2024

[1]   S. J. Zhang, M. Fang, F. Wang, L. Wen*, Q. Wang, J. Dai, P. B. Gui, X. G. Ren, Z. L. Chen, W. Zeng, Z.X. Huang, Y. Yue*, S. L. Wang*, A novel layered ternary metal chalcogenide Bi2Te2Se as a high-performance cathode for aqueous zinc ion batteries, Chemical Engineering Journal, 2024, 496, 153980. 15 September. 2024. DOI: 10.1016/j.cej.2024.153980.

[2]   Z.L. Qiao, Q. Chen*, Q. R. Yang, Q. H. Wang, W. Wang, X. G. Ren, Z. X. Huang, L. X. Yang, Y.S. Li, A Compact Dual-polarized Solar Cell Phased Array Antenna, IEEE Antennas and Wireless Propagation Letters. 2024. 12 June 2024. DOI:10.1109/LAWP.2024.3413350

[3]   G. Wang*, Y. F. Hu, H. Yan, X. G. Ren, L.X. Yang, Z. X. Huang, X. L. Wu, Effects of F− substitution on crystal structure, band characteristics and microwave dielectric properties of Li3Mg2NbO6 ceramics for high frequency applications. Ceramics International, 2024, 50(10), 17097-17105. 15 May 2024. DOI:10.1016/j.ceramint.2024.02.186

[4]   K. K. Niu*, W. K. Zhang, M. Q. Li, X. G. Ren, Y. S. Li, Z. X. Huang*, B. Wu, X. L. Wu, Atef Z Elsherbeni, Transient Electromagnetic-Thermal Co-Simulation of Microwave/RF Integrated Circuits by the HIE-FDTD Method, IEEE Transactions on Microwave Theory and Techniques, 2024. 14 March 2024. DOI: 10.1109/TMTT.2024.3373767

[5]   Q. Chen*, Z. L. Qiao, J. L. Lv, Y. Ye, X. G. Ren, W. Wang, Z. X. Huang, L. X. Yang, Y. S. Li, A programmable solar‐powered radio frequency transmitter, Microwave and Optical Technology Letters, 2024, 66(3), e34101. 03 March 2024. DOI: 10.1002/mop.34101

 

2023

[6]   K. K. Niu*, Z. J. Xiao, G. D. Xie, X. G. Ren, Y. S. Li, Z. X. Huang*, X. L. Wu, Atef Z Elsherbeni, A Stochastic FDTD Algorithm for Uncertainty Quantification of Electromagnetic-Thermal Simulation, IEEE Transactions on Microwave Theory and Techniques, 2024, 72(7), 3935-3946, 22 December 2023. DOI: 10.1109/TMTT.2023.3342630.

[7]   G. C. Zhu, K. K. Niu*, M. Q. Li, Y.S. Li, X. G. Ren, G. D. Xie, Z. X. Huang, X. L. Wu, Atef Z Elsherbeni, High-order ME-CFS-PML implementations for terminating the FDTD domain composed of arbitrary media, IEEE Transactions on Microwave Theory and Techniques, 2023, 72(4), 2414–2426, 03 October 2023. DOI: 10.1109/TMTT.2023.3315837.

[8]   C. Xie*, Y. Wang, Z. S. Xia, Y. Cheng, X.S. Cui, S. J. Xu, X. G. Ren*, W. H. Yang, Z. X. Huang*, High-Performance Broadband Flexible Photodetectors Based on Ti3C2Tx MXene/Pyramidal Thin Si Heterostructures with Light Trapping Effect for Heart Rate Detection. Advanced Materials Technologies, 2023, (8)24, 2301232. DOI: 10.1002/admt.202301232. 16 October 2023

[9]   D. W. D. Liu*, Z. L. Chen*, Z. Huang, Q. Wu, Y. G. Song, J. F. Yao, H. Zhang, S. Y. Wei, L. P. Yang*, J. X. Chen, W. L. Shao, L.L. Chu, Y. H. Li, P. B. Gui, X. G. Ren, W. Zeng*, G. J. Fang. In Situ Surface Modification Enables High Stability and Optoelectrical Performance for a Self-powered Photodetector. Advanced Optical Materials, 2023, 11(22), 2300940. DOI: 10.1002/adom.202300940. 30 June 2023

[10] P. B. Gui, Y. M. Sun, L. P. Yang, Z. S. Xia, S. Wang, Z. Wang, Z. L. Chen, W. Zeng, X. G. Ren*, S. L. Wang*, G. J. Fang*, Surface Microstructure Engineering in MAPbBr3 Microsheets for Performance-Enhanced Photodetectors. ACS Appl. Mater. Interfaces, 2023, 15(51), 59955–59963. DOI: 10.1021/acsami.3c15029. 12 December 2023

[11] Y. Li, P. B. Gui*, S. Wei, Y. Sun, L. P. Yang, Y. Hu, Z. L. Chen, S. L. Wang, W. Zeng, X.G. Ren*, Z. X. Huang*, Template‐Assisted Synthesis of 2D Perovskite Grating Single Crystal Films at Low Temperatures for UV Polarization‐Sensitive Photodetectors. Small, 2023, 20(13). 2305207. DOI：10.1002/smll.202305207. 14 November 2023.

[12] G. Wang, Z. P. Chen, H. Yan, T. Xuan, M. Y. Wu, X. Zhu, T. Ding, L. Ding, X. G. Ren, X. L. Wu, H. W. Zhang, Crystal structure, Raman spectra, and modified dielectric properties of pure-phase ZnZrNb2O8 ceramics at low temperature, Journal of the American Ceramic Society, 2023, 3(106), 1912-1920. DOI: 10.1111/jace.18892.

