新型存储器、传感器器件物理与集成应用；存内计算；类脑计算；CMOS PI/E IC流片

招收博士后和博士/硕士研究生 (凝聚态物理、微电子学与固体电子学、微电子科学与技术、电子科学与技术等专业)

自旋电子器件物理与集成应用

神经形态计算器件与集成技术

高性能端侧感存算器件与系统

1. 国家工业级集成电路标准委员会委员

2. 国家科技专家库 评审专家

3. 工信部、中电集团、科技部、基金委项目评审专家

4. 中关村管委会项目专员

5. 北京智芯微电子科技有限公司存储器资深顾问

6. Journal of Low Power Electronics and Applications Section Editor-in-Chief

7. The World's Top 2% Scientists (2022) https://elsevier.digitalcommonsdata.com/datasets/btchxktzyw/4

8. The World's Top 2% Scientists (2023) https://elsevier.digitalcommonsdata.com/datasets/btchxktzyw/6

    https://jokergoooo.shinyapps.io/top2pct_scientists/

9. 国家重点研发计划专项评审专家

1. Three-state spintronic device, memory cell, memory array and read-write circuit, US Patent 18/261,716
2. Multi-resistance-state spintronic device, read-write circuit, and in-memory boolean logic operator, US Patent 18/259,747
3. Spintronic device, memory cell, memory array and read and write circuit, US Patent 18/251,699
4. All-electrically-controlled spintronic neuron device, neuron circuit and neural network, US Patent 18/249,805
5. Self-reference storage structure and storage and calculation integrated circuit, US Patent 18/247,446
6. Reconfigurable puf device based on fully electric field-controlled domain wall motion, US Patent 18/061,953
7. SOT-Driven Field-Free Switching MRAM and Array Thereof, US Patent 18/042,249
8. Spin orbit torque magnetic random access memory cell, spin orbit torque magnetic random access memory array, and method for calculating hamming distance, US Patent 18/005,756
9. Magnetoresistive device, method for changing resistance state thereof, and synapse learning module, US Patent 18/003,913
10. Spin orbit torque magnetic random access memory cell, memory array, and memory, US Patent 18/003,038
11. Two-dimensional Material-based Selector, Memory Unit, Array, and Method of Operating The Same, US Patent 17/998,782
12. Magnetoresistive memory cell, write control method and memory computing module, US Patent 17/821,783
13. Spintronic Device, SOT-MRAM Storage Cell, Storage Array and In-Memory Computing Circuit, US Patent 17/594,684
14. Complementary Contact Bar, DTI & Poly Salicide structure to enhance QE with minimized cross-talk in BSI, US Patent 16/283,895
15. Resistive Switching Transition Oxide: Towards High Performance Hybrid Bond Media for BSI Application, US Patent 15/834,519
16. Filter-Free, Highly Selective and Sensitive Multispectral Imaging Sensor Pixel, US Patent UMCD20180400
