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1. Selective and Quasi-continuous Switching of Ferroelectric Chern Insulator Device for Neuromorphic Computing

Author

Chen, Moyu, Xie, Yongqin, Cheng, Bin, Yang, Zaizheng, Li, Xin-Zhi, Chen, Fanqiang, Li, Qiao, Xie, Jiao, Watanabe, Kenji, Taniguchi, Takashi, He, Wen-Yu, Wu, Menghao, Liang, Shi-Jun, and Miao, Feng

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Topologically protected edge state transport in quantum materials is dissipationless and features quantized Hall conductance, and shows great potential in highly fault-tolerant computing technologies. However, it remains elusive about how to develop topological edge state-based computing devices. Recently, exploration and understanding of interfacial ferroelectricity in various van der Waals heterostructure material systems have received widespread attention among the community of materials science and condensed matter physics3-11. Such ferroelectric polarization emergent at the vdW interface can coexist with other quantum states and thus provides an unprecedented opportunity to electrically switch the topological edge states of interest, which is of crucial significance to the fault-tolerant electronic device applications based on the topological edge states. Here, we report the selective and quasi-continuous ferroelectric switching of topological Chern insulator devices and demonstrate its promising application in noise-immune neuromorphic computing. We fabricate this ferroelectric Chern insulator device by encapsulating magic-angle twisted bilayer graphene with doubly-aligned h-BN layers, and observe the coexistence of the interfacial ferroelectricity and the topological Chern insulating states. This ferroelectricity exhibits an anisotropic dependence on the in-plane magnetic field. By using a VBG pulse with delicately controlled amplitude, we realize the nonvolatile switching between any pair of Chern insulating states and achieve 1280 distinguishable nonvolatile resistance levels on a single device. Furthermore, we demonstrate deterministic switching between two arbitrary levels among the record-high number of nonvolatile resistance levels.

Published
2024
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2. Electrical switching of Ising-superconducting nonreciprocity for quantum neuronal transistor

Author

Xiong, Junlin, Xie, Jiao, Cheng, Bin, Dai, Yudi, Cui, Xinyu, Wang, Lizheng, Liu, Zenglin, Zhou, Ji, Wang, Naizhou, Xu, Xianghan, Chen, Xianhui, Cheong, Sang-Wook, Liang, Shi-Jun, and Miao, Feng

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Nonreciprocal quantum transport effect is mainly governed by the symmetry breaking of the material systems and is gaining extensive attention in condensed matter physics. Realizing electrical switching of the polarity of the nonreciprocal transport without external magnetic field is essential to the development of nonreciprocal quantum devices. However, electrical switching of superconducting nonreciprocity remains yet to be achieved. Here, we report the observation of field-free electrical switching of nonreciprocal Ising superconductivity in Fe3GeTe2/NbSe2 van der Waals (vdW) heterostructure. By taking advantage of this electrically switchable superconducting nonreciprocity, we demonstrate a proof-of-concept nonreciprocal quantum neuronal transistor, which allows for implementing the XOR logic gate and faithfully emulating biological functionality of a cortical neuron in the brain. Our work provides a promising pathway to realize field-free and electrically switchable nonreciprocity of quantum transport and demonstrate its potential in exploring neuromorphic quantum devices with both functionality and performance beyond the traditional devices.

Published
2024
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3. Interfacial magnetic spin Hall effect in van der Waals Fe3GeTe2/MoTe2 heterostructure

Author

Dai, Yudi, Xiong, Junlin, Ge, Yanfeng, Cheng, Bin, Wang, Lizheng, Wang, Pengfei, Liu, Zenglin, Yan, Shengnan, Zhang, Cuiwei, Xu, Xianghan, Shi, Youguo, Cheong, Sang-Wook, Xiao, Cong, Yang, Shengyuan A., Liang, Shi-Jun, and Miao, Feng

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The spin Hall effect (SHE) allows efficient generation of spin polarization or spin current through charge current and plays a crucial role in the development of spintronics. While SHE typically occurs in non-magnetic materials and is time-reversal even, exploring time-reversal-odd (T-odd) SHE, which couples SHE to magnetization in ferromagnetic materials, offers a new charge-spin conversion mechanism with new functionalities. Here, we report the observation of giant T-odd SHE in Fe3GeTe2/MoTe2 van der Waals heterostructure, representing a previously unidentified interfacial magnetic spin Hall effect (interfacial-MSHE). Through rigorous symmetry analysis and theoretical calculations, we attribute the interfacial-MSHE to a symmetry-breaking induced spin current dipole at the vdW interface. Furthermore, we show that this linear effect can be used for implementing multiply-accumulate operations and binary convolutional neural networks with cascaded multi-terminal devices. Our findings uncover an interfacial T-odd charge-spin conversion mechanism with promising potential for energy-efficient in-memory computing.

Published
2024
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4. On-device phase engineering

Author

Liu, Xiaowei, Shan, Junjie, Cao, Tianjun, Zhu, Liang, Ma, Jiayu, Wang, Gang, Shi, Zude, Yang, Qishuo, Ma, Mingyu, Liu, Zenglin, Yan, Shengnan, Wang, Lizheng, Dai, Yudi, Xiong, Junlin, Chen, Fanqiang, Wang, Buwei, Pan, Chen, Wang, Zhenlin, Cheng, Bin, He, Yongmin, Luo, Xin, Lin, Junhao, Liang, Shi-Jun, and Miao, Feng

Published
2024
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5. Moire synaptic transistor for homogeneous-architecture reservoir computing

Author

Wang, Pengfei, Chen, Moyu, Xie, Yongqin, Pan, Chen, Watanabe, Kenji, Taniguchi, Takashi, Cheng, Bin, Liang, Shi-Jun, and Miao, Feng

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Reservoir computing has been considered as a promising intelligent computing paradigm for effectively processing complex temporal information. Exploiting tunable and reproducible dynamics in the single electronic device have been desired to implement the reservoir and the readout layer of reservoir computing system. Two-dimensional moire material, with an artificial lattice constant many times larger than the atomic length scale, is one type of most studied artificial quantum materials in community of material science and condensed-matter physics over the past years. These materials are featured with gate-tunable periodic potential and electronic correlation, thus varying the electric field allows the electrons in the moire potential per unit cell to exhibit distinct and reproducible dynamics, showing great promise in robust reservoir computing. Here, we report that a moire synaptic transistor can be used to implement the reservoir computing system with a homogeneous reservoir-readout architecture. The synaptic transistor is fabricated based on a h-BN/bilayer graphene/h-BN moire heterostructure, exhibiting ferroelectricity-like hysteretic gate voltage dependence of resistance. Varying the magnitude of the gate voltage enables the moire transistor to be switched between long-term memory and short-term memory with nonlinear dynamics. By employing the short- and long-term memory as the reservoir nodes and weights of the readout layer, respectively, we construct a full-moire physical neural network and demonstrate that the classification accuracy of 90.8% can be achieved for the MNIST handwritten digit database. Our work would pave the way towards the development of neuromorphic computing based on the moire materials.

