1. GaN纳米线集成传感器

从材料与工艺，解决纳米线的制备工艺与可靠性问题。创新：桥接生长 —— 转为平面生长，与IC平面工艺兼容；无需排列组装，消除电极和损伤问题。GaN材料 —— 第3代半体，耐高温、耐腐蚀、压电性。

2. GaN电化学传感器

通过引入氮空位，首次让GaN具有“优异的化学催化活性”与“超高的电导率”；催化效果超过传统的Bi等贵金属，其电导率比现有n型GaN产品高出近一个数量级。所研制的GaN电化学传感器，检测限达50nM（比现有技术改善了几十倍），寿命可达2年以上（与现有产品相当）。

3. 毛细管荧光仪

激光诱导荧光仪(LIF)是最灵敏的液体痕量检测手段之一，其检测限可低于1pM。发明的“针孔金属毛细管LIF”，可抑制激光泄露导致的背景噪声，因此能够采用便宜微型的“半导体激光器”取代昂贵笨重的“氩离子激光器”。与主流产品（ZetaLIF）相比，成本和体积降低十倍以上，功耗降低一百倍，检测限改善2.5倍。

4. 新型光纤传感器

纤水听器广泛用于水下声波探测，现有产品是基于长臂干涉的相位检测原理，系统昂贵笨重。发明的新型强度检测技术，克服了强度检测的敏度低痼疾，使其灵敏度可媲美相位检测；而且，与相位检测相比，具有响应频带宽、抗加速度干扰、系统小巧便宜（体积缩小近千倍）的优势。

部分发表论文

2023年

1. Weicheng Cai , Zhaolin Li, Hui Huang*, Xuejing Li, Jian Zhao, Pengbo Liu, Yajun Wu, Mingchang Liu, and Jian Wang, “A Compact UV-LED-Induced Fluorescence With Short Metal Capillary and Low Light Leakage: Application to Noninvasive Glucose Detection”, IEEE Sensors Journal, vol. 23, no. 8, pp. 8366-8374, 15 April, 2023, doi: 10.1109/JSEN.2023.3257834. 

2. Chenyang Liu, Ruichen Shang, Hui Huang*, Mengyuan Wang, Jian Zhao, Pengbo Liu, Zengbing Jin, “UV-activated SnO2 thin flm for air-atmospheric oxygen sensing at room temperature”, Physica E, 151 (2023) 115733.

3. Zhirui Li , Hui Huang*, Danna Zhao, and Shunji Chen, “A Reliable Strain Sensor Based on Bridging GaN Nanowires”, IEEE Sensors Journal, vol. 23, no. 1, pp. 189-194, 1 JANUARY, 2023

4. Xuejing Li, Hui Huang, WeiCheng Cai, “Enhancing the optical path inside a capillary without sacrificing light intensity: application to a compact and highly sensitive photometer”, Optics Express, vol. 31, no. 5, 7983-7993, 27 Feb, 2023.  

2022年

1. Shunji Chen, Hui Huang*, Haiming Sun, Qiunan Liu, Huichao Zhu, Jian Zhao, Pengbo Liu, and Jun Yu, “Electrochemical sensor made with 3D micro-/mesoporous structures of CoNi-N/GaN for noninvasive detection of glucose”, ACS Applied Materials & Interfaces, 2022, 14, 49035−49046

2021年

1. J. Zhou, H. Huang*, S. Chen, M. Wang, D. Zhao, J. Yu,S. Jin, Y. Zhong, X. Chen, X. Yu, P. Liu, J. Zhao*, “A high sensitive chemiresistive-biosensor based on self-assembly grown GaN porous layer”, Sensors & Actuators: B, 345 (2021) 130360.  

2. Xuejing Li, Hui Huang*, Weicheng Cai, Min Bai, Jian Zhao, Pengbo Liu, Changkai Sun,Zengbin Jin, “A compact and high sensitive photometer based on axial multi-reflectioninside metal capillary: Application to detecting nitrite of nanomolarconcentration”, Optics and Lasers in Engineering, 2021, 146, 106705.

3. Weicheng Cai, Hui Huang*, Zhibo Yang, Ruichen Shang, Xuejing Li, Chi Ma, Jian Zhao,Pengbo Liu, Jian Wang, Wei Wang, “A compact, low-cost and high sensitive LIF based on pinholemetal-capillary and direct laser-diode excitation”, Optics and Lasers in Engineering, 2021, 139, 106488. 

2020年

1. Shunji Chen, Hui Huang*, Danna Zhao, Jialing Zhou, Jun Yu, Bo Qu, Qiunan Liu, Haiming Sun,and Jun Zhao, “Direct growth of polycrystalline GaN porous layer with rich nitrogen vacancies: application to catalyst-free electrochemical detection”, ACS Applied Materials & Interfaces, 2020, 12 (48), 53807-53815. 