[13] G. Wang*, H. Yan, Y. Hu, X. G. Ren, L. X. Yang, Z. X. Huang, X. L. Wu, Microstructure evolution, crystal structure, Raman analysis, bond characteristics and enhanced microwave dielectric properties of Zn1-xCuxZrNb2O8 solid solution ceramics, Ceramics International. 49(22), 35264-35273. DOI: 10.1016/j.ceramint.2023.08.199. 15 November 2023

[14] J. F. Yao, H. Zhang, J. Z. Lu*, L. P. Yang, D.W De Liu, Y. L. Hu, W. Zeng, P. B. Gui, Z. L. Chen*, X. G. Ren*, A self-power photodetector based on controlled growth of single crystal MAPbBr3/WO3 heterojunction, Science China Technological Sciences, 2023, 66, 2660-2668. DOI: 10.1007/s11431-022-2383-x. 27 June 2023

[15] Q. Chen; Z. L. Qiao; J.L. Lv; Y. Ye; X.G. Ren; W. Wang; Z.X. Huang; L. X. Yang; X. L. Liang, A Broadband Active Solar Cell Meta-Surface Antenna, IEEE Antennas and Wireless Propagation Letters, 2023, 22(9), 2320–2324. DOI: 10.1109/LAWP.2023.3287649. 20 June 2023.

[16] C. Wang, G. H. Xu, M. Q. Li, Z. X. Huang, X. G. Ren, J. P. Wang, X. L. Wu, Ultra-Wideband Millimeter-Wave Bidirectional Circularly Polarized Monopole Antenna Array Using a Sequentially Rotated Feeding Technique, IEEE Transactions on Antennas and Propagation, 2023, vol. 71 (1), pp. 1117 - 1122. DOI: 10.1109/TAP.2022.3216478. 27 October 2022

[17] G. D. Xie, M. Fang, Z. X. Huang, X.L. Wu, X. G. Ren, N. X. Feng, A Numerical Study of Lossy Multipole Debye Dispersive Media Using a Recursive Integral-FDTD Method, IEEE Transactions on Microwave Theory and Techniques, 2023, 71(3) 1009-1018. DOI: 10.1109/TMTT.2022.3217530. 09 November 2022

 

2022

[18] Q. Yu, B. Zhao, X. G. Ren*, C. Zhu, Q. Wang, Y. Lin, W. Zeng, Z.L. Chen, S.L. Wang*, Porous Pure MXene Fibrous Network for Highly Sensitive Pressure Sensors, Langmuir, 2022, 38, 18, 5494-55. doi: 10.1021/acs.langmuir.2c00054.

[19] Y. Zhou, X.G. Ren*, Y.Q. Yan, H. Ren, H.M. Du, X.Y. Cai*, Z.X. Huang, Analysis of Physical Mechanism of Perovskite Solar Cell Based on Double Electron Transport Layer, Acta Phys. Sin., 2022, 71(20): 208802. doi: 10.7498/aps.71.20220725.

(周玚, 任信钢*, 闫业强, 任昊, 杜红梅, 蔡雪原*, 黄志祥，基于双层电子传输层钙钛矿太阳能电池的物理机制分析, 物理学报, 2022, 71(20): 208802. doi: 10.7498/aps.71.20220725)

[20] G. D. Xie, M. Fang, Z. X. Huang, X. G. Ren, X. L. Wu, A unified 3-D simulating framework for Debye-type dispersive media and PML technique based on recursive integral method, Computer Physics Communications, 2022, 280, 108463. doi: 10.1016/j.cpc.2022.108463. (cited by 1)

[21] K. Wang, S. T. Cheng, J. W. Yang, Y. Cheng, Q. Ci, H. Y., K. W. Huang, R. J. Liu, W. J. Li, J.L. Li, C. Tu, F. S. Liang, Y. Y. Yang, J. B. Sun, Q. M. Hu, J. B.Yin, B. L. Guan, X. G. Ren, Y. Qi, Z.F. Liu, Bush-Shaped Vertical Graphene/Nichrome Wire for Blackbody-Like Radiative Heating, Advanced Functional Materials, 2022, 32 (51), 2208785 https://doi.org/10.1002/adfm.202208785. doi: 10.1002/adfm.202208785.

[22] Q. P. Zhan, H. B. Pang, J.N. Liao, W. L. Luo, G. Wang, X. G. Ren, J. Wang, Z. M. Duan, Z. X. Huang, L. Ding*, Design of compact dual-mode photoelectric modulator with high process tolerance based on vanadium dioxide, Applied Optics, 2022, 61(23), 6761-6769. doi: 10.1364/AO.466054.

 

2021

[23] D. F. Shen, X. G. Ren*, Q. Ci, K.K. Niu, S.L. Wang, Z.X. Huang, Dual quasi-bound states in the continuum modes for optical activity manipulation, IEEE Photonics Journal, 2021, 13(6), 4600105. doi: 10.1109/JPHOT.2021.3123094. (cited by 1)

[24] Y. Cai, G.S. Cheng*, X. G. Ren*, J. Wu, H. Ren, K.H. Song, Z.X. Huang* and X.L. Wu, Highly Isolated Two-elements Ultra-wideband MIMO Fractal Antenna with Multi Band-Notched Characteristics Highly Isolated Two-elements Ultra-wideband MIMO Fractal Antenna with Multi Band-Notched Characteristics, Progress In Electromagnetics Research C, 2021, 116, 13-24. doi: 10.2528/PIERC21080401.

[25] Q. Ci, X. G. Ren*, Y.Q. Yan, K.K. Niu, H. Ren, G.X. Sun, Z.X. Huang*, X.L. Wu, The influence of the emission source on outcoupling and directivity of patterned perovskite light-emitting diodes, IEEE Photonics Journal, 2021, 13, 8200405. doi: 10.1109/JPHOT.2021.3107054.