Published
2023
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6. Parallel in-memory wireless computing

Author

Wang, Cong, Ruan, Gong-Jie, Yang, Zai-Zheng, Yangdong, Xing-Jian, Li, Yixiang, Wu, Liang, Ge, Yingmeng, Zhao, Yichen, Pan, Chen, Wei, Wei, Wang, Li-Bo, Cheng, Bin, Zhang, Zaichen, Zhang, Chuan, Liang, Shi-Jun, and Miao, Feng

Subjects
Computer Science - Hardware Architecture, Computer Science - Emerging Technologies, Electrical Engineering and Systems Science - Systems and Control, Physics - Applied Physics
Abstract

Parallel wireless digital communication with ultralow power consumption is critical for emerging edge technologies such as 5G and Internet of Things. However, the physical separation between digital computing units and analogue transmission units in traditional wireless technology leads to high power consumption. Here we report a parallel in-memory wireless computing scheme. The approach combines in-memory computing with wireless communication using memristive crossbar arrays. We show that the system can be used for the radio transmission of a binary stream of 480 bits with a bit error rate of 0. The in-memory wireless computing uses two orders of magnitude less power than conventional technology (based on digital-to-analogue and analogue-to-digital converters). We also show that the approach can be applied to acoustic and optical wireless communications

Published
2023
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8. Half-Valley Ohmic Contact and Contact-Limited Valley-Contrasting Current Injection

Author

Feng, Xukun, Lau, Chit Siong, Liang, Shi-Jun, Lee, Ching Hua, Yang, Shengyuan A., and Ang, Yee Sin

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

Two-dimensional (2D) ferrovalley semiconductor (FVSC) with spontaneous valley polarization offers an exciting material platform for probing Berry phase physics. How FVSC can be incorporated in valleytronic device applications, however, remain an open question. Here we generalize the concept of metal/semiconductor (MS) contact into the realm of valleytronics. We propose a half-valley Ohmic contact based on FVSC/graphene heterostructure where the two valleys of FVSC separately forms Ohmic and Schottky contacts with those of graphene, thus allowing current to be valley-selectively injected through the `Ohmic' valley while being blocked in the `Schottky' valley. We develop a theory of contact-limited valley-contrasting current injection and demonstrate that such transport mechanism can produce gate-tunable valley-polarized injection current. Using RuCl$_2$/graphene heterostructure as an example, we illustrate a device concept of valleytronic barristor where high valley polarization efficiency and sizable current on/off ratio, can be achieved under experimentally feasible electrostatic gating conditions. These findings uncover contact-limited valley-contrasting current injection as an efficient mechanism for valley polarization manipulation, and reveals the potential of valleytronic MS contact as a functional building block of valleytronic device technology., Comment: 9 pages, 5 figures

Published
2023

10. MA$_2$Z$_4$ Family Heteorstructures: Promises and Prospects

Author

Tho, Che Chen, Guo, San-Dong, Liang, Shi-Jun, Ong, Wee-Liat, Lau, Chit Siong, Cao, Liemao, Wang, Guangzhao, and Ang, Yee Sin

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

Recent experimental synthesis of ambient-stable MoSi2N4 monolayer have garnered enormous research interests. The intercalation morphology of MoSi2N4 - composed of a transition metal nitride (Mo-N) inner sub-monolayer sandwiched by two silicon nitride (Si-N) outer sub-monolayers - have motivated the computational discovery of an expansive family of synthetic MA2Z4 monolayers with no bulk (3D) material counterpart (where M = transition metals or alkaline earth metals; A = Si, Ge; and N = N, P, As). MA2Z4 monolayers exhibit interesting electronic, magnetic, optical, spintronic, valleytronic and topological properties, making them a compelling material platform for next-generation device technologies. Furthermore, heterostructure engineering enormously expands the opportunities of MA2Z4. In this review, we summarize the recent rapid progress in the computational design of MA2Z4-based heterostructures based on first-principle density functional theory (DFT) simulations - a central \emph{work horse} widely used to understand the physics, chemistry and general design rules for specific targeted functions. We systematically classify the MA2Z4-based heterostructures based on their contact types, and review their physical properties, with a focus on their performances in electronics, optoelectronics and energy conversion applications. We review the performance and promises of MA2Z4-based heterostructures for device applications that include electrical contacts, transistors, spintronic devices, photodetectors, solar cells, and photocatalytic water splitting. This review unveils the vast device application potential of MA2Z4-based heterostructures, and paves a roadmap for the future experimental and theoretical development of MA2Z4-based functional heterostructures and devices., Comment: 32 pages, 15 figures

Published
2023

12. Cascadable in-memory computing based on symmetric writing and read out

Author

Wang, Lizheng, Xiong, Junlin, Cheng, Bin, Dai, Yudi, Wang, Fuyi, Pan, Chen, Cao, Tianjun, Liu, Xiaowei, Wang, Pengfei, Chen, Moyu, Yan, Shengnan, Liu, Zenglin, Xiao, Jingjing, Xu, Xianghan, Wang, Zhenlin, Shi, Youguo, Cheong, Sang-Wook, Zhang, Haijun, Liang, Shi-Jun, and Miao, Feng

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The building block of in-memory computing with spintronic devices is mainly based on the magnetic tunnel junction with perpendicular interfacial anisotropy (p-MTJ). The resulting asymmetric write and read-out operations impose challenges in downscaling and direct cascadability of p-MTJ devices. Here, we propose that a new symmetric write and read-out mechanism can be realized in perpendicular-anisotropy spin-orbit (PASO) quantum materials based on Fe3GeTe2 and WTe2. We demonstrate that field-free and deterministic reversal of the perpendicular magnetization can be achieved by employing unconventional charge to z-spin conversion. The resulting magnetic state can be readily probed with its intrinsic inverse process, i.e., z-spin to charge conversion. Using the PASO quantum material as a fundamental building block, we implement the functionally complete set of logic-in-memory operations and a more complex nonvolatile half-adder logic function. Our work highlights the potential of PASO quantum materials for the development of scalable energy-efficient and ultrafast spintronic computing., Comment: Accepted by Science Advances

Published
2022

13. Approaching intrinsic threshold breakdown voltage and ultra-high gain in graphite/InSe Schottky photodetector

Author

Zhang, Zhiyi, Cheng, Bin, Lim, Jeremy, Gao, Anyuan, Lyu, Lingyuan, Cao, Tianju, Wang, Shuang, Li, Zhu-An, Wu, Qingyun, Ang, L. K., Ang, Yee Sin, Liang, Shi-Jun, and Miao, Feng

Subjects
Physics - Applied Physics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Realizing both ultra-low breakdown voltage and ultra-high gain has been one of the major challenges in the development of high-performance avalanche photodetector. Here, we report that an ultra-high avalanche gain of 3*10^5 can be realized in the graphite/InSe Schottky photodetector at a breakdown voltage down to 5.5 V. Remarkably, the threshold breakdown voltage can be further reduced down to 1.8 V by raising the operating temperature, approaching the theoretical limit of 1.5E_g/e with E_g the band gap of semiconductor. We develop a two-dimensional impact ionization model and uncover that observation of high gain at low breakdown voltage arises from reduced dimensionality of electron-phonon (e-ph) scattering in the layered InSe flake. Our findings open up a promising avenue for developing novel weak-light detectors with low energy consumption and high sensitivity.

