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1) W Nsengiyumva, S Zhong*, M Luo, B Wang, Terahertz Spectroscopic Characterization and Thickness Evaluation of Internal Delamination Defects in GFRP Composites, Chinese Journal of Mechanical Engineering, 2023, 36 (1), 1-21

2) Y Yang, Z Ren, C Zhou, Y Lin, L Hou, L Shi, S Zhong, 3D©\Printed Robust Dual Superlyophobic Ti©\Based Porous Structure for Switchable Oil/Water Emulsion Separations, Advanced Functional Materials, 2023, 2212262

3) W Tu, S Zhong, Q Zhang, Y Shen, A Incecik, Quality evaluation of organic protective paints using terahertz pulse imaging technology based on wavelet packet energy method, Ocean Engineering, 2023, 267, 113282

4) H Chen, F Yu, B Wang, C Zhao, X Chen, W Nsengiyumva, S Zhong, Elastic Fibre Prestressing Mechanics within a Polymeric Matrix Composite, Polymers, 2023, 15 (2), 431

5) J Zhong, D Liu, S Chi, Z Tu, S Zhong, Vision-based fringe projection measurement system for radial vibration monitoring of rotating shafts, Mechanical Systems and Signal Processing, 2022, 181, 109467

6) X Chen, S Chi, Y Lin, J Zhong, S Zhong, Y Zhang, J Zhong, Modal analysis of beam-like structures using multipoint dynamic testing vision system based on composite fringe pattern, Measurement Science and Technology, 2022, 34 (1), 015002

7) T Lin, Y Huang, S Zhong, Y Zhong, Z Zhang, Q Zeng, Y Yu, Z Peng, Field manipulation of electromagnetically induced transparency analogue in terahertz metamaterials for enhancing liquid sensing, Optics and Lasers in Engineering, 2022, 157, 107127

8) Z Zhang, Y Huang, S Zhong, T Lin, Y Zhong, Q Zeng, W Nsengiyumva, Y Yu, Z Peng, Time of flight improved thermally grown oxide thickness measurement with terahertz spectroscopy, Frontiers of Mechanical Engineering, 2022, 17 (4), 49

9) Y Zhong, Y Huang, S Zhong, T Lin, Z Zhang, Q Zeng, L Yao, Y Yu, Z Peng, Tamm plasmon polaritons induced active terahertz ultra-narrowband absorbing with MoS2, Optics & Laser Technology, 2022, 156, 108581

10) J Zhong, D Liu, S Wu, S Li, S Zhong, W Liang, Three-dimensional translation vibration measurement system based on linear array sensor and composite fringe pattern, Measurement Science and Technology, 2022, 33 (9), 095901

11) C Yang, B Wang, S Zhong, C Zhao, W Liang, On tailoring deployable mechanism of a bistable composite tape-spring structure, Composites Communications, 2022, 32, 101171

12) J Lin, S Zhong*, Q Zhang, J Zhong, W Nsengiyumva, Z Peng, Swept-Source Optical Coherence Vibrometer: Principle and Applications, IEEE Transactions on Instrumentation and Measurement ,2022

13) W Nsengiyumva, S Zhong*, J Lin, Q Zhang, J Zhong, Y Huang, Advances, limitations and prospects of nondestructive testing and evaluation of thick composites and sandwich structures: A state-of-the-art review, Composite Structures, 2021, 256, 112951

14) Z Ren, L Shen, H Bai, L Pan, S Zhong*, Constitutive model of disordered grid interpenetrating structure of flexible microporous metal rubber, Mechanical Systems and Signal Processing, 2021, 154, 107567

15) Hongwen Zhang, Pu Zhang, Jiwu Zhao, Yuan Liu, Yi Huang, Haowei Huang, Chen Yang, Yibo Zhao, Kaifeng Wu, Xianliang Fu, Shengye Jin, Yidong Hou, Zhengxin Ding, Rusheng Yuan, Maarten BJ Roeffaers, Shuncong Zhong*, Jinlin Long*, The Hole©\Tunneling Heterojunction of Hematite©\Based Photoanodes Accelerates Photosynthetic Reaction, Angewandte Chemie International Edition, 2021, 60,16009¨C16018

16) W Nsengiyumva, S Zhong*, M Luo, Q Zhang, J Lin, Critical insights into the state©\of©\the©\art NDE data fusion techniques for the inspection of structural systems, Structural Control and Health Monitoring, 2021, e2857

