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In recent years, the development of artificial intelligence has increased the demand for computing and storage. However, the slowing down of Moore’s law and the separation between computing and storage units in traditional von Neumann architectures result in the increase of power consumption and time delays in the transport of abundant data, raising more and more challenges for integrated circuit and chip design. It is urgent for us to develop new computing paradigms to meet this challenge. The neuromorphic devices based on the in-memory computing architecture can overcome the traditional von Neumann architecture by Ohm’s law and Kirchhoff’s current law. By adjusting the resistance value of the memristor, the artificial neural network which can mimic the biological brain will be realized, and complex signal processing such as image recognition, pattern classification and decision determining can be carried out. In order to further reduce the size of device and realize the integration of sensing, memory and computing, two-dimensional materials can provide a potential solution due to their ultrathin thickness and rich physical effects. In this paper, we review the physical effects and memristive properties of neuromorphic devices based on two-dimensional materials, and describe the synaptic plasticity of neuromorphic devices based on leaky integrate and fire model and Hodgkin-Huxley model in detail, including long-term synaptic plasticity, short-term synaptic plasticity, spiking-time-dependent plasticity and spiking-rate-dependent plasticity. Moreover, the potential applications of two-dimensional materials based neuromorphic devices in the fields of vision, audition and tactile are introduced. Finally, we summarize the current issues on two-dimensional materials based neuromorphic computing and give the prospects for their future applications.
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图 1 基于2D材料的忆阻器工作机制示意图, 其中包括经典效应, 如相变效应、铁电效应, 以及量子效应, 如导电细丝效应、氧空位效应、电荷捕获效应、隧穿效应、vdWs效应等
Figure 1. Schematic diagram of physical working mechanisms of memristor based on 2D materials, including classical effects, such as phase change effect, ferroelectric effect, and quantum effect, like conductive filament effect, oxygen vacancy effect, charge trapping effect, tunneling effect, vdWs effect, etc.
图 2 相变效应 (a) Au/MoS2/Au器件结构示意图以及在电场作用下Li+调控MoS2发生可逆相变过程的示意图[40]; (b) Au/MoS2/Au器件的I-V特性曲线[40]; (c) 通过脉冲编程电压改变电导增量[40]; (d) MoTe2在电场作用下的相变过程以及MoTe2在2H (左下)和2Hd (右下)态下的STEM图像[41]; (e) 电形成过程前后的I-V扫描曲线[41]
Figure 2. Phase change effect: (a) Schematic diagram of Au/MoS2/Au device structure and Li+ regulating the reversible phase change process of MoS2 under the applied electric field[40]; (b) typical I-V curve of Au/MoS2/Au device[40]; (c) conductance changing with continuous pulse programming voltage[40]; (d) phase change process of MoTe2 with electric field applied and the STEM images of 2H (bottom left) and 2Hd (bottom right) states of MoTe2[41]; (e) I-V curves of devices before and after forming processes[41].
图 3 铁电效应 (a) 基于α-In2Se3的FeSFET器件示意图[43]; (b) α-In2Se3沟道材料向上和向下极化时的状态图示, 以及相应的能带图[43]; (c) 不同Vg扫描下器件传输特性曲线[43]; (d) 器件在5个连续的周期脉冲电压下稳定突触后电流(PSC)的增强、抑制效果图[43]
Figure 3. Ferroelectric effect: (a) Schematic of the α-In2Se3 based FeSFET[43]; (b) illustrations of the upward and downward polarized states of α-In2Se3 channel material and the corresponding energy band diagram[44]; (c) device transfer characteristic curves under different scanning ranges of Vg[43]; (d) the potentiation and depression process of the post-synaptic-current (PSC) under 5 continuous periodic voltage pulses[43].
图 4 导电细丝效应 (a) Ag/SnOx/SnSe器件示意图以及器件的横截面TEM图像[78]; (b) 忆阻器的保持性超过105 s[78]; (c) Ag/SnOx/SnSe器件初始状态、导电细丝形成和断裂的示意图[78]; 在CDG (d)和DDG (e)器件中导电细丝形成和断裂示意图[83]
Figure 4. Conductive filament effect: (a) Schematic of Ag/SnOx/SnSe device and the cross-sectional TEM image of the interface[78]; (b) the retention of the device over 105 s[78]; (c) schematic of Ag/SnOx/SnSe device at initial state, conductive filament formation process and fracture state[78]; schematic of conductive filament formation and rupture in CDG (d) and DDG (e) device[83].