17. Size-scaled and location-controlled growth technique for vertically aligned nanowire arrays (CN102531031A)
18. 影像传感器, 发明, 授权, 第 2 发明人, 专利号:  CN110120396B (授权)
19. 一种自参考存储结构和存算一体电路 发明, 第1发明人, 专利号: CN202011077197.0 (授权)
20. 基于磁畴壁驱动型磁隧道结的激活函数发生器及制备方法 发明, 第1发明人, 专利号: CN202110299800.8 (授权)
21. 忆阻器、汉明距离计算方法及存算一体集成应用 发明, 第1发明人, 专利号: CN202110457874.X (授权)
22. 自旋轨道矩磁随机存储单元、阵列及汉明距离计算方法 发明, 第1发明人, 专利号: CN202110084777.0 (授权)
23. 磁电阻器件以及改变其阻态的方法、突触学习模块 发明, 第1发明人, 专利号: CN202011637866.5 (授权)
24. 三态自旋电子器件、存储单元、存储阵列及读写电路 发明, 第1发明人, 专利号: CN202110084765.8 (授权)
25. 多阻态自旋电子器件、读写电路及存内布尔逻辑运算器 发明, 第1发明人, 专利号: CN202011643048.6 (授权)
26. 全电控自旋纳米振荡器神经元器件 发明, 第1发明人, 专利号: CN202110754795.5 (授权)
27. 一种基于磁隧道结阵列图像特征提取方法和装置 发明, 第1发明人, 专利号: CN202311114729.7
28. 磁性薄膜、自旋电子器件、存储池阵列及存储池神经网络 发明, 第1发明人, 专利号: CN202310562209.6
29. 自旋电子器件和递归神经网络 发明, 第1发明人, 专利号: CN202310845125.3
30. 一种自旋纳米振荡器的控制方法及自旋纳米振荡器 发明, 第1发明人, 专利号: CN202310610815.0
31. 磁阻存储器单元、制备方法、阵列电路和二值神经网络芯片 发明, 第1发明人, 专利号: CN202310328734.1
32. 自旋电子器件、电路单元、计算网络、算子以及神经网络 发明, 第1发明人, 专利号: CN202310339778.4
33. 基于全电场控制磁畴壁运动的可重构PUF器件 发明, 第1发明人, 专利号: CN202111216656.3
34. 自旋电子器件、阵列电路及递归神经网络的优化方法 发明, 第1发明人, 专利号: CN202211081304.6
35. 一种基于自旋波单元的存内计算阵列结构及其控制方法 发明, 第1发明人, 专利号: CN202211020617.0
36. 存储单元及其制备方法、存储器和信息存储方法 发明, 第1发明人, 专利号: CN202210822939.0
37. 一种基于磁隧道结的神经元器件及神经网络装置 发明, 第1发明人, 专利号: CN202210381021.7
38. 一种斯格明子晶体管及斯格明子晶体管控制方法 发明, 第1发明人, 专利号: CN202210296254.7
39. 一种SOT-MRAM存储单元、存储阵列、存储器及操作方法 发明, 第1发明人, 专利号: CN202210200790.2
40. 基于离子门调控的可重构神经元器件及其制备方法 发明, 第2发明人, 专利号: CN202210205501.8
41. 自旋电子器件、存储单元、存储阵列和读写电路 发明, 第1发明人, 专利号: CN202111195175.9
42. 一种磁阻存储器单元、写控制方法及存算模块 发明, 第1发明人, 专利号: CN202110922939.3
43. 一种基于自旋轨道矩的神经元器件 发明, 第1发明人, 专利号: CN202110840235.1
44. 全电控自旋电子神经元器件、神经元电路和神经网络 发明, 第1发明人, 专利号: CN202110537062.6
45. 自旋电子器件、SOT-MRAM存储单元、存储阵列以及存算一体电路 发明, 第1发明人, 专利号: CN202010704837.X
46. 无外磁场定向自旋翻转的SOT-MRAM及阵列 发明, 第1发明人, 专利号: CN202010846250.2
47. 自旋轨道扭矩磁随机存储单元、存储阵列及存储器 发明, 第1发明人, 专利号: CN202010594037.7
48. 二维材料基选通器、存储器单元、阵列及其操作方法 发明, 第2发明人, 专利号: CN202010416854.3

1. 入选 2022、2023年度全球顶尖 2%科学家榜单
2. 合作入选2022年度中国芯片科学十大进展
3. 北京市朝阳科技领军人才 2023
4. 联华电子核心技术最佳专案认证奖
5. 国家海外高层次人才
6. 格罗方德项目优秀奖
7. 澳大利亚新南威尔士 Vice-Chancellor Fellowship 基金奖
8. 美国宾夕法尼亚大学 Research Scientist Fellowship
9. 新加披集选区义工奖
10. 新加坡千禧基金学者
11. 中国国家优秀留学奖

https://scholar.google.com/citations?hl=en&user=jxbQ1CgAAAAJ

Citations:  9058 (All)  3822 (Since 2019)

h-index:  51     (All)   36    (Since 2019)

i10-index: 114    (All)   86    (Since 2019)

