Physics, Structures, and Applications of Fluorite‐Structured Ferroelectric Tunnel Junctions

Hwang, Junghyeon; Goh, Youngin; Jeon, Sanghun

doi:10.1002/smll.202305271

Cited by 7 publications

(7 citation statements)

References 126 publications

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“…Very frequently 2D materials occupy flawless interfaces where barriers are negligibly thin (usually less than a nanometer). The essence connecting a photodetector to these is that when photons are being closely absorbed from a thin diffused layer,they afterwards appear as electron-hole pairs [45]. The tunnel effect allows the electrons to flow through the barrier even though it is very thin because the electrons have their quantum mechanical property, i.e., they can go through the barrier as waves and not particles, unlike other materials.…”

Section: The Underlying Physical Mechanisms Of Photodetectorsmentioning

confidence: 99%

Recent advancements and progress in development in chalcogenide (S, Se)-based thin films for high-performance photodetectors: a review

Alanazi,

Alzaidy

2024

Phys. Scr.

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Scientific and technical communities often debate photodetection as a significant technology due to its unquestionable and extensive usage in business and research. Traditional bulk semiconductors like GaN, Si, and InGaAs are being used less and less for photodetection in industry because they aren’t mechanically stable or flexible enough, they have expensive substrates, and charge carriers can’t move around freely enough. Nonetheless, 2D materials such as transition-metal nitrides, chalcogenides, and carbides, in addition to graphene, are leading the path toward achieving more sophisticated results and surpassing the limitations imposed by traditional semiconductors. This is due to their exceptional electronic and mechanical properties, which include flexibility, adjustable bandgaps, high mobilities, and ample potential for constructing heterojunctions of chalcogenides-based thin films. Given the recent surge in photodetection research, the field has expanded significantly and requires a systematic compilation of pertinent scientific knowledge. A comprehensive study must address many aspects of chalcogenides-based thin film manufacturing strategies, assembly procedures, device integration, spectral properties, heterojunction potential, and future research prospects. This paper specifically examines the use of chalcogenides-based thin film materials in photodetection. These areas include solar-blind, visible, near-infrared, and broadband detectors. We have expanded our discussion to include photodetector performance parameters and how the latest chalcogenides-based thin films formed by combining ordinary semiconductors have resulted in high-performance UV, visible, and IR range photodetection. These materials have the potential to be used as photodetectors. Ultimately, we provide a comparative demonstration of the performance characteristics of photodetectors, offering a distinct assessment of the suitability of these materials for use in the advancement of next-generation photodetectors.

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Section: The Underlying Physical Mechanisms Of Photodetectorsmentioning

confidence: 99%

Recent advancements and progress in development in chalcogenide (S, Se)-based thin films for high-performance photodetectors: a review

Alanazi,

Alzaidy

2024

Phys. Scr.

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“…As very large amounts of data processing become more frequent with data transfer between the memory and processor, bottlenecks occur in the traditional von Neumann computing architecture, where the memory and processor are separated. In order to solve such bottlenecks, in-memory computing structures that perform operations during memory access have been proposed as alternatives. − In-memory computing not only consolidates memory and processors to reduce the power used for data transfer but also enables parallel computing, enabling high throughput. However, due to a large amount of data and computation, there are still limitations that require huge power consumption and a very large chip size as well as being unusable for mobile and edge computing.…”

Section: Introductionmentioning

confidence: 99%

Monolithically Integrated Complementary Ferroelectric FET XNOR Synapse for the Binary Neural Network

Hwang,

Joh,

Kim

et al. 2024

ACS Appl. Mater. Interfaces

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Neuromorphic computing, which mimics the structure and principles of the human brain, has the potential to facilitate the hardware implementation of next-generation artificial intelligence systems and process large amounts of data with very low power consumption. Among them, the XNOR synapse-based Binary Neural Network (BNN) has been attracting attention due to its compact neural network parameter size and low hardware cost. The previous XNOR synapse has drawbacks, such as a trade-off between cell density and accuracy. In this work, we show nonvolatile XNOR synapses with high density and accuracy using a monolithically stacked complementary ferroelectric field-effect transistor (C-FeFET) composed of a p-type Si MFMIS-FeFET at the bottom and a 3D stackable n-type Al:IZTO MFS-FeTFT, achieving 60F 2 per cell (2C-FeFET). For adjusting the threshold voltage and improving the switching speed (100 ns) of n-type ferroelectric TFT, we employed a dual-gate configuration and a unique operation scheme, making it comparable to those of Si-based FeFETs. We performed array-level simulation with a 512 × 512 subarray size and a 3-bit flash ADC, demonstrating that the image recognition accuracies using the MNIST and CIFAR-10 data sets were increased by 3.17 and 14.07%, respectively, in comparison to other nonvolatile XNOR synapses. In addition, we performed system-level analysis on a 512 × 512 XNOR C-FeFET, exhibiting an outstanding throughput of 717.37 GOPS and an energy efficiency of 196.7 TOPS/W. We expect that our approach would contribute to the high-density memory systems, logic-in-memory technology, and hardware implementation of neural networks.

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“…FeFETs offer a non-destructive read operation, but diffusion at the oxide/silicon interface poses reliability issues for the device [12,[24][25][26]. Compared to FeRAM and FeFET, FTJ, as a twoterminal device with a simple structure and ultrathin ferroelectric layers, benefits from device miniaturization [27][28][29][30][31].…”

Section: Introductionmentioning

confidence: 99%

Ferroelectric tunnel junctions: promise, achievements and challenges

Park,

Lee,

Park

et al. 2024

J. Phys. D: Appl. Phys.

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Ferroelectric tunnel junctions (FTJs) have been the subject of ongoing research interest due to its fast operation based on the spontaneous polarization direction of ultrathin ferroelectrics and its simple two-terminal structure. Due to the advantages of FTJs, such as non-destructive readout, fast operation speed, low energy consumption, and high-density integration, they have recently been considered a promising candidate for non-volatile next-generation memory. These characteristics are essential to meet the increasing demand for high-performance memory in modern computing systems. In this review, we explore the basic principles and structures of FTJs and clarify the elements necessary for the successful fabrication and operation of FTJs. Then, we focus on the recent progress in perovskite oxide, fluorite, 2-dimensional van der Waals, and polymer-based FTJs and discuss ferroelectric materials expected to be available for FTJs use in the future. We highlight various functional device applications, including non-volatile memories, crossbar arrays, and synapses, utilizing the advantageous properties of ferroelectrics. Lastly, we address the challenges that FTJ devices currently face and propose a direction for moving forward.

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Physics, Structures, and Applications of Fluorite‐Structured Ferroelectric Tunnel Junctions

Cited by 7 publications

References 126 publications

Recent advancements and progress in development in chalcogenide (S, Se)-based thin films for high-performance photodetectors: a review

Recent advancements and progress in development in chalcogenide (S, Se)-based thin films for high-performance photodetectors: a review

Monolithically Integrated Complementary Ferroelectric FET XNOR Synapse for the Binary Neural Network

Ferroelectric tunnel junctions: promise, achievements and challenges

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