图 5 氧空位效应 (a) Ti/HfSexOy/HfSe2/Au忆阻器示意图[50]; (b) 器件的电学特性: 在低工作电流(100 nA)下, 器件的I-V曲线[50]; (c) 锥形氧空位通道在电压调控下形成和断裂的过程[50]; (d) Pd/WS2/Pt器件结构示意图[49]; (e) 文献中报道的不同的编程或SET电流的比较[49]
Figure 5. Oxygen vacancy effect: (a) Schematic of Ti/HfSexOy/HfSe2/Au memristor; (b) electrical characteristics of the device: I-V curves of the device at low operating current (100 nA) [50]; (c) the formation and rupture of conical oxygen vacancy channels under voltage regulation[50]; (d) schematic of the Pd/WS2/Pt device[49]; (e) comparison of various programs or SET currents reported in the literatures[49].
图 6 隧穿效应 (a) 基于MoS2的多端器件的示意图[55]; (b) 浮栅/h-BN/漏极的能带图[55]; (c) 基于MoS2的多端器件在Vds = 1 V的传输特性[55]; (d) 在不同Vds下的开关行为[55]; (e) 基于三端器件的突触示意图[55]; (f) 不同Vg下多端突触器件重复性增强和抑制行为的对数图[55]
Figure 6. Tunneling effect: (a) Schematic diagram of the MoS2-based multi-terminal device[55]; (b) band diagram of floating-gate/h-BN/drain[55]; (c) transmission characteristics of multi-terminal device based MoS2 at Vds = 1 V[55]; (d) switching behavior at different Vds[55]; (e) schematic diagram of a synapse based on a three-terminal device[55]; (f) logarithmic plots of repetitive potentiation and inhibitory behavior of multiterminal synaptic apparatus under different Vg[55].
图 7 电荷的捕获与释放 (a) 基于2D MoTe2的忆阻器结构示意图[53]; (b) 在Vg(–40 V→40 V→–40 V)扫描电压下器件的传输特性曲线(插图为在对数坐标下的I-V曲线)[53]; (c) 2D MoTe2的忆阻器工作机制示意图[53]; (d) 生物突触和基于sr-SiNx的人工突触器件的示意图; (e) 100个周期内增强(左)和抑制(右)周期性电导的变化[53]
Figure 7. Charge trapping and de-trapping effects: (a) Schematic diagram of the memristor structure based on 2D MoTe2[53]; (b) the transfer characteristic curve of the device under the scanning voltage of Vg (–40 V→40 V→–40 V) (the illustration is the same curve shown in logarithmic coordinates) [53]; (c) the working mechanism of the device[53]; (d) schematic illustration of biological synapses and sr-SiNx-based artificial synaptic device[53]; (e) the conductance periodic changes in excitation (left) and inhibition (right) over 100 cycles[53].
图 8 横向vdWs异质结 (a) 基于2D WSe2-WO3横向异质结构的器件示意图[129]; (b) 由Gate 1调节的电阻开关特性[129]; (c) WSe2-WO3横向异质结构的光学图像[129]; (d) Pd-WSe2-Pd(电极4和5)、Pd-WO3-Pd(电极1和2)和Pd-WSe2-WO3-Pd(电极3和4)的I-V特性曲线[129]; (e), (f) 开关原理的示意图, 其中红色圆圈代表质子[129]
Figure 8. Lateral vdWs heterostructure: (a) Schematic diagram of the device based on the 2D WSe2-WO3 lateral heterostructure[129]; (b) resistive switching characteristics regulated by Gate 1 voltage[129]; (c) optical image of WSe2-WO3 lateral heterostructure[129]; (d) I-V characteristic curves of Pd-WSe2-Pd (electrodes 4 and 5), Pd-WO3-Pd (electrodes 1 and 2) and Pd-WSe2-WO3-Pd (electrodes 3 and 4) [129]; (e), (f) schematic of the switching principle, where the red circles represent protons[129].
图 9 垂直vdWs异质结 (a) 基于MoS2–xOx/Gr异质结的器件示意图[130]; (b) 器件在不同温度下的开关曲线[130]; (c) 器件在340和160 ℃下的保持时间[130]
Figure 9. Vertical vdWs heterojunction: (a) Schematic diagram of the device based on MoS2–xOx/Gr heterojunction[130]; (b) switching curves of the device at different temperatures[130]; (c) retention time of device at 340 and 160 ℃ [130].