17) Walter Nsengiyumva, Shuncong Zhong*, Bing Wang1 Longhui Zheng, Zhenhao Zhang, Qiukun Zhang, Jianfeng Zhong, Manting Luo, Zhike Peng, Terahertz spectroscopic study of optical and dielectric properties of typical electrical insulation materials, Optical Materials, 2021

18) H Yao, H Mei, W Zhang, S Zhong, X Wang, Theoretical and Experimental Research on Terahertz Metamaterial Sensor With Flexible Substrate, IEEE Photonics Journal, 2021, 14 (1), 1-9

19) Y Zhong, Y Huang, S Zhong*, T Lin, M Luo, Y Shen, J Ding, Tunable terahertz broadband absorber based on MoS2 ring-cross array structure, Optical Materials, 2021,114, 110996

20) W Tu, S Zhong, M Luo, Q Zhang, Non-Destructive Evaluation of Hidden Defects Beneath the Multilayer Organic Protective Coatings Based on Terahertz Technology, Frontiers in Physics, 2021, 9, 304

21) G Zhu, F Huang, Z Dai, X Ju, S Zhong, X Wang, Reverse design of on-chip terahertz demultiplexers, Micromachines, 2021, 12 (9), 1093

22) T Lin, Y Huang, S Zhong, M Luo, Y Zhong, Y Yu, J Ding, Sensing Enhancement of Electromagnetically Induced Transparency Effect in Terahertz Metamaterial by Substrate Etching, Frontiers in Physics, 9, 216

23) N. Zhou, S Zhong*, et al., Acoustic-excitation Optical Coherence Vibrometer for Real-time Microstructure Vibration Measurement and Modal Analysis, IEEE Transactions on Instrumentation and Measurement ,2020, 69(9), 7180 - 7190

24) B. Fang, S Zhong*, et al., Full range line-field optical coherence tomography for high-accuracy measurements of optical lens, IEEE Transactions on Instrumentation and Measurement ,2020, 67(6), 1434 - 1445

25) Y. Huang, S. Zhong*, et al., Terahertz Plasmonic Phase-Jump Manipulator for Liquid Sensing, Nanophotonics, 2020, 9(9), 3011¨C3021

26) Q Zhang, S Zhong*, et al., Full-range Fourier-domain optical coherence tomography based on Mach¨CZehnder interferometer, Optics and Lasers in Engineering, 2020, 124, 105794

27) M Luo, S Zhong*, L Yao, W Tu, W Nsengiyumva, W Chen, Thin thermally grown oxide thickness detection in thermal barrier coatings based on SWT-BP neural network algorithm and terahertz technology, Applied optics 59 (13), 4097-4104

28) Q. Zhang, S Zhong*, et al., Anti-noise frequency estimation performance of Hanning-windowed energy centrobaric method for optical coherence velocimeter, Optics and Lasers in Engineering, 2020, 134, 106250

29) Y Huang, S Zhong*, T Shi, YC Shen, D Cui, HR-Si prism coupled tightly confined spoof surface plasmon polaritons mode for terahertz sensing, Optics Express, 2019, 27 (23), 34067-34078

30) Y. Huang, S. Zhong*, et al., Trapping waves with tunable prism-coupling terahertz metasurfaces absorber£¬ Optics Express, 2019, 27 (18), 25647-25655.

31) Q Zhang, S Zhong*, J Lin, J Zhong, Y Yu, Z Peng, S Cheng, High-performance optical coherence velocimeter: theory and applications, Optics Express 27 (2), 965-979, 2019

32) J Zhong, S Zhong*, Q Zhang, S Liu, Z Peng, N Maia, Real-time three-dimensional vibration monitoring of rotating shafts using constant-density sinusoidal fringe pattern as tri-axial sensor, Mechanical Systems and Signal Processing 115, 132-146, 2019

33) Yi Huang, Shuncong Zhong*, Yao¨Cchun Shen, Yingjie Yu, and Daxiang Cui, Terahertz phase jumps for ultra-sensitive graphene plasmon sensing, Nanoscale, 10 (47), 22466-22473, 2018

34) Jianfeng Zhong, Shuncong Zhong*, Qiukun Zhang, Nuno Maia, Yaochun Shen, Shulin Liu, Yingjie Yu, and Zhike Peng, Vision-based system for simultaneous montoring of shaft rotational speed and axial vibration using non-projection composite fringe pattern, Mechanical Systems and Signal Processing, 120, 765-776, 2019