23 Publications with Citations > 100

1. Magnetic tunnel junction-based synapses and neurons for all-spin neuromorphic hardware, Nature Communications, In Press (2024) 通讯作者

2. Asymmetric magnetization switching and programmable complete Boolean logic enabled by long-range intralayer Dzyaloshinskii-Moriya interaction, Nature Communications, 15, 2978 (2024) 主要合作者

3. 3D dual-mode tactile sensor with decoupled temperature and pressure sensing: Toward biological skins for wearable devices and smart robotics, Sensors and Actuators B: Chemical, 404, 135255 (2024) 通讯作者

4. Anti-friction gold-based stretchable electronics enabled by interfacial diffusion-induced cohesion, Nature Communications, 15, 1116 (2024) 主要合作者

5. Enhanced gate biasing resilience in asymmetric and double trench MOSFETs towards generalized highly reliable power electronics, Microelectronics Reliability 154, 115342 (2024) 通讯作者

6. Tilted magnetic anisotropy-tailored spin torque nano-oscillators for neuromorphic computing, Applied Physics Letters, 123, 204101 (2023). https://doi.org/10.1063/5.0175446 通讯作者

7. Spintronic leaky-integrate-fire spiking neurons with self-reset and winner-takes-all for neuromorphic computing, Nature Communications 14, 1068 (2023). doi.org/10.1038/s41467-023-36728-1 (Editors’ Highlights 编辑亮点推荐 Featured Article; 《中科院之声》特别报道) 通讯作者 Cited: 25

8. Schottky Barrier Control of Self-Polarization for a Colossal Ferroelectric Resistive Switching, ACS Nano 2023, 17, 13, 12347–12357 (2023) 通讯作者

9. Field-free domain wall spin torque nano-oscillators with multimodal real-time modulation and high-quality factor, Materials Today Electronics, 06, 100065 (2023) doi.org/10.1016/j.mtelec.2023.100065 通讯作者

10. Gate-Tunable Anisotropic Oxygen Ion Migration in SrCoOx: Toward Emerging Oxide-Based Artificial Synapses, Advanced Intelligent Systems, 2200287 (2023) 主要合作者

11. Implementation of Highly Reliable and Energy-Efficient Non-Volatile In-Memory Computing Using Multi-State Domain Wall Spin-Orbit Torque Device, Advanced Intelligent Systems 2200028 (2022) 封面 https://doi.org/10.1002/aisy.202200028 通讯作者 Cited: 19

12. A Computing-in-memory macro with three-dimensional resistive random-access memory, Nature Electronics 5, 469–477 (2022) https://doi.org/10.1038/s41928-022-00795 主要合作者 Cited: 53

13. Tailoring skyrmion motion dynamics via magnetoelectric coupling: towards highly energy-efficient and reliable non-volatile memory applications, Journal of Applied Physics 132, 084902 (2022) (Editor's Pick) 通讯作者

14. Synergy of spin-orbit torque and built-in field in magnetic tunnel junctions with tilted magnetic anisotropy: towards tunable and reliable spintronic neurons, Advanced Science 2203006 (2022) 封面 DOI: 10.1002/advs.202203006 通讯作者 Cited: 12

15. 3T2M Canted-Type x SOT-MRAM: Field-Free, High-Energy-Efficiency, and High-Read-Margin Memory toward Cache Applications, Journal of Science: Advanced Materials and Devices, https://doi.org/10.1016/j.jsamd.2022.100508 (2022) 通讯作者

16. All-Electrical Control of Compact SOT-MRAM: Toward Highly Efficient and Reliable Non-Volatile In-Memory Computing, Micromachines 13, 319 (2022) 通讯作者 Cited: 16

17. Area-Efficient 1T-2D-2MTJ SOT-MRAM Cell for High Read Performance, IEEE Transactions on Circuits and Systems II: Express Briefs, 2022, doi: 10.1109/TCSII.2022.3218042 通讯作者

