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1. Universal Non-Volatile Resistive Switching Behavior in 2D Metal Dichalcogenides Featuring Unique Conductive-Point Random Access Memory Effect

Author

Wu, Xiaohan, Ge, Ruijing, Gu, Yuqian, Okogbue, Emmanuel, Shi, Jianping, Shivayogimath, Abhay, Bøggild, Peter, Booth, Timothy J., Zhang, Yanfeng, Jung, Yeonwoong, Lee, Jack C., and Akinwande, Deji

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Two-dimensional materials have been discovered to exhibit non-volatile resistive switching (NVRS) phenomenon. In our work, we reported the universal NVRS behavior in a dozen metal dichalcogenides, featuring low switching voltage, large on/off ratio, fast switching speed and forming free characteristics. A unique conductive-point random access memory (CPRAM) effect is used to explain the switching mechanisms, supported by experimental results from current-sweep measurements., Comment: 3 pages, 5 figures, IEEE conference(2021 5th EDTM)

Published
2021
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2. Single-defect Memristor in MoS$_2$ Atomic-layer

Author

Hus, Saban M., Ge, Ruijing, Chen, Po-An, Chiang, Meng-Hsueh, Donnelly, Gavin E., Ko, Wonhee, Huang, Fumin, Liang, Liangbo, Li, An-Ping, and Akinwande, Deji

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Non-volatile resistive switching, also known as memristor effect in two terminal devices, has emerged as one of the most important components in the ongoing development of high-density information storage, brain-inspired computing, and reconfigurable systems. Recently, the unexpected discovery of memristor effect in atomic monolayers of transitional metal dichalcogenide sandwich structures has added a new dimension of interest owing to the prospects of size scaling and the associated benefits. However, the origin of the switching mechanism in atomic sheets remains uncertain. Here, using monolayer MoS$_2$ as a model system, atomistic imaging and spectroscopy reveal that metal substitution into sulfur vacancy results in a non-volatile change in resistance. The experimental observations are corroborated by computational studies of defect structures and electronic states. These remarkable findings provide an atomistic understanding on the non-volatile switching mechanism and open a new direction in precision defect engineering, down to a single defect, for achieving optimum performance metrics including memory density, switching energy, speed, and reliability using atomic nanomaterials.

Published
2020

4. Towards Universal Non-Volatile Resistance Switching in Non-metallic Monolayer Atomic Sheets

Author

Ge, Ruijing, Wu, Xiaohan, Kim, Myungsoo, Chou, Harry, Sonde, Sushant, Tao, Li, Lee, Jack C., and Akinwande, Deji

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Here, we report the intriguing observation of stable non-volatile resistance switching (NVRS) in single-layer atomic sheets sandwiched between metal electrodes. NVRS is observed in the prototypical semiconducting (MX2, M=Mo, W; and X=S, Se) transitional metal dichalcogenides (TMDs), and insulating hexagonal boron nitride (h-BN), which alludes to the universality of this phenomenon in non-metallic 2D monolayers, and features forming-free switching. This observation of NVRS phenomenon, widely attributed to ionic diffusion, filament and interfacial redox in bulk oxides and electrolytes, inspires new studies on defects, ion transport and energetics at the sharp interfaces between atomically-thin sheets and conducting electrodes. From a contemporary perspective, switching is all the more unexpected in monolayers since leakage current is a fundamental limit in ultra-thin oxides. Emerging device concepts in non-volatile flexible memory fabrics, and brain-inspired (neuromorphic) computing could benefit substantially from the pervasive NVRS effect and the associated wide materials and engineering co-design opportunity. Experimentally, a 50 GHz radio-frequency (RF) monolayer switch is demonstrated, which opens up a new application for electronic zero-static power RF switching technology.

Published
2017

10. List of contributors

Author

Akinwande, Deji, primary, Chen, Jian, additional, Chen, Lin, additional, Chen, Pai-Yen, additional, Ding, Mengning, additional, Farhat, Mohamed, additional, Gao, Na, additional, Ge, Ruijing, additional, Grazianetti, Carlo, additional, Hsu, Hsien-Yi, additional, Huang, Kai, additional, Ji, Li, additional, Jiang, Siyao, additional, Kabiri Ameri, Shideh, additional, Kang, Dingxuan, additional, Kim, Myungsoo, additional, Lee, Jack C., additional, Liang, Xiaogan, additional, Lin, Linhan, additional, Liu, Anhan, additional, Liu, Congyue, additional, Martella, Christian, additional, Molle, Alessandro, additional, Salama, Khaled Nabil, additional, Sun, Qingqing, additional, Sun, Zhengming, additional, Tao, Li, additional, Tian, Bailin, additional, Wang, Liu, additional, Wang, Zengmei, additional, Wu, Xiaohan, additional, Wu, Zilong, additional, Xu, Hui, additional, Zhang, David Wei, additional, Zhang, Sixin, additional, Zheng, Yuebing, additional, Zhou, Peng, additional, Zhu, Hao, additional, Zhu, Liang, additional, Zhu, Ruijian, additional, Zhu, Zhengrui, additional, and Zou, Xingli, additional

