Emerging memories

Baldi, L.; Bez, R.; Sandhu, Gurtej

doi:10.1016/j.sse.2014.06.009

Cited by 26 publications

(20 citation statements)

References 37 publications

(37 reference statements)

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“…After dominating the semiconductor memory market for the past four decades because of their simple structure (one transistor–one capacitor) and fast write/read access (10 ns/10 ns), dynamic random access memories (DRAM) have now reached their scalability limit. , Among the strongest contenders to replace DRAM technology are ferroelectric tunnel junctions (FTJs). , These memory devices have the advantages of being nonvolatile and highly scalable, in addition to displaying a high switching speed (10 ns) and a high endurance (4 × 10 6 cycles) and operating at low switching energies. Their structure is relatively simple (one transistor–one resistor) and similar to PC-RAM, where one cell resistor is composed of an ultrathin (a few nanometers) ferroelectric layer deposited between two conductive electrodes. , FTJs exploit resistive switching, a reversible process that consists of toggling between a high-resistance state (HRS) and a low-resistance state (LRS) via bipolar voltages to the device. − These two states correspond to the logical “0” and “1” in binary code directly related to the orientation of ferroelectric domains.…”

Section: Introductionmentioning

confidence: 99%

BiFe_1–xCr_xO₃ Ferroelectric Tunnel Junctions for Neuromorphic Systems

Kolhatkar

Mittermeier

González

et al. 2019

ACS Appl. Electron. Mater.

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We report on the fabrication of ferroelectric tunnel junctions of BiFe0.45Cr0.55O3 as a tunneling barrier, Nb-doped (111) SrTiO3 as a bottom electrode, and platinum as a top electrode. BiFeO3 is a generic multiferroic material with perspectives for multiferroic tunnel junctions, with chromium being introduced to shift and enhance the magnetic ordering from canted magnetization to ferrimagnetism. We deposit the ferroelectric films by radio frequency magnetron sputtering, an industry-compatible synthesis method. After confirming the BiFe1–x Cr x O3 film composition and its partial crystallinity, we found possible indications of ferroelectricity through piezoresponse force microscopy. X-ray photoelectron spectroscopy together with optical band measurements provide the electronic band profile of the Nb:SrTiO3/BiFe1–x Cr x O3/Pt structures. Pulsed electrical characterization reveals resistive switching with very high fatigue resistance (>106 cycles) consistent with direct tunneling across a trapezoidal barrier for a surface fraction of the film. These results make BiFe1–x Cr x O3 a promising candidate for ferroelectric tunnel junctions in particular, as they are able to operate as artificial synapses for neuromorphic circuit tiles as evidenced by spike-timing-dependent plasticity.

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Section: Introductionmentioning

confidence: 99%

BiFe_1–xCr_xO₃ Ferroelectric Tunnel Junctions for Neuromorphic Systems

Kolhatkar

Mittermeier

González

et al. 2019

ACS Appl. Electron. Mater.

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“…Resistive memories are promising devices that could be part of the memories catalog or eventually replace nonvolatile flash memory in the future [21,22]. Among all competing technologies for the next generation of solid-state memory, RRAM combines all the virtues requested by industry [1], which explains the tremendous research efforts that have been carried out by research groups in both universities and microelectronic industries.…”

Section: Planar Nanometric Resistive Memorymentioning

confidence: 99%

A Fabrication Process for Emerging Nanoelectronic Devices Based on Oxide Tunnel Junctions

Drouin

Droulers

Labalette

et al. 2017

Journal of Nanomaterials

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We present a versatile nanodamascene process for the realization of low-power nanoelectronic devices with different oxide junctions. With this process we have fabricated metal/insulator/metal junctions, metallic single electron transistors, silicon tunnel field effect transistors, and planar resistive memories. These devices do exploit one or two nanometric-scale tunnel oxide junctions based on TiO2, SiO2, HfO2, Al2O3, or a combination of those. Because the nanodamascene technology involves processing temperatures lower than 300°C, this technology is fully compatible with CMOS back-end-of-line and is used for monolithic 3D integration.

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“…Specifically FeRAM is sensitive to contamination during the back-end-process integration, while PCRAM is temperature-sensitive which makes it ill-suited for space and nuclear applications. 67 MRAM and ReRAM are considered as the forerunners due to their excellent performance, CMOS compatibility, and radiation tolerance.…”

Section: Introductionmentioning

confidence: 99%

Low-power electronic technologies for harsh radiation environments

et al. 2021

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Over the past decades, electronic technologies have evolved to serve a wide range of applications, with some necessitating their reliable operation in harsh radiation environments. This perspective article reviews the current landscape in rad-hard electronics, covering the scope of radiation environments, the application needs, the underlying phenomena that impose functional constraints as well as established design methodologies, relying on commercially available technologies (CMOS) for mitigating e↵ects that lead to failure. We further examine the potential of emerging memristive technologies in this field and their properties that render these rad-hard. We also review a variety of rad-hard device designs, rad-mitigation techniques, and experimental procedures for validating the performance of the most promising solutions. Finally, we conclude this article by presenting a roadmap on new concepts and application opportunities enabled by the introduction of novel technologies and designs that can reliably operate under such extreme conditions. topilot upsets that occur on average once in every 200 flight hours, notwithstanding, electrical upsets in automotive electronics and data centers. 3,7 In addition, the solar flares' intense particles and X-rays ionize and increase the density of the low layers of ionosphere, respectively, and interact with the electromagnetic waves resulting into disturbances in the high-frequency radio communication system by fading of the HF signal. 3 These problems eventually a↵ect the stability of the flight system, and tra c operations and navigations both in airspace and on the ground, where safety assurance is of primary importance. Similarly, the operation of nuclear facilities in a safety critical manner is of paramount importance and rad-hard technologies are commonly employed to enhance the overall safety margins. 8 Moreover, radiation e↵ects raise a concern in medical and industrial equipment where X-ray and are used for therapy and diagnostic purposes while in highenergy physics facilities, various particles and photons are generated by the collisions in particle accelerators which pose a severe challenge for the accelerator instrumentation and the radiation detection, data acquisition and communication in the embarked experiments. 9Nevertheless, rad-hard integrated circuit technologies often require additional processing and more complex configurations than the standard fabrication flow that makes the rad-hard electronics, particularly low-power electronic technologies, di cult to keep up with the International Technology Roadmap for Semiconductors (ITRS) guide. 10 This article examines the latest logic and memory design techniques for radiation e↵ect mitigation and presents future trends for rad-hard technologies.

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Emerging memories

Cited by 26 publications

References 37 publications

BiFe_1–xCr_xO₃ Ferroelectric Tunnel Junctions for Neuromorphic Systems

BiFe_1–xCr_xO₃ Ferroelectric Tunnel Junctions for Neuromorphic Systems

A Fabrication Process for Emerging Nanoelectronic Devices Based on Oxide Tunnel Junctions

Low-power electronic technologies for harsh radiation environments

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Emerging memories

Cited by 26 publications

References 37 publications

BiFe1–xCrxO3 Ferroelectric Tunnel Junctions for Neuromorphic Systems

BiFe1–xCrxO3 Ferroelectric Tunnel Junctions for Neuromorphic Systems

A Fabrication Process for Emerging Nanoelectronic Devices Based on Oxide Tunnel Junctions

Low-power electronic technologies for harsh radiation environments

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Product

Resources

About

BiFe_1–xCr_xO₃ Ferroelectric Tunnel Junctions for Neuromorphic Systems

BiFe_1–xCr_xO₃ Ferroelectric Tunnel Junctions for Neuromorphic Systems