2023年

[1] Qichen Tian, Yuanbin She, Yangguang Zhu, Dan Dai, Mingjiao Shi, Wubo Chu, Tao Cai, Hsu-Sheng Tsai, He Li, Nan Jiang, Li Fu, Hongyan Xia*, Cheng-Te Lin* and Chen Ye*. Highly Sensitive and Selective Dopamine Determination in Real Samples Using Au Nanoparticles Decorated Marimo-like Graphene Microbead-Based Electrochemical Sensors. Sensors 2023, 23, 2870.

[2]Jiajun Hu, Jing Qin, Ziyi Zhou, Zhongqi Shi, Kang Peng, Kai Gao, Hongyan Xia*. Facile synthesis of BP powder via molten salt method and their photoelectrochemical properties[J]. (Doi: 10.1016/j.ceramint.2023.01.050)

[3]Jiajun Hu, Tianran Zhang, Laili Wang, Zhongqi Shi*, Hongyan Xia*. Constructing sandwich–structured poly(vinyl alcohol) composite films with excellent thermal conductive and electrical performance[J]. (Doi: 10.1021/acsami.2c20668)

2022年

[1]Jiajun Hu; Xinguang Hou; Ting Yang; Yi Wang; Kang Si; Hongyan Xia*. Thermal management performance of polyvinyl alcohol composite with boron phosphide decorated reduced graphene oxide[J]. Composites Part A, 2022, 155: 106847. (SCI: 000793797700003)

[2]胡佳军，王凯，侯鑫广，杨婷，夏鸿雁*. 熔盐法合成高导热磷化硼及其热管理性能研究[J]. 无机材料学报，2022, 37(09): 933–940. (SCI: 000855187600002EREF)

2021年

[1]Jiajun Hu; Hongyan Xia*; Xinguang Hou; Ting Yang; Kang Si; Yi Wang; Laili Wang; Zhongqi Sh i ; Enhanced thermal management performance of nanofibrillated cellulose composite with highly th ermally conductive boron phosphide, Journal of Materials Chemistry A, 2021, 9(47): 27049-27060

[2] Hongyan Xia*; Jiajia Li; Kai Wang; Xinguang Hou; Ting Yang; Jiajun Hu; Zhongqi Shi ; Super ior wear resistance of epoxy composite with highly dispersed graphene spheres, Advanced Composite s and Hybrid Materials, 2021, /: /

2020年

[1]Jiajia Li, Jiajun Hu, Kai Wang, Hongyan Xia*. Coal slime waste: a promising precursor to develop highly porous activated carbon for  supercapacitors. Carbon Letters  https://doi.org/10.1007/s42823-020-00138-w

[2]J. Hu, J. Li, K. Wang, H.Y. Xia*. Self-assembly Nb2O5 microsphere with hollow and  carbon coated structure as high rate capability lithium-ion electrode materials. Electrochimica Acta 331 (2020) 135364

[3]H. Xu, Y. Wang, R. Chen, Y. Bai, T. Li, H. Jin*, J.P. Wang*, H.Y. Xia*. A green-synthetic spiderweb-like Si@Graphene-oxide anode material with multifunctional citric acid binder for high energy-density Li-ion batteries. Carbon 157 (2020) 330-339.

2019年

[1] B.Z Ge, J.B. Z.Q. Shi, H.L. Wang, H.Y. Xia, G.J. Qiao. Integration of multi-scale defects for optimizing thermoelectric properties of n-type Cu1-xCdxFeS2 (x=0-0.1). Nanoscale 11(2019) 17340-17349.

[2] B.Z. Ge, Z.Q. Shi*, C.J. Zhou, J.B. Hu, G.W. Liu, H.Y. Xia, J.T. Xu, G.J. Qiao. Enhanced thermoelectric performance of n-type eco-friendly material Cu1-xAgxFeS2 (x=0-0.14) via band gap tuning. Journal of Alloys and Compounds 809 (2019) 151717

[3] H.Y. Xia*, J.J. Hu, J.J. Li, K. Wang. Electrochemical performance of graphene-coated activated mesocarbon microbeads as a supercapacitor electrode. RSC Adv. 9 (2019)7004–7014.

[4]B.Z. Ge, J.B. Hu, Q. Wang, H.Y. Xia, S.J. Xu, Z.Q. Shi. Cu1.75Te nanowires as building blocks to fabricate bulk materials with enhanced thermoelectric performance. DOI: 10.1080/10667857. 2019.169927

[5] N. A. Rongione, M. Li, H. Wu, H. D. Nguyen, J. S. Kang, B.Y. Ouyang, H.Y. Xia, Y.J. Hu. High- Performance Solution-Processable Flexible SnSe Nanosheet Films for Lower Grade Waste Heat Recovery. Adv. Electron. Mater. 2019, 5, 1800774.

[6] M. Li, Z.H. Qin, Y. Cui, C.Y. Yang, C.Y. Deng, Y.B. Wang, J. S. Kang, H.Y. Xia, Y.J. Hu. Ultralight and Flexible Monolithic Polymer Aerogel with Extraordinary Thermal Insulation by A Facile Ambient Process. Adv. Mater. Interfaces 2019, 6, 1900314.