18. Reflow Soldering Capability Improvement by Utilizing TaN Interfacial Layer in 1Mbit RRAM Chip, Micromachines 13, 567, (2022) 主要合作者

19. Biologically emulated flexible sensors with high sensitivity and low hysteresis: towards electronic skin to a sense of touch, Small, DOI: 10.1002/smll.202203044 (2022) 通讯作者 Cited: 57

20. Bioinspired Dual‐Mode Stretchable Strain Sensor Based on Magnetic Nanocomposites for Strain/Magnetic Discrimination, Small, 2205316 (2022) 通讯作者 Cited: 43

21. Highly Stretchable, Responsive Flexible Dual-Mode Magnetic Strain Sensor, Advanced Materials Technologies, 2201439 (2022) 通讯作者Cited: 21 

22. Implementation of Highly Reliable and Energy Efficient in-Memory Hamming Distance Computations in 1 Kb 1-Transistor-1-Memristor Arrays, Advanced Materials Technologies 2100745 (2021) Cited: 19 通讯作者 

23. Highly Sensitive and Wide-Range Flexible Bionic Tactile Sensors, ACS Applied Nano Materials 5, 8, 11028–11036 (2022) Cited: 47 通讯作者 

24. Reducing Dzyaloshinskii-Moriya interaction and field-free spin-orbit torque switching in synthetic antiferromagnets, Nature Communications 12 (1), 3113 (2021)  Cited: 55 主要合作者

25. Hybrid memristor-CMOS neurons for in-situ learning in fully hardware memristive spiking neural networks, Science Bulletin 66 (16), 1624-1633 (2021) Cited: 62 主要合作者

26. Development of magnetic imprinted heterojunction nanoreactors: 3-Dimensional specific recognition for selectively photocatalyzing danofloxacin mesylate, Applied Catalysis B: Environmental 268, 118433 (2020) Cited: 129 通讯作者

27. Prospect of Spin-Orbitronic Devices and Their Applications, iScience 23, 101614 (2020) Cited: 80 共一作者

28. Effect of chemical composition and Cu addition on crystallization and magnetic characteristics of FeZrB alloys, Physics Letters A 384 (26), 126640 (2020) 通讯作者

29. Highly sensitive capacitive flexible 3D-force tactile sensors for robotic grasping and manipulation, Journal of Physics D: Applied Physics 53 (44), 445109 (2020) Cited: 42 通讯作者

30. Composition Regulation Triggered Multicolor Emissions for a Highly Sensitive Thermometer, Industrial & Engineering Chemistry Research 59 (21), 9989-9996 (2020) Cited: 18 通讯作者

31. Rapid-response, low detection limit, and high-sensitivity capacitive flexible tactile sensor based on three-dimensional porous dielectric layer for wearable electronic skin, ACS Applied Materials & Interfaces 11 (43), 40716-40725 (2019) Cited: 188 通讯作者

32. Enhanced thermal conductivity and lower density composites with brick-wall microstructure based on highly oriented graphite nanoplatelet: towards manufacturable cooling, Nanotechnology 30 (24), 245204 (2019) Cited: 40 通讯作者

33. Magnetic Hierarchical Photocatalytic Nanoreactors: Toward Highly Selective Cd²⁺ Removal with Secondary Pollution Free Tetracycline Degradation, ACS Applied Nano Materials 2 (3), 1664-1674 (2019) Cited: 51 通讯作者

34. Sheath–core fiber strain sensors driven by in-situ crack and elastic effects in graphite nanoplate composites, ACS Applied Nano Materials 2 (2), 750-759 (2019) Cited: 42 通讯作者

35. Magnetic functional heterojunction reactors with 3D specific recognition for selective photocatalysis and synergistic photodegradation in binary antibiotic solutions, Journal of Materials Chemistry A 7 (23), 13986-14000 (2019) Cited: 150 通讯作者