Published
2022

14. Tunable quantum criticalities in an isospin extended Hubbard model simulator

Author

Li, Qiao, Cheng, Bin, Chen, Moyu, Xie, Bo, Xie, Yongqin, Wang, Pengfei, Chen, Fanqiang, Liu, Zenglin, Watanabe, Kenji, Taniguchi, Takashi, Liang, Shi-Jun, Wang, Da, Wang, Chenjie, Wang, Qiang-Hua, Liu, Jianpeng, and Miao, Feng

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Studying strong electron correlations has been an essential driving force for pushing the frontiers of condensed matter physics. In particular, in the vicinity of correlation-driven quantum phase transitions (QPTs), quantum critical fluctuations of multiple degrees of freedom facilitate exotic many-body states and quantum critical behaviors beyond Landau's framework. Recently, moir\'e heterostructures of van der Waals materials have been demonstrated as a highly tunable quantum platform for exploring fascinating strongly correlated quantum physics. Here, we report the observation of tunable quantum criticalities in an experimental simulator of extended Hubbard model with spin-valley isospins arising in chiral-stacked twisted double bilayer graphene. Scaling analysis shows a quantum two-stage criticality manifesting two distinct quantum critical points as the generalized Wigner crystal transits to a Fermi liquid by varying the displacement field, suggesting the emergence of a critical intermediate phase. The quantum two-stage criticality evolves into a quantum pseudo criticality as a high parallel magnetic field is applied. In such pseudo criticality, we find that the quantum critical scaling is only valid above a critical temperature, indicating a weak first-order QPT therein. Our results demonstrate a highly tunable solid-state simulator with intricate interplay of multiple degrees of freedom for exploring exotic quantum critical states and behaviors., Comment: https://www.nature.com/articles/s41586-022-05106-0

Published
2022
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15. Cataloguing MoSi$_2$N$_4$ and WSi$_2$N$_4$ van der Waals Heterostructures: An Exceptional Material Platform for Excitonic Solar Cell Applications

Author

Tho, Che Chen, Yu, Chenjiang, Tang, Qin, Wang, Qianqian, Su, Tong, Feng, Zhuoer, Wu, Qingyun, Nguyen, C. V., Ong, Wee-Liat, Liang, Shi-Jun, Guo, San-Dong, Cao, Liemao, Zhang, Shengli, Yang, Shengyuan A., Ang, Lay Kee, Wang, Guangzhao, and Ang, Yee Sin

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

Two-dimensional (2D) materials van der Waals heterostructures (vdWHs) provides a revolutionary route towards high-performance solar energy conversion devices beyond the conventional silicon-based pn junction solar cells. Despite tremendous research progress accomplished in recent years, the searches of vdWHs with exceptional excitonic solar cell conversion efficiency and optical properties remain an open theoretical and experimental quest. Here we show that the vdWH family composed of MoSi$_2$N$_4$ and WSi$_2$N$_4$ monolayers provides a compelling material platform for developing high-performance ultrathin excitonic solar cells and photonics devices. Using first-principle calculations, we construct and classify 51 types of MoSi$_2$N$_4$ and WSi$_2$N$_4$-based [(Mo,W)Si$_2$N$_4$] vdWHs composed of various metallic, semimetallic, semiconducting, insulating and topological 2D materials. Intriguingly, MoSi$_2$N$_4$/(InSe, WSe$_2$) are identified as Type-II vdWHs with exceptional excitonic solar cell power conversion efficiency reaching well over 20%, which are competitive to state-of-art silicon solar cells. The (Mo,W)Si$_2$N$_4$ vdWH family exhibits strong optical absorption in both the visible and ultraviolet regimes. Exceedingly large peak ultraviolet absorptions over 40%, approaching the maximum absorption limit of a free-standing 2D material, can be achieved in (Mo,W)Si$_2$N$_4$/$\alpha_2$-(Mo,W)Ge$_2$P$_4$ vdWHs. Our findings unravel the enormous potential of (Mo,W)Si$_2$N$_4$ vdWHs in designing ultimately compact excitonic solar cell device technology., Comment: 30 pages, 7 figures

Published
2022

16. Multiferroic van der Waals heterostructure FeCl$_2$/Sc$_2$CO$_2$: Nonvolatile electrically switchable electronic and spintronic properties

Author

Cao, Liemao, Deng, Xiaohui, Zhou, Guanghui, Liang, Shi-Jun, Nguyen, Chuong V., Ang, L. K., and Ang, Yee Sin

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

Multiferroic van der Waals (vdW) heterostrucutres offers an exciting route towards novel nanoelectronics and spintronics device technology. Here we investigate the electronic and transport properties of multiferroic vdW heterostructure composed of ferromagnetic FeCl$_2$ monolayer and ferroelectric Sc$_2$CO$_2$ monolayer using first-principles density functional theory and quantum transport simulations. We show that FeCl$_2$/Sc$_2$CO$_2$ heterostructure can be reversibly switched from semiconducting to half-metallic behavior by electrically modulating the ferroelectric polarization states of Sc$_2$CO$_2$. Intriguingly, the half-metallic phase exhibits a Type-III broken gap band alignment, which can be beneficial for tunnelling field-effect transistor application. We perform a quantum transport simulation, based on a \emph{proof-of-concept} two-terminal nanodevice, to demonstrate all-electric-controlled valving effects uniquely enabled by the nonvolatile ferroelectric switching of the heterostructure. These findings unravels the potential of FeCl$_2$/Sc$_2$CO$_2$ vdW heterostructures as a building block for designing a next generation of ultimately compact information processing, data storage and spintronics devices., Comment: 9 pages, 5 figures, accepted for publication in Physical Review B (2022)

Published
2022
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17. Scalable massively parallel computing using continuous-time data representation in nanoscale crossbar array

Author

Wang, Cong, Liang, Shi-Jun, Wang, Chen-Yu, Yang, Zai-Zheng, Ge, Yingmeng, Pan, Chen, Shen, Xi, Wei, Wei, Zhao, Yichen, Zhang, Zaichen, Cheng, Bin, Zhang, Chuan, and Miao, Feng

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

The growth of connected intelligent devices in the Internet of Things has created a pressing need for real-time processing and understanding of large volumes of analogue data. The difficulty in boosting the computing speed renders digital computing unable to meet the demand for processing analogue information that is intrinsically continuous in magnitude and time. By utilizing a continuous data representation in a nanoscale crossbar array, parallel computing can be implemented for the direct processing of analogue information in real time. Here, we propose a scalable massively parallel computing scheme by exploiting a continuous-time data representation and frequency multiplexing in a nanoscale crossbar array. This computing scheme enables the parallel reading of stored data and the one-shot operation of matrix-matrix multiplications in the crossbar array. Furthermore, we achieve the one-shot recognition of 16 letter images based on two physically interconnected crossbar arrays and demonstrate that the processing and modulation of analogue information can be simultaneously performed in a memristive crossbar array., Comment: 18 pages, 4 figures