2019年

1. Danna Zhao, Hui Huang*, Shunji Chen, Zhirui Li, Shida Li, Mengyuan Wang, Huichao Zhu,and Xiaoming Chen, “In situ growth of leakage-free direct-bridging GaN nanowires: application to gas sensors for long-term stability, low power consumption, and sub-ppb detection limit”, Nano Letters, 2019, 19, 3448-3456.

2. Min Baia, Hui Huang*, Zhe Liu, Tingting Zhan, Shufeng Xia, Xiaogan Li, Nickolay Sibirev,Alexei Bouravleuv, Vladimir G. Dubrovskii, George Cirlin, “InAs/InP core/shell nanowire gas sensor: Effects of InP shell on sensitivityand long-term stability”, Applied Surface Science, 498 (2019) 143756.

3. Yang Zonga, Hui Huang*, Danna Zhao, Zhenan Tang,“In situ control of nanowire resistance with real time monitoring by using selfheating induced oxidation”,Current Applied Physics, 20 (2020) 871-876.

4. Siyu Xu, Hui Huang*, Weicheng Cai, Yuan Zhong, Dongsheng Li, Xiaoming Chen,and Jiangwei Zhuang, “Compact, low-cost, and highly sensitive opticalfiber hydrophone based on incident angle sensing”, Applied Optics,vol. 58, no. 28, 7774, 2019.

5. N. V. Sibirev, H. Huang,E. V. Ubyivovk,R. Lv,D. Zhao,Q. Guang,Yu. S.Berdnikov, X. Yan, A. A. Koryakin, I. V. Shtrom, "Growth of GaN Nanotubes and Nanowires on Au–Ni Catalysts",Tech. Phys. Lett. (2019) 45: 159-162.

2018年

1. Weiming Wang, Yan Yu*, Hui Huang*, “A portable high-resolution microscope based on combination of fiber-opticarray and pre-amplification lens”, Measurement, 2018, 125, 371-376. 

2017年

1. Jie Hu, Hui Huang*, Min Bai, TingTing Zhan, ZhiBo Yang, Yan Yu, and Bo Qu,“A high sensitive fiber-optic strain sensor with tunable temperature sensitivity for temperature-compensation measurement”, Scientific Reports, 7, 42430(2017).

2. Danna Zhao, Hui Huang*, Rui Lv, Shunji Chen, Qiyilan Guang, Yang Zong, Zhe Liu, and Xiqing Li, “Controlled growth of aligned GaN nanostructures: from nanowires and needles to micro-rods on a single substrate”, RSC Adv.,2017, 7, 50781

3. Jiqing Y., Yue Z., Hui Huang*, Jian W., Zhou J., Min B., “Highly sensitive detection of thrombin using metal-waveguide-capillary based photometer and gold nanorods probe”, Sensors and Actuators B: Chemical, 243 (2017) 1255–1260.

2016年之前代表性论文

1. Min Bai,Hui Huang*, Yan Yu, Jian Hao, Ji Zhang, Jianchao Fan, and Jun Yan, “Trace analysis of oil-in-water by using visible LED and metal waveguide capillary”, Optics Express, 24, 14538-14545 (2016).

2. Yang Zong, Hui Huang*, Wenbin Song, Rui Lv, Danna Zhao, Zhe Liu, Qiyilan Guang, Jingwei Guo, and Zhenan Tang, “Growth of oriented GaN nanowires by controlling nucleation conditions”, Cryst. Res. Technol., 51(12), 757–761 (2016).

3. Min Bai, Hui Huang*, Jian Hao, Ji Zhang, Haibo Wu, and Bo Qu, “A compact photometer based on metal-waveguide-capillary: application to detecting glucose of nanomolar concentration”, Scientific Reports, 5, 10476 (2015).

4. 4. Pengbo Liu, Hui Huang*, Xueyu Liu, Min Bai, Danna Zhao, Zhenan Tang, Xianliang Huang, Ji-Yeun Kim, and Jinwei Guo, “Core-shell nanowire diode based on strain-engineered bandgap”, Phys. Status Solidi A,Vol.212, No.3, 617–622 (2015).

5. Haibo Wu, Hui Huang*, Min Bai, Pengbo Liu, Ming Chao, Jie Hu, Jian Hao, and Tun Cao, "An ultra-low detection-limit optofluidic biosensor based on all glass Fabry-Perot cavity", Optics Express, 22, 31977-31983 (2014). 

6. P. Liu,Hui Huang*,T. Cao,X. Liu,Z. Qi,Z. Tang,and J. Zhang, "An ultra-low detection-limit optofluidic biosensor with integrated dual-channel Fabry-Pérot cavity", Appl. Phys. Lett., 102, 163701 (2013).