36. Tailoring highly flexible hybrid supercapacitors developed by graphite nanoplatelets-based film: toward integrated wearable energy platform building blocks, ACS Applied Energy Materials 1 (10), 5336-5346 (2018) Cited: 20 通讯作者

37. Rare-earth doping engineering in nanostructured oxide: a new type of eco-friendly photocatalyst with enhanced photocatalytic characteristics, Applied Physics A 124 (9), 1-12 (2018) Cited: 11 通讯作者

38. Enhanced catalytic reduction driven by Fe₃O₄-Au magnetic nanocomposite interface engineering: from facile preparation to recyclable application, Nanomaterials 8 (5), 353 (2018) Cited: 55 通讯作者

39. Highly Efficient, Low-Cost, and Magnetically Recoverable FePt–Ag Nanocatalysts: Towards Green Reduction of Organic Dyes, Nanomaterials 8 (5), 329 (2018) Cited: 25 通讯作者

40. Highly Flexible and Sensitive Wearable E-Skin Based on Nanocomposite Films in Mass Industry Production Available, ACS Applied Materials & Interfaces 9, 38745 (2017) Cited: 99 通讯作者

41. Effects of amount of benzyl ether and reaction time on the shape and magnetic properties of Fe₃O₄ nanocrystals, Powder Technology 319, 53-59 (2017) Cited: 37 通讯作者

42. Rational synthesis and tailored optical and magnetic characteristics of Fe₃O₄–Au composite nanoparticles, Journal of Materials Science 52 (17), 10163-10174 (2017) Cited: 32 通讯作者

43. Development of ZnFe₂O₄@ CdS Core–Shell Nanocomposites for Enhanced Visible-Light Photocatalytic Degradation of Tetracycline, Nanoscience and Nanotechnology Letters 9 (7), 989-997 (2017) Cited: 10 通讯作者

44. Formation Mechanism of Strontium Hexaferrite Compounds by Complementary Structure and Thermogravimetry Investigations, Nanoscience and Nanotechnology Letters 9 (4), 567-572 (2017)  通讯作者

45. Blue Non-Doped Organic Light Emitting Diodes Based on a Novel Donor–Acceptor Molecule, Nanoscience and Nanotechnology Letters 9 (3), 247-251 (2017) 通讯作者

46. High Performance Yellow Green Organic Light-Emitting Devices Based on Ir(ppy)3, Nanoscience and Nanotechnology Letters 7 (10), 806-810 (2015) 通讯作者

47. Doping Concentration of Fluorescent Dyes on the Properties of Yellow Organic Electroluminescent Devices, Nanoscience and Nanotechnology Letters 7 (8), 661-664 (2015)  通讯作者

48. Tailoring surface phase transition and magnetic behaviors in BiFeO₃ via doping engineering, Scientific Reports 5, 9128 (2015) Cited: 47 共一作者

49. Tailoring photoluminescence in strontium aluminate phosphors using fluxing agent and activators: Rational synthesis via a facile microwave-assisted method, Materials Science in Semiconductor Processing 27, 1007-1012 (2014) 通讯作者

50. Positive magnetoresistance in ferromagnetic Nd-doped In₂O₃ thin films grown by pulse laser deposition, Applied Physics Letters 104 (20), 202411 (2014) Cited: 61 通讯作者 第一作者

51. Chemically strengthened protection glasses for the applications of space solar cells, AIP Advances 4 (4), 047133 (2014) Cited: 10 通讯作者

52. Ferromagnetic (Mn, N)-codoped oxide nanopillars array: Experimental and computational insights, Applied Physics Letters 104 (2), 022412 (2014) Cited: 89 通讯作者

53. Tailoring the coercivity in ferromagnetic oxide thin films by 3d and 4f elements codoping, Applied Physics Letters 104 (1), 012405 (2014) Cited: 77 通讯作者