Published
2021
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19. 2022 Roadmap on Neuromorphic Computing and Engineering

Author

Christensen, Dennis V., Dittmann, Regina, Linares-Barranco, Bernabé, Sebastian, Abu, Gallo, Manuel Le, Redaelli, Andrea, Slesazeck, Stefan, Mikolajick, Thomas, Spiga, Sabina, Menzel, Stephan, Valov, Ilia, Milano, Gianluca, Ricciardi, Carlo, Liang, Shi-Jun, Miao, Feng, Lanza, Mario, Quill, Tyler J., Keene, Scott T., Salleo, Alberto, Grollier, Julie, Marković, Danijela, Mizrahi, Alice, Yao, Peng, Yang, J. Joshua, Indiveri, Giacomo, Strachan, John Paul, Datta, Suman, Vianello, Elisa, Valentian, Alexandre, Feldmann, Johannes, Li, Xuan, Pernice, Wolfram H. P., Bhaskaran, Harish, Furber, Steve, Neftci, Emre, Scherr, Franz, Maass, Wolfgang, Ramaswamy, Srikanth, Tapson, Jonathan, Panda, Priyadarshini, Kim, Youngeun, Tanaka, Gouhei, Thorpe, Simon, Bartolozzi, Chiara, Cleland, Thomas A., Posch, Christoph, Liu, Shih-Chii, Panuccio, Gabriella, Mahmud, Mufti, Mazumder, Arnab Neelim, Hosseini, Morteza, Mohsenin, Tinoosh, Donati, Elisa, Tolu, Silvia, Galeazzi, Roberto, Christensen, Martin Ejsing, Holm, Sune, Ielmini, Daniele, and Pryds, N.

Subjects
Computer Science - Emerging Technologies, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Materials Science
Abstract

Modern computation based on the von Neumann architecture is today a mature cutting-edge science. In the Von Neumann architecture, processing and memory units are implemented as separate blocks interchanging data intensively and continuously. This data transfer is responsible for a large part of the power consumption. The next generation computer technology is expected to solve problems at the exascale with 1018 calculations each second. Even though these future computers will be incredibly powerful, if they are based on von Neumann type architectures, they will consume between 20 and 30 megawatts of power and will not have intrinsic physically built-in capabilities to learn or deal with complex data as our brain does. These needs can be addressed by neuromorphic computing systems which are inspired by the biological concepts of the human brain. This new generation of computers has the potential to be used for the storage and processing of large amounts of digital information with much lower power consumption than conventional processors. Among their potential future applications, an important niche is moving the control from data centers to edge devices. The aim of this Roadmap is to present a snapshot of the present state of neuromorphic technology and provide an opinion on the challenges and opportunities that the future holds in the major areas of neuromorphic technology, namely materials, devices, neuromorphic circuits, neuromorphic algorithms, applications, and ethics. The Roadmap is a collection of perspectives where leading researchers in the neuromorphic community provide their own view about the current state and the future challenges. We hope that this Roadmap will be a useful resource to readers outside this field, for those who are just entering the field, and for those who are well established in the neuromorphic community. https://doi.org/10.1088/2634-4386/ac4a83

Published
2021
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20. Designing Efficient Metal Contacts to Two-Dimensional Semiconductors MoSi$_2$N$_4$ and WSi$_2$N$_4$ Monolayers

Author

Wang, Qianqian, Cao, Liemao, Liang, Shi-Jun, Wu, Weikang, Wang, Guangzhao, Lee, Ching Hua, Ong, Wee Liat, Yang, Hui Ying, Ang, Lay Kee, Yang, Shengyuan A., and Ang, Yee Sin

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

Metal contacts to two-dimensional (2D) semiconductors are ubiquitous in modern electronic and optoelectronic devices. Such contacts are, however, often plagued by strong Fermi level pinning (FLP) effect which reduces the tunability of the Schottky barrier height (SBH) and degrades the performance of 2D-semiconductor-based devices. In this work, we show that monolayer MoSi$_2$N$_4$ and WSi$_2$N$_4$ - a recently synthesized 2D material class with exceptional mechanical and electronic properties - exhibit strongly suppressed FLP and wide-range tunable SBH when contacted by metals. An exceptionally large SBH slope parameter of S=0.7 is obtained, which outperform the vast majority of other 2D semiconductors. Such surprising behavior arises from the unique morphology of MoSi$_2$N$_4$ and WSi$_2$N$_4$. The outlying Si-N layer forms a native atomic layer that protects the semiconducting inner-core from the perturbance of metal contacts, thus suppressing the FLP. Our findings reveal the potential of MoSi$_2$N$_4$ and WSi$_2$N$_4$ monolayers as a novel 2D material platform for designing high-performance and energy-efficient 2D nanodevices., Comment: 28 pages, 5 figures

Published
2020

21. Observation of Negative THz Photoconductivity in Large Area Type-II Dirac Semimetal PtTe2

Author

Suo, Peng, Zhang, Huiyun, Yan, Shengnan, Zhang, Wenjie, Fu, Jibo, Lin, Xian, Hao, Song, Jin, Zuanming, Zhang, Yuping, Zhang, Chao, Miao, Feng, Liang, Shi-Jun, and Ma, Guohong

Subjects
Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons, Physics - Optics
Abstract

As a newly emergent type-II Dirac semimetal, Platinum Telluride (PtTe2) stands out from other 2D noble-transition-metal dichalcogenides for the unique structure and novel physical properties, such as high carrier mobility, strong electron-phonon coupling and tunable bandgap, which make the PtTe2 a good candidate for applications in optoelectronics, valleytronics and far infrared detectors. Although the transport properties of PtTe2 have been studied extensively, the dynamics of the nonequilibrium carriers remain nearly uninvestigated. Herein we employ optical pump-terahertz (THz) probe spectroscopy (OPTP) to systematically study the photocarrier dynamics of PtTe2 thin films with varying pump fluence, temperature, and film thickness. Upon photoexcitation the THz photoconductivity (PC) of 5 nm PtTe2 film shows abrupt increase initially, while the THz PC changes into negative value in a subpicosecond time scale, followed by a prolonged recovery process that lasted hundreds of picoseconds (ps). This unusual THz PC response observed in the 5 nm PtTe2 film was found to be absent in a 2 nm PtTe2 film. We assign the unexpected negative THz PC as the small polaron formation due to the strong electron-Eg-mode phonon coupling, which is further substantiated by pump fluence- and temperature-dependent measurements as well as the Raman spectroscopy. Moreover, our investigations give a subpicosecond time scale of sequential carrier cooling and polaron formation. The present study provides deep insights into the underlying dynamics evolution mechanisms of photocarrier in type-II Dirac semimetal upon photoexcitation, which is fundamental importance for designing PtTe2-based optoelectronic devices., Comment: 18 pages, 4 figures

Published
2020
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22. Gate-tunable van der Waals heterostructure for reconfigurable neural network vision sensor