[26] W.C. Wang, X.Q. Bai, Q. Ci, L.L. Du*, X.G. Ren*, and D. L. Phillip*, Near-Field Drives Long-Lived Shallow Trapping of Polymeric C3N4 for Efficient Photocatalytic Hydrogen Evolution, Advanced Functional Materials, 2021, 31(35), 2103978. doi: 10.1002/adfm.202103978. (cited by 47)

[27] Y. Fan, K. Li, X.G. Ren*, W Yan, C. Zhu, Y. Zhao, W. Zeng, Z. L. Chen, S.L. Wang*, A highly selective gas sensor based on the WO₃/WS₂ van der Waals heterojunction for the 2-chloroethyl ethyl sulfide (2-CEES) sensing application, Journal of Materials Chemistry C, 2021, (48), 17496-17503. doi: 10.1039/D1TC04678K. (cited by 4)

[28] R. Gao, D. Li*, Q. Zhang, S Zheng, X.G. Ren*, W. Deng, GNPs-QDs core–satellites assembly: trimodal platform for on-site identification and detection of TNT in complex media, Sensors and Actuators B: Chemical, 2021, 328, 128960. doi:10.1016/j.snb.2020.128960. (cited by 14)

[29] L. Nie, W. K. Ng, Z.F. Liang, X.G. Ren, T.B. Yang, G.D. Mei, C. W. Leung, K. S. Wong*, and W. C.H. Choy*, Upside-Down Molding Approach for Geometrical Parameter-Tunable Photonic Perovskite Nanostructures, ACS Appl. Mater. Interfaces, 2021, 13, 23, 27313-27322. doi: 10.1021/acsami.1c02318.

[30] X. Deng, M. Fang, Z.X. Huang, X.G. Ren, J Shi, X.L. Wu, Bio-Sensor Based on Trapped Mode All-Dielectric Metasurface Coated with Graphene Layer to Enhance Sensitivity, IEEE Photonics Journal, 2021, 13(3)1-12. doi: 10.1109/JPHOT.2021.3075067. (cited by 1)

2020

[31] H. Ren, X.G. Ren*, K.K. Niu, S.L. Wang, Z.X. Huang* and X.L. Wu, Optical-Electrical-Thermal Optimization of Plasmon-enhanced Perovskite Solar Cells, Physical Chemistry Chemical Physics, 2020, 22, 17068-17074. (cited by 15) (selected as Inside Back Cover)

[32] K. K. Niu, Z. X. Huang*, X.G. Ren*, K. Xu, M. Li, X. L. Wu, P. Li, L. Jiang, H. Bagci, An Efficient 3-D Stochastic HIE-FDTD Algorithm for Investigation of Statistical Variation in Electromagnetic Fields, IEEE Transactions on Antennas and Propagation, 2020, 68(12), 8227-8232. doi: 10.1109/TAP.2020.2986060. (cited by 5)

[33] T. Ni, S. Wang*, J. Shi，X. Du, Q. Cheng, Z. Dong, L. Ruan, W. Zeng, X. Guo, X.G. Ren, Z. X. Huang*, Flexible and Self-Healable Zinc-Ion Hybrid Supercapacitors Based on MWCNTs-RGO Fibers, Advanced Materials Technologies, 2020. 5(9), 2000268. (cited by 31)

[34] J. Wu, Z. X. Huang, X.G. Ren, W. Sha, X.L. Wu, Millimeter-wave Dual-mode Dual-circularly-polarized OAM Antenna Using Sequentially Rotated Feeding Technique, IEEE Antennas and Wireless Propagation Letters, 2020, 19(8), 1296-1300. (cited by 16)

[35] X Li, S Guo, J Su, X.G. Ren, Z Fang, Efficient Raman Enhancement in the Molybdenum Disulfide by Tuning the Interlayer Spacing, ACS Applied Materials & Interfaces, 2020,12, 25, 28474-28483. (cited by 15)

[36] S. Guo, X. G. Ren, X. Li, Au Hierarchical Nanostructures for High-Sensitivity and Recyclable SERS Device, Plasmonics, 2020, 15, 591-598. (cited by 7)

[37] K. K. Niu, M. Fang, X.G. Ren, Z. X. Huang, H. Ren, X. L. Wu, W. E. I. Sha, Linear and nonlinear spin-orbital coupling in golden-angle spiral quasicrystals. Optics Express, 2020, 28 (1), 334-344. (cited by 12)

2019

[38] H. Ren, X.G. Ren*, Z.X. Huang† and X.L. Wu, Synergetic Light Trapping Effects in Organic Solar Cells with the Patterned Semi-Transparent Electrode, Physical Chemistry Chemical Physics, 2019, 21, 11306-11312. (cited by 20)

[39] X. G. Ren, Z. S. Wang, W. C. H. Choy, Device Physics of the Carrier Transporting Layer in Planar Perovskite Solar Cells. Advanced Optical Materials, 2019, 7 (20), 1900407. (cited by 20)

[40] D. Li, X. K. Cao, Q. M. Zhang, X. G. Ren*, L. Jiang, D. W. Li, W. Deng, H. T. Liu, Facile in situ synthesis of core-shell MOF@Ag nanoparticle composites on screen-printed electrodes for ultrasensitive SERS detection of polycyclic aromatic hydrocarbons. Journal of Materials Chemistry A, 2019, 7 (23), 14108-14117. DOI: 10.1039/C9TA03690C. (cited by 64)

[41] R. Wang, X. G. Ren*, Z. Yan, L. J. Jiang*, W. E. I. Sha, G. C. Shan*, Graphene based functional devices: A short review. Frontiers of Physics, 2019, 14 (1), 2019. (cited by 151)（ESI highly cited paper）

[42] X. H. Li, S. H. Guo, W. Li, X.G. Ren, J. Su, Q. Song, A. J. Sobrido, B. Q. Wei, Edge-rich MoS2 grown on edge-oriented three-dimensional graphene glass for high-performance hydrogen evolution, Nano Energy, 2019, 57, 388-397. (IF: 13.120, cited by 82)（ESI highly cited paper）

[43] X. S. Deng, M. Fang, X. G. Ren, Z. X. Huang, X. L. Wu, Ultra-sensitive Bio-sensor Based on Trapped Mode All-dielectric Metasurface Coating with Graphene Layer. Acta Photonica Sinica, 2019, 48 (12), 1248005. (In Chinese) (cited by 3)