54. Hybrid CuO/SnO₂ nanocomposites: Towards cost-effective and high performance binder free lithium ion batteries anode materials, Applied Physics Letters 105 (1), 43905 (2014) Cited: 57 第一作者

55. Emergent ferromagnetism in zinc oxide/Al₂O₃ core-shell nanowires: Towards oxide spinterfaces, Applied Physics Letters 103 (2), 022402 (2013) Cited: 73 通讯作者 第一作者

56. Robust room-temperature ferromagnetism with giant anisotropy in Nd-doped oxide nanowire arrays, Nano Letters 12 (8), 3994-4000 (2012) Cited: 189 共一作者

57. High sensitivity low field magnetically gated resistive switching in CoFe₂O₄/La_0.66Sr_0.34MnO₃ heterostructure, Applied Physics Letters 100 (17), 172412 (2012) Cited: 47 共一作者

58. Defects-mediated energy transfer in red-light-emitting Eu-doped oxide nanowire arrays, The Journal of Physical Chemistry C 115 (46), 22729-22735 (2011) Cited: 171 共一作者

59. Structural characteristics, low threshold ultraviolet lasing and ultrafast carrier dynamics in high crystalline oxide nanowire arrays, Chemical Physics Letters 515 (1-3), 132-136 (2011) Cited: 22  第一作者

60. Carrier and exciton spin dynamics in Cu-doped oxide nanowires, IEEE Photonic Society 24th Annual Meeting, 246-247 (2011)   第一作者

61. Defect-induced magnetism in undoped wide band gap oxides: Zinc vacancies in oxide as an example, AIP Advances 1 (2), 022152 (2011) Cited: 196  第一作者

62. Charge transfer dynamics in Cu-doped oxide nanowires, Applied Physics Letters 98 (10), 102105 (2011) Cited: 69  第一作者

63. Structural and electrical characteristics of high quality (100) orientated- thin films grown by radio-frequency magnetron sputtering, Journal of Applied Physics 108 (8), 083710 (2010) Cited: 41  第一作者

64. Dependence of energy transfer and photoluminescence on tailored defects in Eu-doped oxide nanosheets-based microflowers, Journal of Alloys and Compounds 504 (1), 22-26 (2010) Cited: 72 共一作者

65. Ultrathin single-crystal oxide nanobelts: Ag-catalyzed growth and field emission property, Nanotechnology 21 (25), 255701 (2010) Cited: 92  第一作者

66. Correlated ferromagnetism and photoluminescence in undoped oxide nanowires, Applied Physics Letters 96 (11), 112511 (2010) Cited: 259  第一作者

67. Bound magnetic polarons induced ferromagnetism in transition-metal-doped oxide nanostructures, 2010 3rd International Nanoelectronics Conference (INEC), 1120-1121 (2010) 第一作者

68. Strong correlation between ferromagnetism and oxygen deficiency in Cr-doped nanostructures, Physical Review B 79 (17), 174406 (2009) Cited: 177  第一作者

69. Comparative study of room‐temperature ferromagnetism in Cu‐doped oxide nanowires enhanced by structural inhomogeneity, Advanced Materials 20 (18), 3521-3527 (2008) Cited: 300 第一作者

70. Effect of annealing on conductivity behavior of undoped zinc oxide prepared by rf magnetron sputtering, Journal of Alloys and Compounds 457 (1-2), 36-41 (2008) Cited: 116  第一作者

71. Low-temperature processed highly efficient hole transport layer free carbon-based planar perovskite solar cells with SnO₂ quantum dot electron transport layer, Materials Today Physics 13, 100204 (2020) Cited: 39 主要合作者

72. Interface Engineering via Sputtered Oxygenated CdS:O Window Layer for Highly Efficient Sb₂Se₃ Thin‐Film Solar Cells with Efficiency Above 7%, Solar RRL 3 (10), 1900225 (2019) Cited: 49 主要合作者

73. Local mechanical and electrical behavior in CdTe thin film solar cells revealed by scanning probe microscopy, AIP Advances 9 (8), 085108 (2019) Cited: 3 主要合作者