Published
2020
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13. Wafer-Scalable Single-Layer Amorphous Molybdenum Trioxide

Author

Alam, Md Hasibul, primary, Chowdhury, Sayema, additional, Roy, Anupam, additional, Wu, Xiaohan, additional, Ge, Ruijing, additional, Rodder, Michael A., additional, Chen, Jun, additional, Lu, Yang, additional, Stern, Chen, additional, Houben, Lothar, additional, Chrostowski, Robert, additional, Burlison, Scott R., additional, Yang, Sung Jin, additional, Serna, Martha I., additional, Dodabalapur, Ananth, additional, Mangolini, Filippo, additional, Naveh, Doron, additional, Lee, Jack C., additional, Banerjee, Sanjay K., additional, Warner, Jamie H., additional, and Akinwande, Deji, additional

Published
2022
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17. Universal Non-Volatile Resistive Switching Behavior in 2D Metal Dichalcogenides Featuring Unique Conductive-Point Random Access Memory Effect

Author

Wu, Xiaohan, primary, Ge, Ruijing, additional, Gu, Yuqian, additional, Okogbue, Emmanuel, additional, Shi, Jianping, additional, Shivayogimath, Abhay, additional, Boggild, Peter, additional, Booth, Timothy J., additional, Zhang, Yanfeng, additional, Jung, Yeonwoong, additional, Lee, Jack C., additional, and Akinwande, Deji, additional

Published
2021
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18. A Library of Atomically Thin 2D Materials Featuring the Conductive‐Point Resistive Switching Phenomenon

Author

Ge, Ruijing, primary, Wu, Xiaohan, additional, Liang, Liangbo, additional, Hus, Saban M., additional, Gu, Yuqian, additional, Okogbue, Emmanuel, additional, Chou, Harry, additional, Shi, Jianping, additional, Zhang, Yanfeng, additional, Banerjee, Sanjay K., additional, Jung, Yeonwoong, additional, Lee, Jack C., additional, and Akinwande, Deji, additional

Published
2020
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19. Electron irradiation-induced defects for reliability improvement in monolayer MoS2-based conductive-point memory devices.

Author

Wu, Xiaohan, Gu, Yuqian, Ge, Ruijing, Serna, Martha I., Huang, Yifu, Lee, Jack C., and Akinwande, Deji

Subjects
COMPUTER storage devices, METAL-insulator-metal structures, X-ray photoelectron spectroscopy, MONTE Carlo method, MONOMOLECULAR films, SKYRMIONS, MEMRISTORS
Abstract

Monolayer molybdenum disulfide has been previously discovered to exhibit non-volatile resistive switching behavior in a vertical metal-insulator-metal structure, featuring ultra-thin sub-nanometer active layer thickness. However, the reliability of these nascent 2D-based memory devices was not previously investigated for practical applications. Here, we employ an electron irradiation treatment on monolayer MoS2 film to modify the defect properties. Raman, photoluminescence, and X-ray photoelectron spectroscopy measurements have been performed to confirm the increasing amount of sulfur vacancies introduced by the e-beam irradiation process. The statistical electrical studies reveal the reliability can be improved by up to 1.5× for yield and 11× for average DC cycling endurance in the devices with a moderate radiation dose compared to unirradiated devices. Based on our previously proposed virtual conductive-point model with the metal ion substitution into sulfur vacancy, Monte Carlo simulations have been performed to illustrate the irradiation effect on device reliability, elucidating a clustering failure mechanism. This work provides an approach by electron irradiation to enhance the reliability of 2D memory devices and inspires further research in defect engineering to precisely control the switching properties for a wide range of applications from memory computing to radio-frequency switches. [ABSTRACT FROM AUTHOR]

Published
2022
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29. Thinnest Nonvolatile Memory Based on Monolayer h‐BN

Author

Wu, Xiaohan, primary, Ge, Ruijing, additional, Chen, Po‐An, additional, Chou, Harry, additional, Zhang, Zhepeng, additional, Zhang, Yanfeng, additional, Banerjee, Sanjay, additional, Chiang, Meng‐Hsueh, additional, Lee, Jack C., additional, and Akinwande, Deji, additional

Published
2019
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32. Understanding of multiple resistance states by current sweeping in MoS2-based non-volatile memory devices.