35) J Zhong, Shuncong Zhong*, Q Zhang, Z Peng, Measurement of instantaneous rotational speed using double-sine-varying-density fringe pattern, Mechanical Systems and Signal Processing 103, 117-130, 2018

36) Q Zhang, Shuncong Zhong*, J Zhong, X Fu, Ultrahigh-Accuracy Measurement of Refractive Index Curves of Optical Materials using Interferometry Technology, Measurement, 122, 40-44, 2018

37) W Tu, Shuncong Zhong*, A Incecik, X Fu, Defect feature extraction of marine protective coatings by terahertz pulsed imaging, Ocean Engineering, 173, 58-67, 2019

38) S Zhong, Progress in terahertz nondestructive testing: A review, Frontiers of Mechanical Engineering, 14(3), 273¨C281, 2019

39) Jiewen Lin, Shuncong Zhong*, Qiukun Zhang, Weiqiang Chen, Five-frame Variable Phase-shifting Method for Full-Range Spectral-Domain Optical Coherence Tomography, Applied Sciences, 2018, 8(9), 1580

40) M Luo, S Zhong, Non-Contact Measurement of Small-Module Gears Using Optical Coherence Tomography, Applied Sciences 8 (12), 2490, 2018

41) Y Huang, Shuncong Zhong*, Y Shen, L Yao, Y Yu, D Cui, Graphene/Insulator Stack Based Ultrasensitive Terahertz Sensor with Surface Plasmon Resonance, IEEE Photonics Journal, 9 (6), 1-11, 2017

42) Yi Huang, Shuncong Zhong*, Haizi Yao, and Daxiang Cui, Tunable Terahertz Plasmonic Sensor Based on Graphene/Insulator Stacks, IEEE Photonics Journal, 9 (1), 1-10, 2017

43) Shuncong Zhong*, J. Zhong, Q. Zhang, N. Maia, Quasi-optical coherence vibration tomography technique for damage detection in beam-like structures based on auxiliary mass induced frequency shift, Mechanical Systems and Signal Processing, 93, 241-254, 2017

44) Jianfeng Zhong, Shuncong Zhong*,Qiukun Zhang, Quasi©\OCVT technique for response©\only experimental modal analysis of beam©\like structures, Structural Control and Health Monitoring, 24 (11), 2017

45) H Yao, Shuncong Zhong*, H Yi, D Cui, CL Pan, Handedness-Switchable Optical Chirality in One-Dimensional Periodic Plasmonic-Grooves for Circular Dichroism and Simultaneous Refractive Index Sensing, IEEE Photonics Journal 9 (3), 1-9, 2017

46) Haizi Yao, Shuncong Zhong*, ¡°Handedness-switchable chiral field in the one-dimensional metal grooves for plasmonic circular dichroism spectroscopy¡±, Journal of Optics, 19 (5), 055001, 2017

47) Y Lin, H Yao, X Ju, Y Chen, S Zhong, X Wang, Free-standing double-layer terahertz band-pass filters fabricated by femtosecond laser micro-machining, Optics Express 25 (21), 25125-25134, 2017

48) Jianfeng Zhong, Shuncong Zhong*, Qiukun Zhang, Two-dimensional optical coherence vibration tomography for low-frequency vibration measurement and response-only modal analysis, Mechanical Systems and Signal Processing, 79, 65-71, 2016

49) J. Zhong, Shuncong Zhong* et al., Vibration monitoring using non-projection quasi-interferogram fringe density enhanced by spectrum correction method, ?Measurement Science and Technology, 28(1):015903 , 2016

50) Wanli Tu, Shuncong Zhong*, Yaochun Shen1, and Atilla Incecik, Nondestructive Testing of Marine Protective Coatings Using Terahertz Waves with Stationary Wavelet Transform, Ocean Engineering, 111, 582-592, 2016

51) Haizi Yao, Shuncong Zhong*, Wideband circularly polarized vortex surface modes on helically grooved metal wires, IEEE Photonics Journal, 7 (6), 1-7, 2015

52) Shuncong Zhong*, Qiukun Zhang, Subnanoscale-displacement-resolution Calibration of Piezoelectric Actuators using Enhanced Optical Coherence Tomography, Sensors and Actuators A: physical, 233, 42-46, 2015

53) H Yao, Shuncong Zhong*, W Tu£¬Performance analysis of higher mode spoof surface plasmon polariton for terahertz sensing, Journal of Applied Physics 117 (13), 133104, 2015

