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[2].  A Novel Interface Database of Graphene Nanoribbon from Density Functional Theory.  arXiv:2311.18203. 

[3].  Graph Machine Learning Framework for Depicting Wavefunction on Interface.  Machine Learning: Science and Technology, Vol.4, No.4, 045037, 2023. 

[4].  Planar Weibull Quantum Circuit Genetic Algorithm with Strong Search Ability and its Implementatio....  Physica Scripta, 98, 125113,2023. 

[5].  A Dynamic Pruning Method on Multiple Sparse Structures in Deep Neural Networks.  IEEE ACCESS.  11.  38448-38457.  2023. 

[6].  A Novel Multiscale Simulation Framework for Low-dimensional Memristors.  Science China Physics, Mechanics & Astronomy.  66 (7).  276811.  2023. 

[7].  A General Quantum Minimum Searching Algorithm with High Success Rate and its Implementation.  Science China Physics, Mechanics & Astronomy.  66 (4).  240315.  2023. 

[8].  Graph representation based machine learning framework for predicting electronic band structures o....  Science China Materials.  (DOI: 10.1007/s40843-022-2103-9).  2022. 

[9].  A Multi-classification Hybrid Quantum Neural Network Using All-qubit Multi-observable Measurement....  Entropy.  (DOI: 10.3390/e24030394).  2022. 

[10].  Magnetic Tunneling Junctions Based on 2D CrI3 and CrBr3: Spin Filtering Effects and High Tunnel M....  Semiconductor Science and Technology.  37 (015006).  2022. 

[11].  The effect of Ag atoms diffusion into δ-phase CsPbI3-based memory device.  Microelectronic Engineering.  251 (11166).  2022. 

[12].  Steep-Slope Transistors Based on Chiral Graphene Nanoribbons with Intrinsic Cold Source.  IEEE Transactions on Electron Devices.  68 (8).  4123-4128.  2021. 

[13].  Machine learning method for tight-binding Hamiltonian parameterization from ab-initio band struct....  npj Computational Materials.  7 (11).  2021. 

[14].  Memristor-Based Image Enhancement: High Efficiency and Robustness.  IEEE Transactions on Electron Devices.  26 (2).  602-609.  2021. 

[15].  Ensemble Echo Network with Deep Architecture for Time-Series Modelling.  Neural Computing & Applications.  33 (10).  4997-5010.  2021. 

[16].  A Multilayer Neural Network Merging Image Preprocessing and Pattern Recognition by Integrating Di....  IEEE Transactions on Cognitive and Developmental Systems.  13 (3).  645-656.  2021. 

[17].  Reconstruction of the Symmetry between Sublattices: A Strategy to Improve the Transport Propertie....  Physical Chemistry Chemical Physics.  22.  18265-18271.  2020. 

[18].  Fully Memristive Spiking-Neuron Learning Framework and Its Applications on Pattern Recognition an....  Neurocomputing.  403.  80-87.  2020. 

[19].  Wave-function symmetry mechanism of quantum-well states in graphene nanoribbon heterojunctions.  Physical Review Applied.  12 (044018).  2019. 

[20].  SpikeCD: A Parameter-insensitive Spiking Neural Network with Clustering Degeneracy Strategy.  Neural Computing & Applications.  31 (8).  3933-3945.  2019. 

[21].  Acceleration of LSTM with Structured Pruning Method on FPGA.  IEEE Access.  7 (1).  62930-62937.  2019. 

[22].  Influence on Compact Memristors’ Stability on Machine Learning.  IEEE Access.  7 (1).  47472-47478.  2019. 

[23].  Interface Coupling as a Crucial Factor for Spatial Localization of Electronic States in a Heteroj....  Physical Review Applied.  11.  024026.  2019. 

[24].  Efficient Multispike Learning for Spiking Neural Networks Using Probability-Modulated Timing Meth....  IEEE Transactions on Neural Networks and Learning Systems.  30 (7).  1984-1997.  2019. 