Author

Wang, Chen-Yu, Liang, Shi-Jun, Wang, Shuang, Wang, Pengfei, Li, Zhuan, Wang, Zhongrui, Gao, Anyuan, Pan, Chen, Liu, Chuan, Liu, Jian, Yang, Huafeng, Liu, Xiaowei, Song, Wenhao, Wang, Cong, Wang, Xiaomu, Chen, Kunji, Wang, Zhenlin, Watanabe, Kenji, Taniguchi, Takashi, Yang, J. Joshua, and Miao, Feng

Subjects
Condensed Matter - Materials Science, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics
Abstract

Early processing of visual information takes place in the human retina. Mimicking neurobiological structures and functionalities of the retina provide a promising pathway to achieving vision sensor with highly efficient image processing. Here, we demonstrate a prototype vision sensor that operates via the gate-tunable positive and negative photoresponses of the van der Waals (vdW) vertical heterostructures. The sensor emulates not only the neurobiological functionalities of bipolar cells and photoreceptors but also the unique synaptic connectivity between bipolar cells and photoreceptors. By tuning gate voltage for each pixel, we achieve reconfigurable vision sensor for simultaneously image sensing and processing. Furthermore, our prototype vision sensor itself can be trained to classify the input images, via updating the gate voltages applied individually to each pixel in the sensor. Our work indicates that vdW vertical heterostructures offer a promising platform for the development of neural network vision sensor., Comment: 20 pages, 4 figures

Published
2020
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24. Edge-Epitaxial Growth of InSe Nanowires toward High-Performance Photodetectors

Author

Hao, Song, Yan, Shengnan, Wang, Yang, Xu, Tao, Zhang, Hui, Cong, Xin, Li, Lingfei, Liu, Xiaowei, Cao, Tianjun, Gao, Anyuan, Zhang, Lili, Jia, Lanxin, Long, Mingsheng, Hu, Weida, Wang, Xiaomu, Tan, Pingheng, Sun, Litao, Cui, Xinyi, Liang, Shi-Jun, and Miao, Feng

Subjects
Physics - Applied Physics
Abstract

Semiconducting nanowires offer many opportunities for electronic and optoelectronic device applications due to their special geometries and unique physical properties. However, it has been challenging to synthesize semiconducting nanowires directly on SiO2/Si substrate due to lattice mismatch. Here, we developed a catalysis-free approach to achieve direct synthesis of long and straight InSe nanowires on SiO2/Si substrate through edge-homoepitaxial growth. We further achieved parallel InSe nanowires on SiO2/Si substrate through controlling growth conditions. We attributed the underlying growth mechanism to selenium self-driven vapor-liquid-solid process, which is distinct from conventional metal-catalytic vapor-liquid-solid method widely used for growing Si and III-V nanowires. Furthermore, we demonstrated that the as-grown InSe nanowire-based visible light photodetector simultaneously possesses an extraordinary photoresponsivity of 271 A/W, ultrahigh detectivity of 1.57*10^14 Jones and a fast response speed of microsecond scale. The excellent performance of the photodetector indicates that as-grown InSe nanowires are promising in future optoelectronic applications. More importantly, the proposed edge-homoepitaxial approach may open up a novel avenue for direct synthesis of semiconducting nanowire arrays on SiO2/Si substrate., Comment: 19 pages, 4 figures, published in Small

Published
2019
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25. Van der Waals heterostructures for high-performance device applications: challenges and opportunities

Author

Liang, Shi-Jun, Cheng, Bin, Cui, Xinyi, and Miao, Feng

Subjects
Physics - Applied Physics
Abstract

Discovery of two-dimensional materials with unique electronic, superior optoelectronic or intrinsic magnetic order have triggered worldwide interests among the fields of material science, condensed matter physics and device physics. Vertically stacking of two-dimensional materials with distinct electronic and optical as well as magnetic properties enables to create a large variety of van der Waals heterostructures. The diverse properties of the vertical heterostructures open up unprecedented opportunities for various kinds of device applications, e.g. vertical field effect transistors, ultrasensitive infrared photodetectors, spin-filtering devices and so on, which are inaccessible in the conventional material heterostructures. Here, we review the current status of vertical heterostructures device applications in vertical transistors, infrared photodetectors and spintronic memory/transistors. The relevant challenges for achieving high-performance devices are presented. We also provide outlook on future development of vertical heterostructure devices with integrated electronic and optoelectronic as well as spintronic functinalities., Comment: 49 pages, 18 figures, published in Advanced Materials

Published
2019
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26. Two-dimensional layered materials for memristive and neuromorphic applications

Author

Wang, Chen-Yu, Wang, Cong, Meng, Fanhao, Wang, Pengfei, Wang, Shuang, Liang, Shi-Jun, and Miao, Feng

Subjects
Physics - Applied Physics
Abstract

With many fantastic properties, memristive devices have been proposed as top candidate for next-generation memory and neuromorphic computing chips. Significant research progresses have been made in improving performance of individual memristive devices and in demonstrating functional applications based on small-scale memristive crossbar arrays. However, practical deployment of large-scale traditional metal oxides based memristive crossbar array has been challenging due to several issues, such as high-power consumption, poor device reliability, low integration density and so on. To solve these issues, new materials that possess superior properties are required. Two-dimensional (2D) layered materials exhibit many unique physical properties and show great promise in solving these challenges, further providing new opportunities to implement practical applications in neuromorphic computing. Here, recent research progress on 2D layered materials based memristive device applications is reviewed. We provide an overview of the progresses and challenges on how 2D layered materials are used to solve the issues of conventional memristive devices and to realize more complex functionalities in neuromorphic computing. Besides, we also provide an outlook on exploitation of unique properties of 2D layered materials and van der Waals heterostructures for developing new types of memristive devices and artificial neural mircrocircuits., Comment: 38 pages,10 figures published in Advanced Electronic Materials

Published
2019
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27. Local electric field induced spin photocurrent in ReS2

Author

Zhang, Yang, Wang, Yu, Liu, Yu, Zeng, Xiao-Lin, Wu, Jing, Yu, Jin ling, Cao, Tian-Jun, Liang, Shi-Jun, and Chen, Yong-Hai

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

Circular polarized photocurrent is observed near the electrodes on a few-layer ReS2sample at room temperature. For both electrodes, the spatial distribution of the circular polarized photocurrent shows a feature of two wings, with one positive and the other negative. We suggest that this phenomenon arises from the inverse spin Hall effect due to local electric field near the electrode. Bias voltage that modulates this field further controls the sign and magnitude of the inverse spin Hall effect photocurrent. Our research shows that electric field near electrodes has a significant impact on spin transmission operation, hence it could be taken into account for manufacturing spintronic devices in future., Comment: 14 pages,6 figures

Published
2019

28. Direct evidence for charge compensation induced large magnetoresistance in thin WTe2

Author

Wang, Yaojia, Wang, Lizheng, Liu, Xiaowei, Wu, Heng, Wang, Pengfei, Yan, Dayu, Cheng, Bin, Shi, Youguo, Watanabe, Kenji, Taniguchi, Takashi, Liang, Shi-Jun, and Miao, Feng

