and co-optimization of hardware and software are indispensable to improve energy efficiency. The book discusses various topics including (1) details of low-power technologies including power gating, (2) characteristics of several new-generation NVMs, (3) normally-off computing architecture, (4) important technologies for implementing normally-off computing, (5) three practical implementations: healthcare, mobile information devices, and sensor network systems for smart city applications, and (6) related research and development. Bridging computing methodology and emerging memory devices, the book is designed for both hardware and software designers, engineers, and developers as comprehensive material for understanding normally-off computing.

Nanomagnetic and Spintronic Devices for Energy-Efficient Memory and Computing
Nanomagnetic and Spintronic Devices for Energy-Efficient Memory and Computing

Author: Jayasimha Atulasimha

Publisher: John Wiley & Sons

Published: 2016-03-07

Total Pages: 356

ISBN-13: 1118869265

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Nanomagnetic and spintronic computing devices are strong contenders for future replacements of CMOS. This is an important and rapidly evolving area with the semiconductor industry investing significantly in the study of nanomagnetic phenomena and in developing strategies to pinpoint and regulate nanomagnetic reliably with a high degree of energy efficiency. This timely book explores the recent and on-going research into nanomagnetic-based technology. Key features: Detailed background material and comprehensive descriptions of the current state-of-the-art research on each topic. Focuses on direct applications to devices that have potential to replace CMOS devices for computing applications such as memory, logic and higher order information processing. Discusses spin-based devices where the spin degree of freedom of charge carriers are exploited for device operation and ultimately information processing. Describes magnet switching methodologies to minimize energy dissipation. Comprehensive bibliographies included for each chapter enabling readers to conduct further research in this field. Written by internationally recognized experts, this book provides an overview of a rapidly burgeoning field for electronic device engineers, field-based applied physicists, material scientists and nanotechnologists. Furthermore, its clear and concise form equips readers with the basic understanding required to comprehend the present stage of development and to be able to contribute to future development. Nanomagnetic and Spintronic Devices for Energy-Efficient Memory and Computing is also an indispensable resource for students and researchers interested in computer hardware, device physics and circuits design.