74. Improved stability and efficiency of CdSe/Sb2Se3 thin-film solar cells, Solar Energy 188, 586-592 (2019) Cited: 37 主要合作者

75. Interfacial engineering of oxygenated chemical bath–deposited CdS window layer for highly efficient Sb2Se3 thin-film solar cells, Materials Today Physics 10, 100125 (2019) Cited: 38 主要合作者

76. Establishment and experimental verification of the photoresist model considering interface slip between photoresist and concave spherical substrate, AIP Advances 5 (7), 077103 (2015) Cited: 4 主要合作者

77. Ferromagnetism and crossover of positive magnetoresistance to negative magnetoresistance in Na-doped oxide, Chemistry of Materials 27 (4), 1285-1291 (2015) Cited: 41 主要合作者

78. Zn vacancy induced ferromagnetism in K doped oxide, Journal of Materials Chemistry C 3 (45), 11953-11958 (2015) Cited: 45 主要合作者

79. Ferromagnetic ordering in Mn-doped oxide nanoparticles, Nanoscale Research Letters 9 (1), 1-8 (2014) Cited: 65 主要合作者

80. Tailoring characteristic thermal stability of Ni-Au binary nanocrystals via structure and composition engineering: theoretical insights into structural evolution and atomic, AIP Advances 4 (11), 117132 (2014) Cited: 3 主要合作者

81. Low temperature dependent ferroelectric resistive switching in epitaxial BiFeO₃ films, Applied Physics Letters 104 (13), 132904 (2014) Cited: 36 主要合作者

82. Pre-lithiation of onion-like carbon/MoS₂ nano-urchin anodes for high-performance rechargeable lithium ion batteries, Nanoscale 6 (15), 8884-8890 (2014) Cited: 105 主要合作者

83. Fabrication and characterization of P–N dual acceptor doped p-type oxide thin films, Applied Surface Science 287, 484-489 (2013) Cited: 35 主要合作者

84. Competition of shape and interaction patchiness for self-assembling nanoplates, Nature Chemistry 5 (6), 466-473 (2013) Cited: 324 主要合作者

85. Effects of (P, N) dual acceptor doping on band gap and p-type conduction behavior of oxide films, Journal of Applied Physics 113 (13), 133101 (2013) Cited: 35 主要合作者

86. Origin of green emission and charge trapping dynamics in oxide nanowires, Physical Review B 87 (11), 115309 (2013) Cited: 76 主要合作者

87. Engineering catalytic contacts and thermal stability: gold/iron oxide binary nanocrystal superlattices for CO oxidation, Journal of The American Chemical Society 135 (4), 1499-1505 (2013) Cited: 136 主要合作者

88. Orientation-dependent surface potential behavior in Nb-doped BiFeO₃, Applied Physics Letters 100 (17), 172901 (2012) Cited: 15 主要合作者

89. Improved size-tunable synthesis of monodisperse gold nanorods through the use of aromatic additives, ACS Nano 6 (3), 2804-2817 (2012) Cited: 900 主要合作者

90. Polaronic transport and magnetism in Ag-doped oxide, Applied Physics Letters 99 (22), 222511 (2011) Cited: 79 主要合作者

91. Evidence of cation vacancy induced room temperature ferromagnetism in Li-N codoped oxide thin films, Applied Physics Letters 99 (18), 182503 (2011) Cited: 53 主要合作者

92. Ferromagnetic interaction between Cu ions in the bulk region of Cu-doped oxide nanowires, Physical Review B 84 (15), 153203 (2011) Cited: 55 主要合作者

93. Sb doping behavior and its effect on crystal structure, conductivity and photoluminescence of oxide film in depositing and annealing processes, Journal of Alloys and Compounds 509 (17), 5426-5430 (2011) Cited: 45 主要合作者

94. Metal-layer-assisted coalescence of Au nanoparticles and its effect on diameter control in vapor-liquid-solid growth of oxide nanowires, Physical Review B 83 (4), 045403 (2011) Cited: 34 主要合作者