[44] B. P. Yang, D. Ouyang, Z. F. Huang, X. G. Ren, H. Zhang, W. C. H. Choy, Multifunctional Synthesis Approach of In:CuCrO2 Nanoparticles for Hole Transport Layer in High-Performance Perovskite Solar Cells. Advanced Functional Materials, 2019, 29 (34), 1902600. (cited by 60)

[45] J. Wu, Z. X. Zhang, X. G. Ren, Z. X. Huang, X. L. Wu, A Broadband Electronically Mode-Reconfigurable Orbital Angular Momentum Metasurface Antenna. IEEE Antennas and Wireless Propagation Letters, 2019, 18 (7), 1482-1486. (cited by36)

2018

[46] Y. Zhao#, H. Zhang#, X.G. Ren#, L. Zhu, Z. Huang, F. Ye, D. Ouyang, K. Cheah, A. K.-Y. Jen, and W. C.H. Choy, Thick TiO2 Based Top Electron Transport Layer on Perovskite for Highly Efficient and Stable Solar Cells, ACS Energy Lett., 2018, 3, 2891. (#: equally contributed). DOI: 10.1021/acsenergylett.8b01507 (cited by 62, IF: 12.277)

[47] H. Lu#, X.G. Ren#, D. Ouyang, W. C. H. Choy, Emerging Novel Metal Electrodes for Photovoltaic Applications, Small, 2018, 14, 1703140. (#: equally contributed，邀请综述) DOI: 10.1002/smll.201703140. (cited by 80, IF: 8.643)

[48] D. Li, Y. Ma, H. Dua, F. Jiang, W. Deng, X.G. Ren*, Fluorescent/SERS dual-sensing and imaging of intracellular Zn ²⁺, Analytica Chimica Acta, 2018, 1038, 148-156. (*: corresponding author) DOI: 10.1016/j.aca.2018.07.020 (cited by 23, IF: 5.123).

[49] H. Zhang, X.G. Ren, X. Chen, J. Mao, J. Cheng, Y. Zhao, Y. Liu, J. Milic, W. Yin, M. Grätzel, W. C. H. Choy, Improving the stability and performance of perovskite solar cells via off-the-shelf post-device ligand treatment, Energy Environ. Sci., 2018, 11, 2253-2262. (IF: 30.067, cited by 158, highly cited paper)

[50] Z. Wang, X.G. Ren, X.P. Xu, Q. Peng, W. E. I. Sha, W. C. H. Choy, A Comprehensively Theoretical and Experimental Study of Carrier Generation and Transport for Achieving High Performance Ternary Blend Organic Solar Cells, Nano Energy, 2018, 51,206-215. (cited by 13, IF: 13.120)

[51] S. Guo, X. Li, X.G. Ren, L. Yang, J. Zhu, B. Q. Wei, Optical and Electrical Enhancement of Hydrogen Evolution by MoS₂@MoO₃ Core–Shell Nanowires with Designed Tunable Plasmon Resonance, Adv. Funct. Mater. 2018, 28, 1802567. (cited by 57, IF: 13.325)

[52] S. Guo, L. Yang, Y. Zhang, Z. Huang, X.G. Ren, W. Sha, X. Li, Enhanced hydrogen evolution via interlaced Ni3S2/MoS2 heterojunction photocatalysts with efficient interfacial contact and broadband absorption, J. Alloy. Compd., 2018, 749, 473-480. (cited by 34, IF: 3.779)

[53] Z. Huang, J. Cheng, X.G. Ren, J.Q Zhuang, V. A. L. Roy, J. M. Burkhartsmeyer, K.S Wong, W. C. H. Choy, All Room-Temperature Solution-Processed Mixed Maghemite/Iron-Hydroxide Nanocomposites Based Hole Transporting Layer for High-Performance Organic Solar Cells, Nano Energy, 2018, 47, 26-34. (IF: 13.120, cited by 20)

[54] W. Sha, H. Zhang, Z Wang, L. Zhu, X.G. Ren, F. Lin, A.K.-Y. Jen, W.C.H. Choy*, Quantifying Efficiency Loss of Perovskite Solar Cells by a Modified Detailed Balance Model, Adv. Energy Mater., 2018, 8, 1701586. (cited by 52, IF: 21.875)

[55] K.K Niu, Z.X. Huang, X.G. Ren, M.Q. Li, B. Wu, X.L. Wu, An optimized 3-D HIE-FDTD method with reduced numerical dispersion, IEEE Transactions on Antennas and Propagation,2018, 66 (11), 6435-6440. (cited by 35)

2017

[56] X.G. Ren, Z. S. Wang, W. E. I. Sha*, W. C. H. Choy*, Exploring the Way to Approach the Efficiency Limit of Perovskite Solar Cells by Drift-Diffusion Model, ACS Photonics, 2017. 4 (4), 934-942. (IF: 6.880, cited by 90)

[57] J. Cheng, X.G. Ren, H. L. Zhu, J. Mao, C. Liang, J. Zhuang, V. A. L. Roy, W. C. H. Choy*, Pre- and post-treatments free nanocomposite based hole transport layer for high performance organic solar cells with considerably enhanced reproducibility. Nano Energy 2017, 34, 76-85. (IF: 13.120, cited by 89)

[58] J. Mao, W. Sha, H. Zhang, X.G. Ren, J. Zhuang, V. A. L. Roy, K. S. Wong, W. C. H. Choy*, Novel Direct Nanopatterning Approach to Fabricate Periodically Nanostructured Perovskite for Optoelectronic Applications. Adv. Funct. Mater. 2017, 27 (10), 1606525(1-10). (IF: 13.325，cited by 64)(highlighted by MaterialsViewsChina.com and X-MOL)

2016

[59] X.G. Ren#, J. Q. Cheng#, S. Q. Zhang, X. C. Li, T. K. Rao, L. J. Huo, J. H. Hou, W. C. H. Choy*, High Efficiency Organic Solar Cells Achieved by the Simultaneous Plasmon-Optical and Plasmon-Electrical Effects from Plasmonic Asymmetric Modes of Gold Nanostars, Small, 2016. 12 (37), 5200-5207. (Front Cover, highlighted by MaterialsViewsChina.com and AtlasofScience.com) (IF: 9.598, cited by 70)