图 10 LIF模型神经元 (a) 平面器件Ag/MoS2/TiW 示意图[139]; (b) 器件在连续脉冲序列下的泄漏-集成-发射的电学行为[139]; (c) 器件在1 ms、电压为2.0 V的单脉冲下的易失性开关行为[139]; (d) 垂直器件Ag/MoS2/Au的结构示意图和光学图片[140]; (e) 上图为Ag/MoS2/Au人工神经元的电路图, 下图为神经元的连续输出电流尖峰[140]; (f) 上图为电路图节点B处的电压VB, 下图为负载电阻RL 两端的电压VRL[140]
Figure 10. LIF model neurons: (a) Schematic diagram of planar device Ag/MoS2/TiW[139]; (b) leakage-integration-emission electrical behavior of device under continuous pulse trains[139]; (c) volatile switching behavior of the device with a single pulse of 2.0 V at 1 ms[139]; (d) schematic diagram and optical picture of the vertical device Ag/MoS2/Au[140]; (e) the top picture is the circuit diagram of the Ag/MoS2/Au artificial neuron, and the picture below is the continuous output current spike of the neuron[140]; (f) the picture in the top panel shows the voltage VB at node B of the circuit diagram, and the picture in the bottom panel shows the voltage VRL across the load resistance RL[140].
图 11 H-H尖峰神经元 (a) 器件的光学图片示意图[141]; (b) 器件结构示意图[141]; (c) H-H模型神经元的电路等效图[141]; (d) H-H模型中gK的时间演变关系图[141]; (e) H-H 模型中gNa的时间演变关系图[141]; (f) GHeT神经元的完整电路图[141]; (g) 图(d)中的 GHeT神经元电路的前30 s的实验结果[141]
Figure 11. H-H spiking neurons: (a) Optical image of the device[141]; (b) the schematic of device structure[141]; (c) equivalent circuit diagram of H-H model neuron[141]; (d) time evolution diagram of gK in H-H model[141]; (e) time evolution diagram of gNa in H-H model[141]; (f) complete circuit diagram of a GHeT neuron[141]; (g) experimental results for the first 30 s of the GHeT neuron circuit in panel (d) [141]
图 12 LTSP (a) 人工突触器件示意图[42]; (b) 重复进行LTP和LTD操作, 一个周期是100个增强脉冲和随后的100个抑制脉冲. 左上图和右上图分别对应最初10个循环和最后10个循环的运行情况[42]; (c) 离子门控突触晶体管的示意图[149]; (d) 生物系统(上)和离子门控突触晶体管(下)中离子迁移和动态平衡过程[149]; (e) 一系列电压脉冲(5 V, 50 ms)施加到栅极(Vds = 0.5 V)时, 实现从STSP到LTSP的转换[149]; (f) 对基于WSe2的突触晶体管使用增强(1.2 V, 100 ms)和抑制(–0.4 V, 100 ms)脉冲信号, 间隔3 s, 显示出良好的线性、对称性和重复性[149]
Figure 12. LTSP: (a) Schematic diagram of artificial synapse[42]; (b) the LTP and LTD operations were repeated with a cycle of 100 enhancement pulses followed by 100 inhibition pulses; the upper left and upper right diagrams correspond to the operation of the first 10 cycles and the last 10 cycles, respectively[42]; (c) schematic of an ion-gated synaptic transistor[149]; (d) ion migration and dynamic equilibrium in biological systems (top) and ion-gated synaptic transistors (bottom)[149]; (e) when a series of voltage pulses (5 V, 50 ms) are applied to the gate (Vds = 0.5 V), the transition occurs from STSP to LTSP[149]; (f) by using excitatory (1.2 V, 100 ms) and inhibitory (–0.4 V, 100 ms) pulsed signals with 3 s intervals for WSe2-based synaptic transistors, the device shows good linearity, symmetry, and reproducibility[149].
图 14 STDP和SRDP (a) 四种STDP模型突触权重变化的示意图; (b) 典型的STDP模型. 突触前电流(兴奋性)和IPSC的相对时间前后影响突触权重产生LTP和LTD; (c) 典型的SRDP模型, 尖峰频率的大小带来的突触权重的变化
Figure 14. STDP and SRDP: (a) Schematic diagram of synaptic weight changes of the four STDP models; (b) typical STDP model. Influence synaptic weights to generate LTP and LTD on relative timing of presynaptic currents (excitatory) and IPSCs; (c) typical SRDP model; changes of synaptic weights caused by the magnitude of the spike frequency.
