Low‐Power Nonvolatile Charge Storage Memory Based on MoS<sub>2</sub> and an Ultrathin Polymer Tunneling Dielectric

Woo, Myung Hoon; Jang, Byung Chul; Choi, Junhwan; Lee, Khang June; Shin, Gwang Hyuk; Seong, Hyejeong; Im, Sung Gap; Choi, Sung‐Yool

doi:10.1002/adfm.201703545

Cited by 43 publications

(51 citation statements)

References 34 publications

(45 reference statements)

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“…We find a very low cycle to cycle variability in the memory ratio, defined as the ratio of the on and off state current, demonstrating the reliability of these non-volatile memory devices (inset of figure 3(d)). Furthermore, the memory ratio in our devices, which can be as high as 10 8 , is comparable to state of the art sensors fabricated with two-dimensional materials, that have reported in literature (Supplementary section C.2) [52][53][54][55][56][57][58][59]. Additionally, the low bias requirements and program state current value makes the device power efficient with an observed power dissipation of ≈10pW in the program state in our MoS 2 based memory devices [51].…”

supporting

confidence: 73%

A generic method to control hysteresis and memory effect in Van der Waals hybrids

Ahmed¹,

Islam²,

Paul³

et al. 2020

Mater. Res. Express

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The diverse properties of two-dimensional materials have been utilized in a variety of architecture to fabricate high quality electronic circuit elements. Here we demonstrate a generic method to control hysteresis and stable memory effect in Van der Waals hybrids with a floating gate as the base layer. The floating gate can be charged with a global back gate-voltage, which it can retain in a stable manner. Such devices can provide a very high, leakage-free effective gate-voltage on the field-effect transistors due to effective capacitance amplification, which also leads to reduced input power requirements on electronic devices. The capacitance amplification factor of ∼10 can be further enhanced by increasing the area of the floating gate. We have exploited this method to achieve highly durable memory action multiple genre of ultra-thin 2D channels, including graphene, MoS 2 , and topological insulators at room temperature.

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supporting

confidence: 73%

A generic method to control hysteresis and memory effect in Van der Waals hybrids

Ahmed¹,

Islam²,

Paul³

et al. 2020

Mater. Res. Express

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“…The group of S.‐Y. Choi developed a low‐power flash‐memory cell consisting of a few‐layer MoS 2 channel, a polymer tunneling layer, namely a ≈10 nm thick film of poly(1,3,5‐trimethyl‐1,3,5‐trivinyl cyclotrisiloxane) (pV3D3) formed via a solvent‐free initiated chemical vapor deposition (iCVD) process, as well as an Al 2 O 3 blocking oxide (≈20 nm) deposited by ALD onto a Au‐nanoparticle charge‐storage layer (≈4 nm). The memory cells displayed promising characteristics, namely endurance >10 3 cycles, state‐of‐the‐art retention time (>10 years) and high switching ratio ( I on / I off ≈ 10 6 ), being the highest obtained so far in GRM‐based flash devices (see Table ).…”

Section: Flash Memories Based On Grmsmentioning

confidence: 99%

Nonvolatile Memories Based on Graphene and Related 2D Materials

et al. 2019

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The pervasiveness of information technologies is generating an impressive amount of data, which need to be accessed very quickly. Nonvolatile memories (NVMs) are making inroads into high‐capacity storage to replace hard disk drives, fuelling the expansion of the global storage memory market. As silicon‐based flash memories are approaching their fundamental limit, vertical stacking of multiple memory cell layers, innovative device concepts, and novel materials are being investigated. In this context, emerging 2D materials, such as graphene, transition metal dichalcogenides, and black phosphorous, offer a host of physical and chemical properties, which could both improve existing memory technologies and enable the next generation of low‐cost, flexible, and wearable storage devices. Herein, an overview of graphene and related 2D materials (GRMs) in different types of NVM cells is provided, including resistive random‐access, flash, magnetic and phase‐change memories. The physical and chemical mechanisms underlying the switching of GRM‐based memory devices studied in the last decade are discussed. Although at this stage most of the proof‐of‐concept devices investigated do not compete with state‐of‐the‐art devices, a number of promising technological advancements have emerged. Here, the most relevant material properties and device structures are analyzed, emphasizing opportunities and challenges toward the realization of practical NVM devices.

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“…Due to enhanced electrostatic control and inter-layer van der Waals bonding, these materials could offer high-performing, flexible and transparent alternatives to silicon-based memory components [2][3][4][5][6][7][8][9]. On-chip MoS 2 -based vertical memory cells [10][11][12][13][14][15][16][17][18] and printed lateral devices with synaptic functionalities [19] have been prototyped in recent years.…”

mentioning

confidence: 99%

MoS₂ Memtransistors Fabricated by Localized Helium Ion Beam Irradiation

et al. 2019

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Two-dimensional layered semiconductors have recently emerged as attractive building blocks for next-generation low-power non-volatile memories. However, Hongzhou Zhang: hozhang@tcd.ie 1 arXiv:1811.09545v1 [cond-mat.mtrl-sci] 23 Nov 2018 † J.J. and D.K. contributed equally to this project. D.K. performed electrical measurements on samples of different layer thickness and irradiation dose, as well as atomic force microscopy and scanning electron microscopy. CVD growth of MoS 2 monolayers was carried out by C.P.C. Mechanically-exfoliated devices were prepared by J.J. and D.K. Raman and PL spectroscopy was carried out by C.P.C. and analysed by P.M.. J.J and D.K. carried out EBL to fabricate the FET devices. H.S. assisted with fabrication and wirebonding of devices tested in Peking University (PKU). D.K., J.J. and P.M. carried out the HIM irradiations in Trinity College Dublin (TCD) while J.J and Y.Z. conducted the HIM exposures in PKU. J.J carried out the electrical tests (endurance and potentiation) with assistance from H.S and Y.Z in PKU. P.M. performed FIB processing of irradiated devices and carried out TEM of the cross-sectioned lamellae with assistance from C.D.. D.S.F. carried out helium exposures and TEM imaging of the plan-view irradiated devices after J.J. transferred the samples onto TEM grids. Z.L. oversaw the electrical characterisation work in PKU, while R.Z. and J.X. facilitated microscopy experiments in PKU. N.M and G.S.D. oversaw the material growth process and spectroscopic experiments in TCD. J.J.B. and H.Z. conceived the study and supervised the project. The manuscript was written by J.J., D.K. and P.M. All authors agreed with the final version of the paper.

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Low‐Power Nonvolatile Charge Storage Memory Based on MoS₂ and an Ultrathin Polymer Tunneling Dielectric

Cited by 43 publications

References 34 publications

A generic method to control hysteresis and memory effect in Van der Waals hybrids

A generic method to control hysteresis and memory effect in Van der Waals hybrids

Nonvolatile Memories Based on Graphene and Related 2D Materials

MoS₂ Memtransistors Fabricated by Localized Helium Ion Beam Irradiation

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Low‐Power Nonvolatile Charge Storage Memory Based on MoS2 and an Ultrathin Polymer Tunneling Dielectric

Cited by 43 publications

References 34 publications

A generic method to control hysteresis and memory effect in Van der Waals hybrids

A generic method to control hysteresis and memory effect in Van der Waals hybrids

Nonvolatile Memories Based on Graphene and Related 2D Materials

MoS2 Memtransistors Fabricated by Localized Helium Ion Beam Irradiation

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Product

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Low‐Power Nonvolatile Charge Storage Memory Based on MoS₂ and an Ultrathin Polymer Tunneling Dielectric

MoS₂ Memtransistors Fabricated by Localized Helium Ion Beam Irradiation