[60] W. C. H. Choy^*, X.G. Ren^*, Plasmon-Electrical Effects on Organic Solar Cells by Incorporation of Metal Nanostructures, IEEE J. Sel. Top. Quantum Electron., 2016. 22 (1), 4100209. (Cover, corresponding author)( IF: 3.367, cited by 47)

[61] G. Luo, X.G. Ren, S. Zhang, H. B. Wu*, W. C. H. Choy*, Z. He*, Y. Cao, Recent Advances in Organic Photovoltaics: Device Structure and Optical Engineering Optimization on the Nanoscale, Small, 2016. 12 (12), 1547-1571. (IF: 9.598, cited by 69)

2015

[62] X.G. Ren, X.C. Li, W. C. H. Choy*, Optically Enhanced Semi-Transparent Organic Solar Cells through Hybrid Metal/Nanoparticle/Dielectric Nanostructure, Nano Energy, 2015. 17, 187-195. (IF: 13.120, cited by 60)

[63] X. Li^#, X.G. Ren^#, F. X. Xie, Y. X. Zhang*, T. T. Xu, B. Q. Wei*, W. C. H. Choy*, High-Performance Organic Solar Cells with Broadband Absorption Enhancement and Reliable Reproducibility Enabled by Collective Plasmonic Effects, Adv. Opt. Mater., 2015. 3 (9), 1220-1231. (equally contributed, Cover)(IF: 7.430, cited by 61)

[64] H. Lu^#, X.G. Ren^#, W. E. I. Sha, J. F. Chen, Z. W. Kang, H. X. Zhang, H.-P. Ho*, W. C. H. Choy*, Experimental and Theoretical Investigation of Macro-Periodic and Micro-Random Nanostructures with Simultaneously Spatial Translational Symmetry and Long-Range Order Breaking, Sci. Rep., 2015. 5, 7876. (equally contributed) (IF: 4.122, cited by 21)

[65] H. Lu^#, X.G. Ren^#, W. E. I. Sha, H.-P. Ho, W. C. H. Choy*, Broadband near-field enhancement in macro-periodic and micro-random structure with a hybridized excitation of propagating Bloch-Plasmonic and localized surface-plasmonic modes, Nanoscale, 2015. 7 (40), 16798-16804. (equally contributed) DOI: 10.1039/C5NR03391H. (IF: 7.233, cited by 9)

[66] W. Sha, X.G. Ren, L. Z. Chen, W. C. H. Choy, The efficiency limit of CH3NH3PbI3 perovskite solar cells, Appl. Phys. Lett., 2015. 106 (22), 221104. (IF: 3.459, cited by 519) (ESI, Top 1% Highly cited paper)

[67] F. Xie, D. Zhang, H. Su, X.G. Ren, K. S. Wong, M. Gratzel, W. C. H. Choy*, Vacuum-Assisted Thermal Annealing of CH3NH3PbI3 for Highly Stable and Efficient Perovskite Solar Cells, Acs Nano, 2015. 9 (1), 639-646. (IF: 13.709, cited by 335) (ESI, Top 1% Highly cited paper)

[68] J. Liu, X. Li, S. Zhang, X.G. Ren, J. Q. Cheng, L. Zhu, D. Zhang, L. J. Huo, J. H. Hou, W. C. H. Choy, Synergic Effects of Randomly Aligned SWCNT Mesh and Self-Assembled Molecule Layer for High-Performance, Low-Bandgap, Polymer Solar Cells with Fast Charge Extraction, Adv. Mater. Interfaces, 2015. 2 (17), 1500324. (IF: 4.834, cited by 23)

[69] X. Li, X.G. Ren, Y. X. Zhang, W. C. H. Choy, B. Q. Wei, An all-copper plasmonic sandwich system obtained through directly depositing copper NPs on a CVD grown graphene/copper film and its application in SERS, Nanoscale, 2015. 7 (26), 11291-11299. (front cover) (IF: 7.233, cited by 66)

2014

[70] L. Zhu, W. C. H. Choy, W. Sha, X.G. Ren, Photovoltaic Mode Ultraviolet Organic Photodetectors with High On/Off Ratio and Fast Response, Adv. Opt. Mater., 2014. 2 (11), 1082-1089. (IF:7.430, cited by 37)

[71] H. Lu, D. Zhang, X.G. Ren, J. Liu, W. C. H. Choy, Selective Growth and Integration of Silver Nanoparticles on Silver Nanowires at Room Conditions for Transparent Nano-Network Electrode, Acs Nano, 2014. 8 (10), 10980-10987. (IF: 13.709, cited by 121)

[72] X. Li, W. Choy*, X.G. Ren, D. Zhang, H. F. Lu, Highly Intensified Surface Enhanced Raman Scattering by Using Monolayer Graphene as the Nanospacer of Metal Film-Metal Nanoparticle Coupling System, Adv. Funct. Mater., 2014. 24 (21), 3114-3122. (Frontispiece Cover, highlighted by MaterialsViewsChina.com) (IF: 13.325, cited by 173)

[73] H. Wang, Z. Huang, X. Wu, X.G. Ren, B. Wu, Symplectic FDTD algorithm for the simulations of double dispersive materials, Acta Phys. Sin-ch. Ed., 2014. 63 (7), 070203. (In Chinese) (IF: 0.669, cited by 2)

[74] Y. Zhou, X. Li, X.G. Ren, L. B. Yang*, J. H. Liu*, Designing and fabricating double resonance substrate with metallic nanoparticles-metallic grating coupling system for highly intensified surface-enhanced Raman spectroscopy, Analyst., 2014. 139 (19), 4799-4805. (Inside Front Cover) (IF: 3.864, cited by 20)

2013

[75] X.G. Ren, W. E. I. Sha, W. C. H. Choy*, Tuning optical responses of metallic dipole nanoantenna using graphene, Opt. Express, 2013. 21 (26), 31824-31829. (IF: 3.356, cited by 42)