54) Jianfeng Zhong, Shuncong Zhong*, Qiukun Zhang, ¡°Two-dimensional optical coherence tomography for real-time structural dynamical characterization¡±, Optics and Lasers in Engineering, 66, 74-79, 2015

55) H. Lin, R. May, M. Evans, Shuncong Zhong, L. Gladden, Y. Shen, J. Zeitler, Impact of Processing Conditions on Inter-tablet Coating Thickness Variations Measured by Terahertz In-Line Sensing, Journal of Pharmaceutical Sciences, 104(8), 2513-22, 2015

56) Haizi Yao, Shuncong Zhong*, Higher-order mode spoof SPP of periodic grooves for high sensitive terahertz sensing, Optics Express, 2014, 22(21): 25149-25160.

57) Wanli Tu, Shuncong Zhong*, Yaochun Shen, Qing Zhou and Ligang Yao, FDTD-Based Quantitative Analysis of Terahertz Wave Detection for Multilayered Structures, Journal of the Optical Society of America A , 31(10), 2285-2293 (2014)

58) Haizi Yao, Shuncong Zhong*, ¡°Plasmonic corrugated cylinder-cone terahertz probe¡±, Journal of the Optical Society of America A, 31(8), 1856-1860, 2014

59) Haizi Yao, Shuncong Zhong*, ¡°Frequency dependent circular-polarization of terahertz chiral spoof surface plasmon polariton on helically grooved metallic wire¡±, Optics Communications, 2015

60) Shuncong Zhong, Y.Shen, L. Ho, R. May, J. Zeitler, M. Evans, P. Taday, M. Pepper, T. Rades, K. Gordon, R. Muller, and P. Kleinebudde, ¡°Nondestructive quantification of pharmaceutical tablet coatings using terahertz pulsed imaging and optical coherence tomography¡±, Optics and Lasers in Engineering, 49(3), 361-365, 2011.

61) Shuncong Zhong, Hao Shen, and Yaochun Shen, ¡°Real-time monitoring of structural vibration using spectral-domain optical coherence tomography¡±, Optics and Lasers in Engineering, 49(1), 127-131, 2011.

62) R.K. May, M. J. Evans, Shuncong Zhong, I. Warr, L.F. Gladden, Y.C. Shen and J.A. Zeitler, Terahertz in-line sensor for direct coating thickness measurement of individual tablets during film coating in real-time, Journal of Pharmaceutical Sciences, 100(4), 1535-1544, 2011

63) R.K. May, K. Su, L. Han, Shuncong Zhong, J. A. Elliott, L. F. Gladden, M. Evans, Y. C. Shen, and J. A. Zeitler, Hardness and Density Distributions of Pharmaceutical Tablets Measured by Terahertz Pulsed Imaging, Journal of Pharmaceutical Sciences (DOI: 10.1002/jps.23560)

64) Shuncong Zhong, S Olutunde Oyadiji, ¡°Crack sensitivity analysis of sampling interval for damage detection by wavelet transform¡±, Structural Control and Health Monitoring, 20(1), 2013

65) Shuncong Zhong, S. O. Oyadiji, ¡°Detection of cracks in simply-supported beams by continuous wavelet transform of reconstructed modal data¡±, Computers and Structures, 89,127-148, 2011.

66) Shuncong Zhong, S. O. Oyadiji, ¡°Crack Detection in Simply Supported Beams using Stationary Wavelet Transform of Modal Data¡±, Structural Control and Health Monitoring, 18(2), 169-190, 2011.

67) Shuncong Zhong, S Olutunde Oyadiji, ¡°Analytical predictions of natural frequencies of cracked beams with a traversing auxiliary mass¡±, Journal of Sound and vibration, 311, 328-352, 2008

68) Shuncong Zhong, S Olutunde Oyadiji, ¡° Response-only method for damage detection of beam-like structures using high accuracy frequencies¡±, Journal of Sound and Vibration , 311, 1075-1099, 2008

69) Shuncong Zhong, S Olutunde Oyadiji, ¡°Identification of cracks in beams with auxiliary mass spatial probing by stationary wavelet transform¡±, Trans. of ASME, Journal of Vibration and Acoustics, 30, 1-14, 2008

70) Shuncong Zhong, S Olutunde Oyadiji, ¡°Crack detection in simply-supported beams without modal parameter using stationary wavelet transform¡±, Mechanical Systems and Signal Processing, 21(4) , 1853-1884, 2007

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