Author

Wu, Xiaohan, Ge, Ruijing, Akinwande, Deji, and Lee, Jack C

Subjects
*COMPUTER storage devices, *BORON nitride, *RANDOM access memory, *TRANSITION metals, *MONOMOLECULAR films, *NANOSTRUCTURED materials
Abstract

Recently, various two-dimensional materials have been reported to exhibit non-volatile resistance switching phenomenon. The atomristors, featuring memristor effect in atomically thin nanomaterials such as monolayer transition metal dichalcogenides and hexagonal boron nitride, have drawn much attention due to the extremely thin active layer thickness with the advantages of forming-free characteristic, large on/off resistance ratio and fast switching speed. To investigate the switching mechanisms in the 2D monolayers, we introduced an electrical characterization method by current sweeping to illustrate the detailed information hidden in the commonly used voltage-sweep curves. Multiple transition steps have been observed in the SET process of MoS2-based resistance switching devices. The different behaviors of transition steps were attributed to the number of defects or vacancies associated with the switching phenomenon, which is consistent with the previously reported conductive-bridge-like model for 2D atomristors. This work provides an approach using current sweeping to precisely characterize the resistance switching effect and inspires further research to optimize the defect distribution in 2D materials for the applications in multi-bit non-volatile memory and neuromorphic computing. [ABSTRACT FROM AUTHOR]

Published
2020
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34. Recommended Methods to Study Resistive Switching Devices

Author

Lanza, Mario, primary, Wong, H.-S. Philip, additional, Pop, Eric, additional, Ielmini, Daniele, additional, Strukov, Dimitri, additional, Regan, Brian C., additional, Larcher, Luca, additional, Villena, Marco A., additional, Yang, J. Joshua, additional, Goux, Ludovic, additional, Belmonte, Attilio, additional, Yang, Yuchao, additional, Puglisi, Francesco M., additional, Kang, Jinfeng, additional, Magyari-Köpe, Blanka, additional, Yalon, Eilam, additional, Kenyon, Anthony, additional, Buckwell, Mark, additional, Mehonic, Adnan, additional, Shluger, Alexander, additional, Li, Haitong, additional, Hou, Tuo-Hung, additional, Hudec, Boris, additional, Akinwande, Deji, additional, Ge, Ruijing, additional, Ambrogio, Stefano, additional, Roldan, Juan B., additional, Miranda, Enrique, additional, Suñe, Jordi, additional, Pey, Kin Leong, additional, Wu, Xing, additional, Raghavan, Nagarajan, additional, Wu, Ernest, additional, Lu, Wei D., additional, Navarro, Gabriele, additional, Zhang, Weidong, additional, Wu, Huaqiang, additional, Li, Runwei, additional, Holleitner, Alexander, additional, Wurstbauer, Ursula, additional, Lemme, Max C., additional, Liu, Ming, additional, Long, Shibing, additional, Liu, Qi, additional, Lv, Hangbing, additional, Padovani, Andrea, additional, Pavan, Paolo, additional, Valov, Ilia, additional, Jing, Xu, additional, Han, Tingting, additional, Zhu, Kaichen, additional, Chen, Shaochuan, additional, Hui, Fei, additional, and Shi, Yuanyuan, additional

Published
2018
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37. Observation of single-defect memristor in an MoS2atomic sheet

Author

Hus, Saban M., Ge, Ruijing, Chen, Po-An, Liang, Liangbo, Donnelly, Gavin E., Ko, Wonhee, Huang, Fumin, Chiang, Meng-Hsueh, Li, An-Ping, and Akinwande, Deji