[76] X. Li, W. Choy*, X.G. Ren, J. Z. Xin, P. Lin, D. C. W. Leung, Polarization-independent efficiency enhancement of organic solar cells by using 3-dimensional plasmonic electrode, Appl. Phys. Lett., 2013. 102 (15), 153304. (IF: 3.459, cited by 53)

2012

[77] X.G. Ren, Z. X. Huang*, X. L. Wu, S. L. Lu, H. Wang, L. Wu, S. Li, High-order unified symplectic FDTD scheme for the metamaterials, Comput. Phys. Commun., 2012. 183 (6), 1192-1200. (IF: 3.748, cited by34)

[78] S. Lu, X. Wu, X.G. Ren, Y. C. Mei, J. Shen, Z. X. Huang*, Study of periodic dispersive structures using split field FDTD method, Acta Phys. Sin-ch. Ed., 2012. 61 (19). 194701. (IF: 0.669, cited by 12)

2011

[79] H. Wang, Z. Huang*, X. Wu, X.G. Ren, Perfect plane-wave source for a high-order symplectic finite-difference time-domain scheme, Chin. Phys. B, 2011. 20 (11), 114701. (IF:1.321, cited by 10)

 

 

Patent    

 

1.       任信钢、慈晴、黄志祥、牛凯坤、方明、程光尚、杨利霞、任昊、周旸，一种光场可调的钙钛矿发光二极管，专利授权号：Z. L. 202011223232.5，授权日期2021.12.24.(1/9)

2.       任信钢、申东方、慈晴、黄志祥、杨利霞、王思亮、牛凯坤、任子华，一种旋光性与极化可调的方形晶格超表面谐振器，专利授权号：Z. L. 202111056842.5，授权日期2023.06.02. (1/8)

3.       任信钢、赵亚莉、孙国星、饶嘉宇、王刚、牛凯坤、吴先良、黄志祥、李迎松，一种超宽带电磁带隙结构及电路板，专利授权号：ZL. 202311068387X，专利授权日期2023.10.19. (1/9)

4.       任信钢、刘宇行、黄志祥、王丽华、李迎松、王思亮、王刚，一种可增强二次谐波产生效率的 BIC 超表面，专利授权号：Z. L. 202311322136X，专利授权日期：2023.12.08. (1/7)

5.       任信钢、琚胡平、智薇、黄志祥、王刚、牛凯坤、王思亮、李迎松、吴先良、曹孙根，一种SOIMOSFET结构，专利授权号：Z. L. 2023107026711，专利授权日期2024.01.05. (1/10)

6.       任信钢、韦声扬、夏兆生、黄志祥、沙威、王丽华、王刚、吴博、李迎松、陈志亮、彭勇，一种太阳能电池内部损耗机制的诊断方法，专利授权号：Z.L. 202410163721.8，专利授权日期：2024.04.19. (1/11)

7.       任信钢、蔡勇、王丽华、黄志祥、饶嘉宇、王刚、吴博、李迎松、徐光辉、余航、彭勇，宽带双圆极化磁电偶极子天线，专利申请号：Z.L. 202410319837.6, 专利授权日期：2024.04.26. (1/11)

8.       任信钢、蔡勇、黄志祥、方明、程光尚、牛凯坤、杨利霞、任昊、吴杰，一种两元宽带天线装置，专利申请号：Z.L. 202011243907.2, 专利申请日期：2021.02.26. (1/9)

9.       任信钢、陶伟、黄志祥、蔡雪原、吴先良、谢国大、王思亮、郭小辉，一种具有静电驱动的双层扭转的MEMS微镜及激光雷达，专利申请号：Z.L. 202210263856.2，专利申请日期：2022.06.17. (1/8)

10.     任信钢、夏兆生、韦声扬、黄志祥、陈志亮、郑海英、叶飞鸿、王刚、吴博、吕瑞瑞、尉元杰、曹孙根，一种叠层太阳能电池，专利申请号：Z.L. 2024103911471，专利申请日期：2024. 04.02. (1/12)

11.     Xingang Ren、Qing Ci、Zhixiang Huang、Kaikun Niu、Ming Fang、Guangshang Cheng、Lixia Yang，Perovskite Light-Emitting Diode with Adjustable Light Field，美国专利授权号：US 11 758 748 B2，专利授权日期：2023.06.12. (1/7)

12.     Xingang Ren、Yong Cai、Zhixiang Huang、Ming Fang、Guangshang Cheng、Kaikun Niu、Lixia Yang、Hao Ren、Jie Wu，Two-Element Broadband Antenna Device，荷兰专利授权号： 2029498，专利授权日期：2023.03.23. (1/9)

13.     Xingang Ren、Dongfang Shen、Qing Ci、Zhixiang Huang、Lixia Yang、Siliang Wang、Kaikun Niu、Zihua Ren，Square Lattice Metasurface Resonator With Adjustable Optical Rotation And Polarization，荷兰专利授权号： 2030632，专利授权日期：2023.06.28. (1/8)

14.     Xingang Ren、Wei Zhi、Huping Ju、Zhixiang Huang、Gang Wang、Kaikun Niu、Siliang Wang、Yingsong Li、Xianliang Wu、Sungeng Cao, Silicon-On-Insulator Metal-Oxide-Semiconductor Field-Effect Transistor (SOI MOSFET) Structure，美国专利授权号：US 12,057,502 B1. 专利授权日期：2024.08.06. (1/10)

15.     Xingang Ren、Shengyang Wei、Yali Zhao、Guoxing Sun、Jiayu Rao、 Gang Wang、Kaikun Niu、Xianliang Wu、Zhixiang Huang、Yingsong Li、Yong Peng, Ultra-Wideband Electromagnetic Band Gap (EBG) Structure and Circuit Board，美国专利授权号：18539132. 专利申请日期：2024.01.28. (1/11)

16.     Xingang Ren、Shengyang Wei、Zhaosheng Xia、Zhixiang Huang、Wei Sha、Lihua Wang、Gang Wang、Bo Wu、Yingsong Li、Zhiliang Chen、Yong Peng, Method For Diagnosing Internal Loss Mechanism Of Solar Cell, 专利申请号：US 18/737 ,928, 专利申请日期：2024.06.21

17.     方明、徐珂、黄志祥、吴杰、杨利霞、任信钢、刘瑜，一种基于全介质超表面的激光发射器及参数确定方法，授权发明专利号: Z.L. 201911075885.0，授权日期2020.09.01.