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Since the discovery of extremely large non-saturating magnetoresistance (MR) in WTe2, much effort has been devoted to understanding the underlying mechanism, which is still under debate. Here, we explicitly identify the dominant physical origin of the large non-saturating MR through in-situ tuning of the magneto-transport properties in thin WTe2 film. With an electrostatic doping approach, we observed a non-monotonic gate dependence of the MR. The MR reaches a maximum (10600%) in thin WTe2 film at certain gate voltage where electron and hole concentrations are balanced, indicating that the charge compensation is the dominant mechanism of the observed large MR. Besides, we show that the temperature dependent magnetoresistance exhibits similar tendency with the carrier mobility when the charge compensation is retained, revealing that distinct scattering mechanisms may be at play for the temperature dependence of magneto-transport properties. Our work would be helpful for understanding mechanism of the large MR in other nonmagnetic materials and offers an avenue for achieving large MR in the non-magnetic materials with electron-hole pockets., Comment: 16 pages, 3 figures, accepted by Nano Letters

Published
2019
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29. Pressure-Tunable Ambipolar Conduction and Hysteresis in Ultrathin Palladium Diselenide Field Effect Transistors

Author

Di Bartolomeo, Antonio, Pelella, Aniello, Liu, Xiaowei, Miao, Feng, Passacantando, Maurizio, Giubileo, Filippo, Grillo, Alessandro, Iemmo, Laura, Urban, Francesca, and Liang, Shi-Jun

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

A few-layer palladium diselenide (PdSe2) field effect transistor is studied under external stimuli such as electrical and optical fields, electron irradiation and gas pressure. We observe ambipolar conduction and hysteresis in the transfer curves of the PdSe2 material unprotected and as-exfoliated. We tune the ambipolar conduction and its hysteretic behavior in the air and pure nitrogen environments. The prevailing p-type transport observed at room pressure is reversibly turned into dominant n-type conduction by reducing the pressure, which can simultaneously suppress the hysteresis. The pressure control can be exploited to symmetrize and stabilize the transfer characteristic of the device as required in high-performance logic circuits. The transistor is immune from short channel effects but is affected by trap states with characteristic times in the order of minutes. The channel conductance, dramatically reduced by the electron irradiation during scanning electron microscope imaging, is restored after several minutes anneal at room temperature. The work paves the way toward the exploitation of PdSe2 in electronic devices by providing an experiment-based and deeper understanding of charge transport in PdSe2 transistors subjected to electrical stress and other external agents., Comment: 21 pages - 5 figure panels

Published
2019
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30. S-type Negative Differential Resistance in Semiconducting Transition-Metal Dichalcogenides

Author

Wang, Miao, Wang, Chengyu, Wu, Chenchen, Li, Qiao, Pan, Chen, Wang, Cong, Liang, Shi-Jun, and Miao, Feng

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Current-controlled (also known as "S-type") negative differential resistance (NDR) is of crucial importance to many emerging applications including neuromorphic computing and high-density memristors integration. However, the experimental realization of S-type NDR based on conventional mechanisms poses demanding requirements on materials, which greatly limits their potential applications. Here, we experimentally identify that semiconducting transition metal dichalcogenides (TMDs) can host a bipolar S-type NDR devices. Theoretical simulations indicate that the origin of the NDR in these devices arises from a thermal feedback mechanism. Furthermore, we demonstrate the potential applications of TMDs based S-type NDR device in signal processing and neuromorphic electronics., Comment: To be appear in Advanced Electronic Materials, 9 pages 4 figures

Published
2019
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32. Electrical switching of Ising-superconducting nonreciprocity for quantum neuronal transistor

Author

Xiong, Junlin, primary, Xie, Jiao, additional, Cheng, Bin, additional, Dai, Yudi, additional, Cui, Xinyu, additional, Wang, Lizheng, additional, Liu, Zenglin, additional, Zhou, Ji, additional, Wang, Naizhou, additional, Xu, Xianghan, additional, Chen, Xianhui, additional, Cheong, Sang-Wook, additional, Liang, Shi-Jun, additional, and Miao, Feng, additional

Published
2024
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33. Experimental identification of critical condition for drastically enhancing thermoelectric power factor of two-dimensional layered materials

Author

Zeng, Junwen, He, Xin, Liang, Shi-Jun, Liu, Erfu, Sun, Yuanhui, Pan, Chen, Wang, Yu, Cao, Tianjun, Liu, Xiaowei, Wang, Chengyu, Zhang, Lili, Yan, Shengnan, Su, Guangxu, Wang, Zhenlin, Watanabe, Kenji, Taniguchi, Takashi, Singh, David J., Zhang, Lijun, and Miao, Feng

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Nano-structuring is an extremely promising path to high performance thermoelectrics. Favorable improvements in thermal conductivity are attainable in many material systems, and theoretical work points to large improvements in electronic properties. However, realization of the electronic benefits in practical materials has been elusive experimentally. A key challenge is that experimental identification of the quantum confinement length, below which the thermoelectric power factor is significantly enhanced, remains elusive due to lack of simultaneous control of size and carrier density. Here we investigate gate tunable and temperature-dependent thermoelectric transport in $\gamma$ phase indium selenide ($\gamma$ InSe, n type semiconductor) samples with thickness varying from 7 to 29 nm. This allows us to properly map out dimension and doping space. Combining theoretical and experimental studies, we reveal that the sharper pre-edge of the conduction-band density of states arising from quantum confinement gives rise to an enhancement of the Seebeck coefficient and the power factor in the thinner InSe samples. Most importantly, we experimentally identify the role of the competition between quantum confinement length and thermal de Broglie wavelength in the enhancement of power factor. Our results provide an important and general experimental guideline for optimizing the power factor and improving the thermoelectric performance of two-dimensional layered semiconductors., Comment: 26 page, 5 figures

Published
2018
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34. Proximity-Induced Superconductivity with Subgap Anomaly in Type II Weyl Semi-Metal WTe2

Author

Li, Qiao, He, Chaocheng, Wang, Yaojia, Liu, Erfu, Wang, Miao, Wang, Yu, Zeng, Junwen, Ma, Zecheng, Cao, Tianjun, Yi, Changjiang, Wang, Naizhou, Watanabe, Kenji., Taniguchi, Takashi., Shao, Lubing, Shi, Youguo, Chen, Xianhui, Liang, Shi-Jun, Wang, Qiang-Hua, and Miao, Feng

Subjects
Condensed Matter - Superconductivity
Abstract

Due to the non-trivial topological band structure in type-II Weyl semimetal Tungsten ditelluride (WTe2), unconventional properties may emerge in its superconducting phase. While realizing intrinsic superconductivity has been challenging in the type-II Weyl semimetal WTe2, proximity effect may open an avenue for the realization of superconductivity. Here, we report the observation of proximity-induced superconductivity with a long coherence length along c axis in WTe2 thin flakes based on a WTe2/NbSe2 van der Waals heterostructure. Interestingly, we also observe anomalous oscillations of the differential resistance during the transition from superconducting to normal state. Theoretical calculations show excellent agreement with experimental results, revealing that such a sub-gap anomaly is the intrinsic property of WTe2 in superconducting state induced by the proximity effect. Our findings enrich the understanding of superconducting phase of type-II Weyl semimetals, and pave the way for their future applications in topological quantum computing., Comment: 20 pages, 4 figures