Abstract

Non-volatile resistive switching, also known as memristor1effect, where an electric field switches the resistance states of a two-terminal device, has emerged as an important concept in the development of high-density information storage, computing and reconfigurable systems2–9. The past decade has witnessed substantial advances in non-volatile resistive switching materials such as metal oxides and solid electrolytes. It was long believed that leakage currents would prevent the observation of this phenomenon for nanometre-thin insulating layers. However, the recent discovery of non-volatile resistive switching in two-dimensional monolayers of transition metal dichalcogenide10,11and hexagonal boron nitride12sandwich structures (also known as atomristors) has refuted this belief and added a new materials dimension owing to the benefits of size scaling10,13. Here we elucidate the origin of the switching mechanism in atomic sheets using monolayer MoS2as a model system. Atomistic imaging and spectroscopy reveal that metal substitution into a sulfur vacancy results in a non-volatile change in the resistance, which is corroborated by computational studies of defect structures and electronic states. These findings provide an atomistic understanding of non-volatile switching and open a new direction in precision defect engineering, down to a single defect, towards achieving the smallest memristor for applications in ultra-dense memory, neuromorphic computing and radio-frequency communication systems2,3,11.

Published
2021
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39. Memory effect in two dimensional atomically-thin sheets

Author

Ge, Ruijing

Subjects
Non-volatile resistive switching, Two-dimensional material
Abstract

Two-dimensional (2D) materials have attracted much attention over the last decade in nanoelectronics due to their remarkable electronic, optical, mechanical, and thermal properties. In this dissertation, we report intriguing observation of stable non-volatile resistive switching (NVRS) in single layer 2D atomic sheets sandwiched between metal electrodes. These devices can be collectively labeled atomristor, in essence, memristor effect in atomically-thin nanomaterials or atomic sheets. The systematic investigation for 2D-based-NVRS is conducted in terms of performance, materials, mechanisms, and applications and presented in separate chapters. Chapter 1 is an introduction to 2D materials and non-volatile memories. In Chapter 2, molybdenum disulfide (MoS₂) based atomristor is demonstrated showing large on/off ratio, forming-free characteristic and small switching voltages. In chapter 3, we further expand the collection of 2D materials showing NVRS, including transition metal dichalcogenides (MX₂, M=transition metal atom, e.g. Mo, W, Re, Sn or Pt; X=chalcogen atom, e.g. S, Se or Te), a heterostructure (WS₂/MoS₂) and an insulator (h-BN), indicating the universality of the phenomenon in various 2D atomic sheets. Then a possible mechanism dissociation-diffusion-adsorption (DDA) model is presented in Chapter 4, supported by both first-principle calculation results and scanning tunneling microscope (STM) atomistic imaging. In chapter 5, emerging device concepts in non-volatile flexible memory and zero-static power radio frequency (RF) switches are demonstrated, which could benefit substantially from the wide 2D materials design space. Our findings overturn the contemporary thinking that non-volatile switching is not scalable to sub nanometer and thus motivate further research in defect engineering, interface modification and ionic diffusion, which is discussed in the last Chapter 6

Published
2020

40. Memristors Based on 2D Monolayer Materials

Author

Wu, Xiaohan, Lee, Jack C., Akinwande, Deji, and Ge, Ruijing

Subjects
Technology & Engineering
Abstract

2D materials have been widely used in various applications due to their remarkable and distinct electronic, optical, mechanical and thermal properties. Memristive effect has been found in several 2D systems. This chapter focuses on the memristors based on 2D materials, e. g. monolayer transition metal dichalcogenides (TMDs) and hexagonal boron nitride (h-BN), as the active layer in vertical MIM (metal–insulator–metal) configuration. Resistive switching behavior under normal DC and pulse waveforms, and current-sweep and constant stress testing methods have been investigated. Unlike the filament model in conventional bulk oxide-based memristors, a new switching mechanism has been proposed with the assistance of metal ion diffusion, featuring conductive-point random access memory (CPRAM) characteristics. The use of 2D material devices in applications such as flexible non-volatile memory (NVM) and emerging zero-power radio frequency (RF) switch will be discussed.

Published
2022

41. Resistance state evolution under constant electric stress on a MoS 2 non-volatile resistive switching device.

Author

Wu X, Ge R, Huang Y, Akinwande D, and Lee JC

Abstract

MoS 2 has been reported to exhibit a resistive switching phenomenon in a vertical metal-insulator-metal (MIM) structure and has attracted much attention due to its ultra-thin active layer thickness. Here, the resistance evolutions in the high resistance state (HRS) and low resistance state (LRS) are investigated under constant voltage stress (CVS) or constant current stress (CCS) on MoS 2 resistive switching devices. Interestingly, compared with bulk transition metal oxides (TMO), MoS 2 exhibits an opposite characteristic in the fresh or pre-RESET device in the "HRS" wherein the resistance will increase to an even higher resistance after applying CVS, a unique phenomenon only accessible in 2D-based resistive switching devices. It is inferred that instead of in the highest resistance state, the fresh or pre-RESET devices are in an intermediate state with a small amount of Au embedded in the MoS 2 film. Inspired by the capability of both bipolar and unipolar operation, positive and negative CVS measurements are performed and show similar characteristics. In addition, it is observed that the resistance state transition is faster when using higher electric stress. Numerical simulations have been performed to study the temperature effect with small-area integration capability. These results can be explained by a modified conductive-bridge-like model based on Au migration, uncovering the switching mechanisms in the ultrathin 2D materials and inspiring future studies in this area., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published
2020
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42. Understanding of multiple resistance states by current sweeping in MoS 2 -based non-volatile memory devices.