[25].  A Hardware Friendly Unsupervised Memristive Neural Network with Weight Sharing Mechanism.  Neurocomputing.  332.  193-202.  2019. 

[26].  Strain engineering of chevron graphene nanoribbons.  Journal of Applied Physics.  125.  082501.  2018. 

[27].  A Transport Isolation by Orbital Hybridization Transformation toward Graphene Nanoribbon-based Na....  Nanotechnology.  29.  455704.  2018. 

[28].  Restraining Strategy of the Stone–Wales Defect Effect on Graphene Nanoribbon MOSFETs.  IEEE Electron Device Letters.  39 (7).  1092¬¬¬-1095.  2018. 

[29].  Activating Impurity Effect in Edge Nitrogen-doped Chevron Graphene Nanoribbons.  Journal of Physics Communications.  2 (4).  045028.  2018. 

[30].  Dielectric Engineering with the Environment Material in 2D Semiconductor Devices.  IEEE Journal of the Electron Devices Society.  6 (1).  325-331.  2018. 

[31].  A Versatile and Accurate Compact Model of Memristor with Equivalent Resistor Topology.  IEEE Electron Device Letters.  38 (10).  1367-1370.  2017. 

[32].  Highly Sensitive Bilayer Phosphorene Nanoribbon Pressure Sensor Based on the Energy Gap Modulatio....  IEEE Electron Device Letters.  38 (9).  1313-1316.  2017. 

[33].  Multi-valued Logic Design Methodology with Double Negative Differential Resistance Transistors.  IET Micro & Nano Letters.  12 (10).  738-743.  2017. 

[34].  Graphene Nanoribbon Tunnel Field-Effect Transistor Via Segmented Edge Saturation.  IEEE Transactions on Electron Devices.  64 (6).  2694-2701.  2017. 

[35].  Confined State Energies in AGNR Semiconductor-Semiconductor Heterostructure.  Physics Letters A.  381.  319-322.  2017. 

[36].  Scaling Effect of Phosphorene Nanoribbon - Uncovering the Origin of Asymmetric Current Transport.  Scientific Reports.  (DOI: 10.1038/srep38009).  2016. 

[37].  The Dual Effects of Gate Dielectric Constant in Tunnel FETs.  IEEE Journal of the Electron Devices Society.  4 (6).  445-450.  2016. 

[38].  Novel Strategy of Edge Saturation Hamiltonian for Graphene Nanoribbon Devices.  IEEE Transactions on Electron Devices.  63 (11).  4514-4520.  2016. 

[39].  Prior Knowledge Input Neural Network Method for GFET Description.  Journal of Computational Electronics.  15 (3).  911-918.  2016. 

[40].  Adaptive Digital Ridgelet Transform and its Application in Image Denoising.  Digital Signal Processing.  52.  45-54.  2016. 

[41].  Energy gap tunable graphene antidot nanoribbon MOSFET: A uniform multiscale analysis from band st....  Carbon.  101.  143-151.  2016. 

[42].  Negative differential resistance in graphene nanoribbon superlattice field-effect transistors.  IET Micro & Nano Letters.  10 (8).  400-403.  2015. 

[43].  An evaluation of fake fingerprint databases utilizing SVM classification.  Pattern Recognition Letters.  (DOI:10.1016/j.patrec.2015.03.015).  2015. 

[44].  Effects of Fin shape on sub-10nm FinFETs.  Journal of Computational Electronics.  14 (2).  515-523.  2015. 

[45].  SVM-based synthetic fingerprint discrimination algorithm and quantitative optimization strategy.  PLOS ONE.  9 (10).  e111099.  2014. 

[46].  A novel barrier controlled tunnel FET.  IEEE Electron Device Letters.  35 (7).  798-800.  2014. 

[47].  常胜 Effects of vacancy defects on graphene nanoribbon field effect transistor.  MICRO & NANO LETTERS.  8 (11).  2013.