Published
2018
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35. Negative Photoconductance in van der Waals Heterostructures-Based Floating Gate Phototransistor

Author

Wang, Yu, Liu, Erfu, Gao, Anyuan, Cao, Tianjun, Long, Mingsheng, Pan, Chen, Zhang, Lili, Zeng, Junwen, Wang, Chenyu, Hu, Weida, Liang, Shi-Jun, and Miao, Feng

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Van der Waals (vdW) heterostructures made of two-dimensional materials have been demonstrated to be versatile architectures for optoelectronic applications due to strong light-matter interactions. However, most of light-controlled phenomena and applications in the vdW heterostructures rely on positive photoconductance (PPC). Negative photoconductance (NPC) has not yet been reported in vdW heterostructures. Here we report the observation of the NPC in ReS2/h-BN/MoS2 vdW heterostructures-based floating gate phototransistor. The fabricated devices exhibit excellent performance of nonvolatile memory without light illumination. More interestingly, we observe a gate-tunable transition between the PPC and the NPC under the light illumination. The observed NPC phenomenon can be attributed to the charge transfer between floating gate and conduction channel. Furthermore, we show that the control of NPC through light intensity is promising in realization of light-tunable multi-bit memory devices. Our results may enable potential applications in multifunctional memories and optoelectronic devices., Comment: 21 pages, 4 figures, accepted by ACS Nano

Published
2018

36. Low-Temperature Eutectic Synthesis of PtTe2 with Weak Antilocalization and Controlled Layer Thinning

Author

Hao, Song, Zeng, Junwen, Xu, Tao, Cong, Xin, Wang, Chenyu, Wu, Chenchen, Wang, Yaojia, Liu, Xiaowei, Cao, Tianjun, Su, Guangxu, Jia, Lanxin, Wu, Zhangting, Lin, Qian, Zhang, Lili, Yan, Shengnan, Guo, Mengfan, Wang, Zhenlin, Tan, Pingheng, Sun, Litao, Ni, Zhenhua, Liang, Shi-Jun, Cui, Xinyi, and Miao, Feng

Subjects
Condensed Matter - Materials Science
Abstract

Metallic transition metal dichalcogenides (TMDs) have exhibited various exotic physical properties and hold the promise of novel optoelectronic and topological devices applications. However, the synthesis of metallic TMDs is based on gas-phase methods and requires high temperature condition. As an alternative to the gas-phase synthetic approach, lower temperature eutectic liquid-phase synthesis presents a very promising approach with the potential for larger-scale and controllable growth of high-quality thin metallic TMDs single crystals. Herein, we report the first realization of low-temperature eutectic liquid-phase synthesis of type-II Dirac semimetal PtTe2 single crystals with thickness ranging from 2 to 200 nm. The electrical measurement of synthesized PtTe2 reveals a record-high conductivity of as high as 3.3*106 S/m at room temperature. Besides, we experimentally identify the weak antilocalization behavior in the type-II Dirac semimetal PtTe2 for the first time. Furthermore, we develop a simple and general strategy to obtain atomically-thin PtTe2 crystal by thinning as-synthesized bulk samples, which can still retain highly crystalline and exhibits excellent electric conductivity. Our results of controllable and scalable low-temperature eutectic liquid-phase synthesis and layer-by-layer thinning of high-quality thin PtTe2 single crystals offer a simple and general approach for obtaining different thickness metallic TMDs with high-melting point transition metal.

Published
2018
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37. Asymmetric Schottky Contacts in Bilayer MoS2 Field Effect Transistors

Author

Di Bartolomeo, Antonio, Grillo, Alessandro, Urban, Francesca, Iemmo, Laura, Giubileo, Filippo, Luongo, Giuseppe, Amato, Giampiero, Croin, Luca, Sun, Linfeng, Liang, Shi-Jun, and Ang, Lay Kee

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We discuss the high-bias electrical characteristics of back-gated field-effect transistors with CVD-synthesized bilayer MoS2 channel and Ti Schottky contacts. We find that oxidized Ti contacts on MoS2 form rectifying junctions with ~0.3 to 0.5 eV Schottky barrier height. To explain the rectifying output characteristics of the transistors, we propose a model based on two slightly asymmetric back-to-back Schottky barriers, where the highest current arises from image force barrier lowering at the electrically forced junction, while the reverse current is due to Schottky-barrier limited injection at the grounded junction. The device achieves a photo responsivity greater than 2.5 AW-1 under 5 mWcm-2 white-LED light. By comparing two- and four-probe measurements, we demonstrate that the hysteresis and persistent photoconductivity exhibited by the transistor are peculiarities of the MoS2 channel rather than effects of the Ti/MoS2 interface., Comment: 22 pages, 5 figure

Published
2018
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38. Gate-Induced Interfacial Superconductivity in 1T-SnSe2

Author

Zeng, Junwen, Liu, Erfu, Fu, Yajun, Chen, Zhuoyu, Pan, Chen, Wang, Chenyu, Wang, Miao, Wang, Yaojia, Xu, Kang, Cai, Songhua, Yan, Xingxu, Wang, Yu, Liu, Xiaowei, Wang, Peng, Liang, Shi-Jun, Cui, Yi, Hwang, Harold Y., Yuan, Hongtao, and Miao, Feng

Subjects
Condensed Matter - Superconductivity
Abstract

Layered metal chalcogenide materials provide a versatile platform to investigate emergent phenomena and two-dimensional (2D) superconductivity at/near the atomically thin limit. In particular, gate-induced interfacial superconductivity realized by the use of an electric-double-layer transistor (EDLT) has greatly extended the capability to electrically induce superconductivity in oxides, nitrides and transition metal chalcogenides and enable one to explore new physics, such as the Ising pairing mechanism. Exploiting gate-induced superconductivity in various materials can provide us with additional platforms to understand emergent interfacial superconductivity. Here, we report the discovery of gate-induced 2D superconductivity in layered 1T-SnSe2, a typical member of the main-group metal dichalcogenide (MDC) family, using an EDLT gating geometry. A superconducting transition temperature Tc around 3.9 K was demonstrated at the EDL interface. The 2D nature of the superconductivity therein was further confirmed based on 1) a 2D Tinkham description of the angle-dependent upper critical field, 2) the existence of a quantum creep state as well as a large ratio of the coherence length to the thickness of superconductivity. Interestingly, the in-plane approaching zero temperature was found to be 2-3 times higher than the Pauli limit, which might be related to an electric field-modulated spin-orbit interaction. Such results provide a new perspective to expand the material matrix available for gate-induced 2D superconductivity and the fundamental understanding of interfacial superconductivity., Comment: 18 pages, 4 figures, accepted by Nano Letters

Published
2018
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39. Analog Circuit Applications based on Ambipolar Graphene/MoTe2 Vertical Transistors

Author

Pan, Chen, Fu, Yajun, Wang, Jiaxin, Zeng, Junwen, Su, Guangxu, Long, Mingsheng, Liu, Erfu, Wang, Chenyu, Gao, Anyuan, Wang, Miao, Wang, Yu, Wang, Zhenlin, Liang, Shi-Jun, Huang, Ru, and Miao, Feng