18.     方明、邓学松、黄志祥、任信钢、杨利霞、徐珂，检测肿瘤生物标记物的全介质超表面传感平台及设计方法，授权专利号: Z.L. 201910715256.3，授权日期2021.03.11.

19.     黄志祥、吴杰、方明、任信钢、杨利霞、吴先良，一种宽带毫米波双圆极化双模式轨道角动量天线，授权专利号: Z.L. 202010284314.4，授权日期2021.05.11；

20.     王思亮、赵丙田、林洋、任信钢、曾玮,一种多功能锌离子微型电池及其制备方法与应用，授权专利号: 202010284314.4，授权日期2022.06.03.

21.     王思亮、余其涛、林洋、赵丙田、曾玮、任信钢、郭小辉，MXene纤维气凝胶及制备与其在压力传感器中的应用，授权专利号: 202011285892.6，授权日期2022.09.02.

22.     孙东、高刘雅、黄志祥、任信钢、方明、刘俊龙、陈鹤、赵礼良、唐孝柱，一种对证件纸张进行检测、校准和输入的打印机，授权专利号：201910720980.5，授权日期2022.09.13.

23.     程光尚、黄志祥、方明、牛凯坤、赵冉、任信钢、张华永，一种大规模有限周期阵列结构特征模式分析方法，授权专利号: 201810720625.3，授权日期2022.09.23.

24.     牛凯坤、张继瑞、李平、任信钢、谢国大、黄志祥、杨利霞、彭友、陈建新、肖峰，一种区域分解电磁仿真方法及系统，授权发明专利号: Z.L. 201910259369.7，授权日期2022.10.11.

25.     牛凯坤、黄志祥、任信钢、李平、方明、杨利霞、况晓静、朱浩然，一种随机混合显隐式时域有限差分方法，授权发明专利号: 202211635892.3，授权日期2022.10.11.

26.     牛凯坤、周扬、任信钢、李迎松、谢国大、方明、黄志祥、杨利霞、吴先良，一种纳米天线的二次谐波极化状态调控方法，专利申请号：202310222251.3，专利申请日期2023.08.18.

27.     牛凯坤、刘宇行、申东方、任信钢、黄志祥、杨利霞、李迎松，一种新型quasi-BIC超表面手性调控方法，专利申请号：202310525737.4，专利申请日期2023.05.15.

28.     牛凯坤、肖子静、黄志祥、任信钢、李迎松、杨利霞，基于电热多物理场随机FDTD的电磁辐射强度评估方法，专利申请号：202311124149.6，专利申请日期2023.09.01.

29.     牛凯坤，张文凯，任信钢，黄志祥，李迎松，杨利霞，吴先良，基于混合显隐式时域有限差分算法的电热耦合仿真方法，专利申请号：202311433897.2，专利申请日期2023.11.01.

30.     牛凯坤、朱国萃、李民权、黄志祥、李迎松，任信钢，基于高阶矩阵指数完美匹配层的FDTD计算方法及系统，专利申请号：202311207020.1，专利申请日期2023.09.19.

31.     牛凯坤、张继瑞、李平、任信钢、谢国大、黄志祥、杨利霞、彭友、陈建新、肖峰，一种区域分解电磁仿真方法及系统，专利申请号：202210385152.2，专利申请日期2022.04.13.

32.     李迎松、黄志祥、李力、胡应节、任信钢、牛凯坤、方明，一种微型化超低频天线，专利授权号：202310307833.1，专利授权日期2023.06.16.

33.     李迎松、余灿平、孟露露、黄志祥、任信钢、牛凯坤，一种微型化多波束低频/5G/6G连续频率可调天线，专利申请号：202310506371.6，专利授权日期2023.10.31.

34.     黄志祥、王超、李民权、徐光辉、谢国大、任信钢、吴先良，一种双向圆极化单元天线及阵列天线，专利申请号：202310307833.1，专利授权日期2023.07.21.

35.     黄志祥、王超、李民权、徐光辉、谢国大、牛凯坤、任信钢，一种基于正交磁偶极子的平面双圆极化天线，专利申请号：202310129296.6，专利申请日期2023.02.17.

36.     黄志祥、钱思贤、吴杰、牛凯坤、李义、安书杨、任信钢、杨利霞、吴先良，一种S波段频率重构轨道角动量天线及频率重构方法，专利申请号：202211635892.3，专利申请日期2022.12.20.

37.     王思亮、严文龙、夏昌岳、孙创、黄志祥、任信钢、曾玮、桂鹏彬、陈志亮，WO3/Al2O3/graphite复合材料及制备与应用，专利申请号：202310628577.6，专利申请日期2023.05.31.

38.     王思亮、张长林、任信钢、曾玮、张绍军，一种V₂CT_x-V₂O_x材料及其制备方法和应用，专利申请号：202310632878.6，专利申请日期2023.05.31.

39.     金秋延、刘瑞哲、王紫任、任信钢，基于正态分布宽带信号的无源互调预测方法，专利申请号：202310339208.5，专利申请日期2023.04.02.

40.     徐光辉、饶嘉宇、任信钢、杨利霞、李迎松、黄志祥、吴先良，基于毫米波振子与sub-6GHz环天线的共口径手机边框天线，专利申请号：202310741463.2，专利申请日期2023.06.20.

41.     徐光辉、饶嘉宇、任信钢、杨利霞、黄志祥，毫米波双极化贴片天线与环天线的双频共口径手机天线，专利申请号：202311044033.1，专利申请日期2023.08.17.

42.     孙东、高刘雅、黄志祥、吴先良、任信钢、刘俊龙、陈鹤、赵礼良、唐孝柱，一种对证件纸张进行检测、校准和输入的打印机，授权实用新型专利号：201921161922.5，2020.05.