Author

Wu X, Ge R, Akinwande D, and Lee JC

Abstract

Recently, various two-dimensional materials have been reported to exhibit non-volatile resistance switching phenomenon. The atomristors, featuring memristor effect in atomically thin nanomaterials such as monolayer transition metal dichalcogenides and hexagonal boron nitride, have drawn much attention due to the extremely thin active layer thickness with the advantages of forming-free characteristic, large on/off resistance ratio and fast switching speed. To investigate the switching mechanisms in the 2D monolayers, we introduced an electrical characterization method by current sweeping to illustrate the detailed information hidden in the commonly used voltage-sweep curves. Multiple transition steps have been observed in the SET process of MoS 2 -based resistance switching devices. The different behaviors of transition steps were attributed to the number of defects or vacancies associated with the switching phenomenon, which is consistent with the previously reported conductive-bridge-like model for 2D atomristors. This work provides an approach using current sweeping to precisely characterize the resistance switching effect and inspires further research to optimize the defect distribution in 2D materials for the applications in multi-bit non-volatile memory and neuromorphic computing.

Published
2020
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43. Zero-static power radio-frequency switches based on MoS 2 atomristors.

Author

Kim M, Ge R, Wu X, Lan X, Tice J, Lee JC, and Akinwande D

Abstract

Recently, non-volatile resistance switching or memristor (equivalently, atomristor in atomic layers) effect was discovered in transitional metal dichalcogenides (TMD) vertical devices. Owing to the monolayer-thin transport and high crystalline quality, ON-state resistances below 10 Ω are achievable, making MoS 2 atomristors suitable as energy-efficient radio-frequency (RF) switches. MoS 2 RF switches afford zero-hold voltage, hence, zero-static power dissipation, overcoming the limitation of transistor and mechanical switches. Furthermore, MoS 2 switches are fully electronic and can be integrated on arbitrary substrates unlike phase-change RF switches. High-frequency results reveal that a key figure of merit, the cutoff frequency (f c ), is about 10 THz for sub-μm 2 switches with favorable scaling that can afford f c above 100 THz for nanoscale devices, exceeding the performance of contemporary switches that suffer from an area-invariant scaling. These results indicate a new electronic application of TMDs as non-volatile switches for communication platforms, including mobile systems, low-power internet-of-things, and THz beam steering.

Published
2018
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44. Atomristor: Nonvolatile Resistance Switching in Atomic Sheets of Transition Metal Dichalcogenides.

Author

Ge R, Wu X, Kim M, Shi J, Sonde S, Tao L, Zhang Y, Lee JC, and Akinwande D

Abstract

Recently, two-dimensional (2D) atomic sheets have inspired new ideas in nanoscience including topologically protected charge transport,1,2 spatially separated excitons,3 and strongly anisotropic heat transport.4 Here, we report the intriguing observation of stable nonvolatile resistance switching (NVRS) in single-layer atomic sheets sandwiched between metal electrodes. NVRS is observed in the prototypical semiconducting (MX 2 , M = Mo, W; and X = S, Se) transitional metal dichalcogenides (TMDs),5 which alludes to the universality of this phenomenon in TMD monolayers and offers forming-free switching. This observation of NVRS phenomenon, widely attributed to ionic diffusion, filament, and interfacial redox in bulk oxides and electrolytes,6-9 inspires new studies on defects, ion transport, and energetics at the sharp interfaces between atomically thin sheets and conducting electrodes. Our findings overturn the contemporary thinking that nonvolatile switching is not scalable to subnanometre owing to leakage currents.10 Emerging device concepts in nonvolatile flexible memory fabrics, and brain-inspired (neuromorphic) computing could benefit substantially from the wide 2D materials design space. A new major application, zero-static power radio frequency (RF) switching, is demonstrated with a monolayer switch operating to 50 GHz.

Published
2018
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