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The current integrated circuit (IC) technology based on conventional MOS-FET (metal-oxide-semiconductor field-effect transistor) is approaching the limit of miniaturization with increasing demand on energy. Several analog circuit applications based on graphene FETs have been demonstrated with less components comparing to the conventional technology. However, low on/off current ratio caused by the semimetal nature of graphene has severely hindered its practical applications. Here we report a graphene/MoTe2 van der Waals (vdW) vertical transistor with V-shaped ambipolar field effect transfer characteristics to overcome this challenge. Investigations on temperature dependence of transport properties reveal that gate tunable asymmetric barriers of the devices are account for the ambipolar behaviors. Furthermore, to demonstrate the analog circuit applications of such vdW vertical transistors, we successfully realized output polarity controllable (OPC) amplifier and frequency doubler. These results enable vdW heterojunction based electronic devices to open up new possibilities for wide perspective in telecommunication field., Comment: To appear on Advanced Electronics Materials; 26 pages, 5 figures, 7 supplementary figures

Published
2018
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41. Adiabatic control of surface plasmon-polaritons in a 3-layers graphene curved configuration

Author

Huang, Wei, Liang, Shi-Jun, Kyoseva, Elica, and Ang, Lay Kee

Subjects
Quantum Physics, Physics - Optics, Physics - Plasma Physics
Abstract

In this paper, we utilize coupled mode theory (CMT) to model the coupling between surface plasmon-polaritons (SPPs) between multiple graphene sheets. By using the Stimulated Raman Adiabatic Passage (STIRAP) Quantum Control Technique, we propose a novel directional coupler based on SPPs evolution in three layers of graphene sheets in some curved configuration. Our calculated results show that the SPP can be transferred efficiently from the input graphene sheet to the output graphene sheet, and the coupling is also robust that it is not sensitive to the length of the device., Comment: 4 figures

Published
2017
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42. Electrical transport and persistent photoconductivity in monolayer MoS2 phototransistors

Author

Di Bartolomeo, Antonio, Genovese, Luca, Foller, Tobias, Giubileo, Filippo, Luongo, Giuseppe, Croin, Luca, Liang, Shi-Jun, Ang, L. K., and Schleberger, Marika

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We study electrical transport properties in exfoliated molybdenum disulfide (MoS2) back-gated field effect transistors at low drain bias and under different illumination intensities. It is found that photoconductive and photogating effect as well as space charge limited conduction can simultaneously occur. We point out that the photoconductivity increases logarithmically with the light intensity and can persist with a decay time longer than 10^4 s, due to photo-charge trapping at the MoS2/SiO2 interface and in MoS2 defects. The transfer characteristics present hysteresis that is enhanced by illumination. At low drain bias, the devices feature low contact resistance of 1.4 k{\Omega}/{\mu}m, ON current as high as 1.25 nA/{\mu}m, 10^5 ON-OFF ratio, mobility of 1 cm^2/Vs and photoresponsivity R=1 A/W., Comment: Research paper, 12 pages, 4 figures

Published
2017
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43. A new coupling mechanism between two graphene electron waveguides for ultrafast switching

Author

Huang, Wei, Liang, Shi-Jun, Kyoseva, Elica, and Ang, Lay Kee

Subjects
Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics
Abstract

We propose a novel ultrafast electronic switching device based on dual-graphene electron waveguides, in analogy to the optical dual-channel waveguide device. The design utilizes the principle of coherent quantum mechanical tunneling of Rabi oscillations between the two graphene electron waveguides. Based on a modified coupled mode theory, we construct a theoretical model to analyse the device characteristics, and predict that the swtiching speed is faster than 1 ps. Due to the long mean free path of electrons in graphene at room temperature, the proposed design avoids the limitation of low temperature operation required in the normal semiconductor quantum-well structure. The layout of the our design is similar to that of a standard CMOS transistor that should be readily fabricated with current state-of-art nanotechnology., Comment: 6 pages, 4 figures

Published
2017
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44. Rotation-invariant image recognition using interconnected floating-gate phototransistor.

Author

Pan, Xuan, Shi, Jingwen, Yu, Wentao, Zhao, Yichen, Yang, Yuekun, Cheng, Bin, Liang, Shi-Jun, and Miao, Feng

Subjects
IMAGE analysis, VISUAL fields, ELECTRON tunneling, IMAGING systems, PHOTOTRANSISTORS
Abstract

Rotational invariance is fundamental for robust image recognition systems, ensuring accurate analysis irrespective of image orientation. However, existing systems predominantly reliant on software often encounter challenges such as increased computational demands and compromises between processing speed and accuracy. In this study, we propose leveraging the interconnected floating-gate (FG) structure as an effective hardware-level solution to achieve rotational invariance in image recognition. Our design features a reconfigurable two-dimensional material FG phototransistor array, where each processing unit integrates four sensory devices sharing a common FG. This configuration facilitates uniform distribution of stored charges across the interconnected FG layer, which is typically made of metal, enabling consistent application of a single weight matrix to images across varied rotational conditions. The photoactive material, tungsten diselenide (WSe2), possesses a distinctive bipolar property that facilitates both hole and electron tunneling into the FG layer. This property directly contributes to the efficiency of state transition within the setup and improves its overall adaptability. In this manner, our design achieves stable and predictable outputs in recognizing identical digital numbers regardless of their rotation, while also demonstrating variable performance essential for accurately distinguishing between different digital numbers. This dual capability guarantees both the adaptability and precision required for rotation-invariant image recognition, suggesting that our work may open up a promising venue for exploring advanced hardware designs, such as optimized interconnected FG architectures, tailored for enhancing recognition accuracy and efficiency in the field of intelligent visual systems. [ABSTRACT FROM AUTHOR]

Published
2024
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49. High-Efficiency Van Der Waals heterostructure Thermionic Device With Graphene Electrodes

Author

Liang, Shi-Jun and Ang, Lay Kee

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In this paper, we propose van del Waals heterostructure-based thermionic devices for the applications in cooling and power generation in the temperature range of 300 to 400 K. By using two-dimensional materials of low cross-plane thermal conductivity as the barrier materials and graphene as electrodes, our calculation demonstrates that our proposed device will have a higher efficiency as compared to other methods such as thermoelectric device and the traditional thermionic devices. By using the parameters within the current technology, we predict a cooling capability at more than 50$\%$ of the Carnot efficiency, and a 10 to 20 $\%$ efficiency in harvesting the wasted heat at 400 K., Comment: This paper has been withdrawn by the author due to incomplete information

Published
2015

50. Revised diode equation for Ideal Graphene-Semiconductor Schottky Junction

Author

Liang, Shi-Jun and Ang, Lay Kee

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In this paper we carry out a theoretical and experimental study of the nature of graphene/semiconductor Schottky contact. We present a simple and parameter-free carrier transport model of graphene/semiconductor Schottky contact derived from quantum statistical theory, which is validated by the quantum Landauer theory and first-principle calculations. The proposed model can well explain experimental results for samples of different types of graphene/semiconductor Schottky contact., Comment: 4 pages 8 figures

Published
2015

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