 

 

Conference Papers‍

1. Y. Q. Yan, X. G. Ren, S. P. He, X. T. Huang, Z. X. Huang, Steady-state Analysis of Bipolar Transistor, 2021 Photonics & Electromagnetics Research Symposium (PIERS), 21-25, Nov. 2021, doi:  10.1109/PIERS53385.2021.9694751. (PDF,  程序册）
2. Y. Cai, S. P. He, X. G. Ren, Z. X. Huang , An Octagonal Iterative Fractal Antenna with Notch Band and UWB Characteristics, 2021 Photonics & Electromagnetics Research Symposium (PIERS), 28-31, July 2021, doi:  10.1109/PIERS53385.2021.9694679. (PDF,  程序册）
3. Q. Ci, X. G. Ren, Z. Huang and X. Wu, Radiation pattern design of Perovskite light-emitting diodes by nanostructures, 2021 International Applied Computational Electromagnetics Society (ACES-China) Symposium, 28-31, July 2021, doi: 10.23919/ACES-China52398.2021.9582043. (PDF,  程序册）
4. Y. Cai, X. G. Ren, S. He and Z. Huang, Four-Element UWB-MIMO Fractal Antenna with 8.5GHz Band-Notched Characteristic, 2021 International Applied Computational Electromagnetics Society (ACES-China) Symposium, 28-31, July 2021, doi: 10.23919/ACES-China52398.2021.95816701. (PDF,  程序册）
5. H. Ren, X. G. Ren, Q.Q. Deng, Z.X. Huang, X.L. Wu, Study on Optical-Electric-Thermal Performance of the Perovskite Solar Cells Based on Embedding Different Geometric Metal Nanoparticles, 2020 IEEE MTT-S International Conference on Numerical Electromagnetic and Multiphysics Modeling and Optimization (NEMO), 7-9 Dec. 2020, doi:  10.1109/NEMO49486.2020.9343634. (PDF,  程序册）
6. X. G. Ren, Y. Wang, H. Ren, Z.X. Huang, X. L. Wu，Modeling of graphene based strong coupling nanodevice (invited),  2019 International Applied Computational Electromagnetics Society Symposium (2019 ACES Nanjing, China), 8-11 Aug. 2019 .doi:  10.23919/ACES48530.2019.9060578.  (PDF,  程序册）
7. X. G. Ren, Theoretical Understanding of Device Physics for Enhancing Organic Solar Cell Performance, 22nd International Conference on Photochemical Conversion and Storage of Solar Energy (22-IPS)，July 29-Aug 3, Hefei, China, 2018.
8. Z. Liu, G.D. Xie, B. Wu, X. G. Ren, M. Fang, Z.X. Huang，A Novel FDTD Algorithm Based on the Vector and Scalar Potentials Equations,  2019 IEEE International Conference on Computational Electromagnetics (ICCEM), 20-22 March 2019. doi:  10.1109/COMPEM.2019.8779133.  (PDF,  程序册）
9. Z. X. Huang, Y. K.  Zhang, M. Fang, K. K. Niu, X. G. Ren,  X. L. Wu, The Self-Consistent Model Incorporating the Gain into a Dispersive  Metamaterial Nanostructure. 2017 Ieee Electrical Design of Advanced  Packaging and Systems Symposium (EDAPS), 14-16 Dec. 2017, doi:  10.1109/EDAPS.2017.8276938.  (PDF）
10. Dec. 14-Dec-16, Haining, Hangzhou, China, 2017.  doi.
11. X.G. Ren, X. C. Li and W. C.  H. Choy, " Optically enhanced semi-transparent organic solar cells through  hybrid metal/nanoparticle/dielectric nanostructure" presented at 2016 MRS  Spring Meeting & Exhibit (2016 MRS Spring),  March 28-April 1, Phoenix, Arizona, United State, 2016.
12. X. G. Ren, W. E. I. Sha, W. C. H.  Choy, Graphene Nanoantenna with Tunable Optical Properties. In Progress In Electromagnetics Research  Symposium (PIERS), Stockholm, Sweden, 2013.
13. X. G. Ren, Z. X. Huang, X. L. Wu, S.  L. Lu, Y. C. Mei, H. M. Du, H. Wang, J. Shen, Numerical dispersion analysis of  symplectic and ADI schemes. In Microwave  and Millimeter Wave Technology (ICMMT), Shenzhen, China, 2012; Vol. 5, pp  1-4.
14. S. L. Lu, B. Wu, Z. X.  Huang, X. L. Wu, X. G. Ren,  Y. C. Mei, H. M. Du, Study of periodic dispersive structures at oblique  incidence by split-field FDTD method. In Microwave  and Millimeter Wave Technology (ICMMT), Shenzhen, China, 2012; Vol. 4, pp  1-4.
15. X. G. Ren, Z. X. Huang, X. L. Wu, H.  Wang, S. L. Lu, Research on Unified Formulation for the FDTD simulation of   Nonlinear Dispersive Media. In National  Conference on Antenna(NCAnt2011), Nanjing, 2011.
16. X. G. Ren, Z. X. Huang, X. L. Wu, S.  L. Lu, Y. C. Mei, H. M. Du, L. Wu, A split-operator method to simulate the left  hand materials. In Cross Strait  Quad-Regional Radio Science and Wireless Technology Conference (CSQRWC2011),  2011; Vol. 1, pp 214-217.
17. H. Wang, Z. X. Huang,  X. L. Wu, J. X. Sun, X. G. Ren,  L. Wu, The SP-FDTD method for high-order FDTD plane wave injection. In Antennas Propagation and EM Theory (ISAPE),  Chendu, China, 2010; pp 780-783.
18. Y. C. Mei, Z. X. Huang,  X. L. Wu, X. G. Ren, H. M.  Du, Numerical simulation of GPR based on 3-D high-order FDTD. In Antennas Propagation and EM Theory (ISAPE),  Chendu, China, 2010; pp 872-875.‍