95. CrSi₂ Hexagonal Nanowebs, Journal of the American Chemical Society 132 (45), 15875-15877 (2010) Cited: 40 主要合作者

96. Rayleigh-instability-driven simultaneous morphological and compositional transformation from Co nanowires to CoO octahedra, Applied Physics Letters 97 (20), 203112 (2010) Cited: 49 主要合作者

97. Tuning ferromagnetism in  thin films by band gap and defect engineering, Applied Physics Letters 97 (10), 102506 (2010) Cited: 105 主要合作者

98. A template and catalyst-free metal-etching-oxidation method to synthesize aligned oxide nanowire arrays: NiO as an example, ACS Nano 4 (8), 4785-4791 (2010) Cited: 49 主要合作者

99. Shape-controlled fabrication of micro/nanoscale triangle, square, wire-like, and hexagon pits on silicon substrates induced by anisotropic diffusion and silicide sublimation, ACS Nano 4 (5), 2901-2909 (2010) Cited: 23 主要合作者

100. Electrode dependence of resistive switching in Mn-doped oxide: Filamentary versus interfacial mechanisms, Applied Physics Letters 96 (19), 192113 (2010) Cited: 202 主要合作者

101. Ferromagnetism in dilute magnetic semiconductors through defect engineering: Li-doped oxide, Physical Review Letters 104 (13), 137201 (2010) Cited: 495 主要合作者

102. Photoluminescence characteristics of high quality oxide nanowires and its enhancement by polymer covering, Applied Physics Letters 96 (2), 023111 (2010) Cited: 161 主要合作者

103. P-type electrical, photoconductive, and anomalous ferromagnetic properties of  nanowires, Applied Physics Letters 94 (11), 113106 (2009) Cited: 127 主要合作者

104. Ferroelectric transistors with nanowire channel: toward nonvolatile memory applications, ACS Nano 3 (3), 700-706 (2009) Cited: 103 主要合作者

105. Fabrication and properties of B–N codoped p-type oxide thin films, Journal of Physics D: Applied Physics 42 (6), 065101 (2009) Cited: 38 主要合作者

106. Tailoring the photoluminescence of oxide nanowires using Au nanoparticles, Nanotechnology 19 (43), 435711 (2008) Cited: 183 主要合作者

107. Cu-doped oxide nanoneedles and nanonails: morphological evolution and physical properties, The Journal of Physical Chemistry C 112 (26), 9579-9585 (2008) Cited: 245 主要合作者

108. Effects of nitrogen doping and illumination on lattice constants and conductivity behavior of zinc oxide grown by magnetron sputtering, Journal of Applied Physics 99 (12), 123510 (2006) Cited: 86 主要合作者

• Dynamic characteristics and operation mechanism of new type spin-orbit torque-based artificial synapses, PI, NNSFC Project, 2024-2027
• New edge-terminal in-memory sensing and computing devices and integrated chip system, PI, National Key T&D Program, 2022-2025
• Emerging integration of magnetic memory under full electric field control, PI, National Strategic Priority Project, 2021-2024
• Research on high-performance in-memory computing and integrated devices, PI, Ministry Key Project, 2020-2023
• High-Performance Spintronic Materials and Novel Magnetic Memory, Co-PI, Ministry Project, 2019-2022
• Non-volatile Memory Device Physics and Integration Technology, Co-PI, National Key Program, 2019-2022

Semiconductor Manufacturing International Corporation

北京智芯微电子科技有限公司

GlobalFoundries

United Microelectronics Corporation

BOE Technology Group

美国加州大学伯克利分校

清华大学

中国科学技术大学

中国科学院物理研究所

香港理工大学

复旦大学

北京航空航天大学

华中科技大学

美国宾夕法尼亚大学

澳大利亚新南威尔士大学

美国阿拉巴马大学

美国亚利桑那州立大学

美国亚利桑那大学