Paper Publications

• [16] Liang ZP, Wang MY, Liu SW, Hassan M, Zhang XZ, Lei SY, Qiao GJ, Liu GW*, One-pot hydrothermal synthesis of self-assembled MoS2/WS2 nanoflowers for chemiresistive room-temperature NO2 sensors, Sensors and Actuators B: Chemical, 2024, 403: 135215.
• [17] Hassan M, Liang ZP, Liu SW, Hussain S, Qiao GJ, Liu GW*, Temperature-driven n- to p-type transition of a chemiresistive NiO/CdS-CdO NO2 gas sensor, Sensors and Actuators B: Chemical, 2024, 398: 134755.
• [18] Ge CX, Jin CC, Wang MS*, Bai L, Hussain S, Qiao GJ, Kim EJ, Liu GW*, Template-derived net-like SnO2 nanoarrays for robust H2S sensing with broad-range linear response，Sensors and Actuators B: Chemical, 2022, 366: 131991
• [19] Liu SW, Wang MY, Ge CX, Lei SY, Hussain S, Wang MS, Qiao GJ, Liu GW*, Enhanced NO2 room temperature sensing performance of SnO2/Ti3C2 composite with double heterojunctions by controlling co-exposed {221} and {110} facets of SnO2, Sensors and Actuators B: Chemical, 2022, 365: 131919.
• [20] Tan J, Hussain S*, Ge CX, Wang MS, Shah S, Liu GW*, Qiao GJ, ZIF-67 MOF-derived Unique Double-shelled Co3O4/NiCo2O4 Nanocages for Superior Gas-sensing Performances, Sensors and Actuators B: Chemical, 2020: 303: 127251.
• [21] Amu-Darko JNO, Hussain S*, Agyekum EA, Begi AN, Shah S, Yusuf K, Manavalan RK, Qiao GJ, Liu GW*. Low-temperature NO2 gas-sensing system based on metal-organic framework-derived In2O3 structures and advanced machine learning techniques, Inorganic Chemistry, 2024, 63(35): 16429–16441.
• [22] （2）陶瓷高温润湿与钎焊方面的代表作：
• [23] Zhang X, Zhang Y, Wang C, Guo Q, Liu G*, Qiao G*. Enhanced Ag-Nb2O5/SiC wetting and brazing by SiC pre-oxidation: Experiments and first-principles study, Journal of the American Ceramic Society, 2025, accepted
• [24] Zhang MF, Xu SJ, Valenza F, Zhang XZ, Liu GW*, Qiao GJ*, Advances in reactive air wetting and brazing of engineering ceramics, Journal of Advanced Ceramics, 2025, 14: 9220977.
• [25] Guo QH, Xu SJ, Zhang XZ*, Gui XY, Qiu YD, Guo ZY, Zhou Y, Wan H, Qiao GJ*, Liu GW*, Microstructures and interfacial behavior of Ag-CuO/AlN system by air wetting and brazing: Experiments and first-principles calculations,Journal of the European Ceramic Society, 2024, 44(8): 4963–4974.
• [26] Qiu YD, Xu SJ, Zhang XZ*, Zhang MF, Guo QH, Wang BJ, Qiao GJ, Liu GW*, Reactive air wetting and brazing of Al2O3 ceramic using Ag-Nb2O5 filler: Performance and interfacial behavior, Journal of Advanced Ceramics, 2024, 13(2): 135‒142.
• [27] Gui XY, Zhang MF, Xu PH, Liu GW*, Guo GH, Zhang XZ*, Meng HN, Qiao GJ, Experimental and theoretical study on air reaction wetting and brazing of Si3N4 ceramic by Ag-CuO filler metal: Performance and interfacial behavior, Journal of the European Ceramic Society, 2022, 42: 432‒441
• [28] Zhang XZ, Xu PH, Wu XY, Gui XY, Liu GW*, Zhang MF, Meng HN, Qiao GJ*, Insight into the wetting and interfacial behavior of Cu-Ti/ZrB2 system: A combined experimental and DFT calculation, Journal of the European Ceramic Society, 2021: 41(13): 6213‒6222
• [29] Liu GW*, Zhang XZ, Yang J, Qiao GJ. Recent advances in joining of SiC-based materials (monolithic SiC and SiCf/SiC composites): Joining techniques, joint strength and interfacial behavior, Journal of Advanced Ceramics, 2019, 8(1): 19–38. （入选2021年度《先进陶瓷（英文）》优秀论文）
• [30] Zhang XZ, Liu GW*, Tao JN, Guo YJ, Wang JJ, Qiao GJ*，Brazing of WC–8Co cemented carbide to steel using Cu–Ni–Al alloys as filler metal: Microstructures and joint mechanical behavior, Journal of Materials Science & Technology, 2018, 34(7): 1180-1188.