图 15 视觉识别 (a) 人体视觉系统的示意图[194]; (b) 基于ORRAM阵列的人工神经形态视觉系统, 以及用于图像识别的人工神经网络示意图[194]; (c) 人工神经形态视觉系统预处理之前(左)和之后(右)的图像示例[194]; (d) 有/无图像预处理的图像识别率比较[194]; (e) 在生物RC系统上执行的认知任务示意图[195]; (f) 由电和光输入刺激的多功能忆阻器阵列示意图; (g) 对语言符号的识别准确率[195]
Figure 15. Visual recognition: (a) Schematic diagram of the human visual system[194]; (b) artificial neuromorphic vision system based on ORRAM array, and artificial neural network for image recognition[194]; (c) images before (left) and after (right) preprocessing through an artificial neuromorphic vision system[194]; (d) comparison of image recognition rates with and without image preprocessing[194]; (e) schematic diagram of cognitive tasks performed on biological RC systems[195]; (f) illustration of a multifunctional memristor array stimulated by various electrical and optical inputs; (g) recognition accuracy of language sign[195].
图 16 声音定位与模式识别 (a) ITD和ILD的声音定位示意图[26]; (b) 电压扫描下焦耳热驱动的电导变化; (c) 两个连续脉冲刺激后的PPF和PPD指数与Δt的函数关系图[26]; (d) 基于ITD的声音定位的突触计算工作机制示意图; “CA”指图(a)所示的耳蜗, 蓝色的圆圈代表神经元, 水平虚线代表神经元放电的潜在阈值[26]; (e) 生物突触与vdWs混合突触器件的功能和结构比较[167]; (f) 基于三种人工神经网络的声学模式识别率, 并与SW-NN的识别率进行比较[167]
Figure 16. Sound localization and pattern recognition: (a) Schematic diagram of sound localization of ITD and ILD[26]; (b) joule heat driven conductivity change under the sweep voltage[26]; (c) the pulse intervals dependent PPF and PPD indexes stimulated by two consecutive pulses[26]; (d) schematic diagram of the synaptic computing of ITD-based sound localization; “CA” refers to the cochlea shown in panel (a); the blue circles represent neurons; horizontal dashed lines represent potential thresholds for neuronal firing[26]; (e) comparison of function and structure between biological synapses and vdWs hybrid synaptic devices[167]; (f) acoustic pattern recognition rates based on three artificial neural networks with compared results achieved by the SW-NN recognition rate[167].
图 17 触觉模拟 (a) 生物触觉神经系统[202]; (b) 带有离子凝胶门控晶体管的 PENG 示意图[202]; (c) 压电Gr人工触觉突触工作原理[202]; (d) PSC幅度与应变脉冲数的关系图[202]
Figure 17. Tactile mimicking: (a) Biological sensory nervous system[202]; (b) schematic diagram of a PENG with iongel-gated transistors[202]; (c) the working principle of piezoelectric Gr artificial sensory synapse[202]; (d) PSC amplitude shown as the function of strain-pulse number[202].
表 1 不同材料的人工突触器件性能对比
Table 1. Performance comparison of artificial synaptic devices based on different materials.
材料 突触可塑性 耐久性
(循环)保持性 功耗/能耗 刺激方式 文献 2D材料 MoS2 LTP, LTD, PPF, SRDP 100 >11 h 4.5 fJ 电 [166] h-BN/WSe2 LTP, LTD, STDP — — 66 fJ 光电 [167] SnSe LTP, LTD, PPF, STDP 230 >104 s 66 fJ 电 [44] MoTe2 LTP, LTD, PPF, STDP 570 >104 s — 电 [53] 氧化物材料 TiO2 LTP, LTD, PPF, STDP — — 26 pJ 电 [168] ZTO LTP, LTD, STDP — 104 s — 电 [169] IGZO LTP, LTD — — 160 pJ 光电 [170] In2O3 LTP, LTD, PPF, SRDP 20 — — 电 [171] 有机材料 C8-BTBT LTP, LTD 105 >3500 s <5 fJ 电 [177] PMMA LTP, LTD, PPF, SRDP, STDP — >103 s 10-8 W 电 [178] PVA PPF, LTP, LTD, LTM — 600 s — 光 [179] P(VDF-TrFE)
/P(VP-EDMAEMAES)LTP, LTD, PPF — — 75 pJ 电 [180] 钙钛矿材料 BaTiO3 STDP 105 108 s 600 pJ 电 [182] PdZr0.52Ti0.48O3 SRTP, LSTP — — 2.5 pJ 电 [183] BiFeO3 STDP — — 200 nW 电 [184] (CH3NH3)3Sb2Br9 LTP, LTD, STDP 300 104 s 117.9 fJ 电 [185] -
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