2018年

[1] Y.Y. Zhao, W.M. Wang, H.Y. Xia, J.P. Wang. Preparation of siliconized graphite by liquid silicon infiltration of porous carbon materials.  Materials Science Forum 922(2018)55-61.

[2] X.Y. Zhang, Z.Q. Shi* , X. Zhang, K. Wang, Y.Y. Zhao, H.Y. Xia, J.P. Wang. Three dimensional AlN skeleton-reinforced highly oriented graphite flake composites with excellent mechanical and thermophysical properties. Carbon 131 (2018) 94-101.

2017年

[1] K. Zhang, Z. Shi, X. Zhang, Z. Zhang, B. Ge, H. Xia, Y. Guo, G Qiao. Molten salt synthesis of continuous tungsten carbide coatings on graphite flakes. Ceramics International 43(2017) 8089-8097

[2] H Jin, Z Shi, X Li, Y Li, H Xia, Z Xu, G Qiao. Effect of rare earth oxides on the microstructure and properties of mullite/hBN composites. Ceramics International 43(2017) 3356-3362

[3] H. Jin, Y.F. Li, Z.Q. Shi, H.Y. Xia, G.J. Qiao. Effect of Y2O3 on the sintering, mechanical and dielectric properties of mullite/h-BN composites. Materials Science Forum 848 (2017) 28-31

2016年

[1] H.Y Xia, K. Wang, S.H. Yang, Z.Q. Shi, H.J. Wang, J.P. Wang. Formation of graphene flowers during high temperature activation of mesocarbon microbeads with KOH. Microporous and Mesoporous Materials 234 (2016) 384-391.

[2] K. Zhang, Z.Q. Shi, H.Y. Xia, K. Wang, G.W. Liu, G.J. Qiao, J.F.Yang. Preparation and thermophysical properties of directional SiC/Cu-Si composite via spontaneous infiltration. Ceramics International 42(2016)996-1001.

[3] C. Wang, M. Chen, H. Wang, X. Fan, H.Y. Xia. Fabrication and thermal shock resistance of multilayer γ-Y2Si2O7 environmental barrier coating on porous Si3N4 ceramic. Journal of the European Society 36(2016)689–695

[4] X. Fan, H. Wang, M. Niu, L. Su, D. Zhang, J. Zhou, J. Fan, J. Shi. Effects of different sintering additives on the synthesis of γ-Y2Si2O7 powders. Ceramics International 42(2016) 14813-14817

2015年

[1] H.Y. Xia, X. Zhang, Z.Q. Shi, et al. Mechanical and thermal properties of reduced graphene oxide reinforced aluminum nitride ceramic composites. Mater. Sci. Eng. A 639(2015) 29-36.

[2] C.Y. Ni, R. Hou, H.Y. Xia*, et al. Perforation resistance of corrugated metallic sandwich plates filled with reactive powder concrete: Experiment and simulation. Composite Structures 127(2015) 426–435.

[3] K. Wang, C.J. Zhou, D. Xia, Z.Q. Shia, ,C. He, H.Y. Xia, et al. Component-controllable synthesis of Co(SxSe1−x)2 nanowires supported by carbon fiber paper as high-performance electrode for hydrogen evolution reaction. Nano energy 18(2015)1-11.

[4] Y.Y. Shao, H.Y. Xia, R. Tang, Z.Q. Shi, J.F. Yang, J.P. Wang. A low cost preparation of C/SiC composites by infiltrating molten Si into gelcasted pure porous carbon preform. Ceramics International  2015,41:(5)6478-6487.

[5] K. Zhang, H.Y. Xia, B. Wang, Z.Q. Shi, X.Z. Zhang, G.W. Liu, G.J. Qiao. Preparation and thermal-physical properties of three dimensional bicontinuous SiC/Cu-Si composite. Materials Science Forum 2015,804:187-190

[6] K. Wang, Z.Q. Shi, Y.Y. Wang, Z.G. Ye, H.Y. Xia, G.W. Liu, G.J. Qiao. Co3O4 nanowires@MnO2 nanolayer or nanoflakes core-shell arrays for high-performance supercapacitors: the influence of morphology on Performance. Journal of Alloys and Compounds 2015,624:85-93.

[7] K. Wang, D. Xi, C.j. Zhou, Z.Q. Shi, H.Y. Xia, G.W. Liu, G.J. Qiao. CoSe2 necklace-like nanowires supported by carbon fiber paper: a 3D integrated electrode for the hydrogen evolution reaction. Journal of Materials Chemistry 3(2015) 9415-9420.

[8] C. Wang, H. Wang, X. Fan, J. Zhou, H.Y. Xia, J Fan. Fabrication of dense β-Si 3 N 4-based ceramic coating on porous Si 3 N 4 ceramic. 35(2015)1743–1750.

2014年

[1] H.Y.Xia, W.B. Wang, Z.Q.Shi. Mechanical properties of reactive powder concrete with ultra-short brass-coated steel fibres. Magazine of Concrete Research 67(2014)308-316.

[2] 夏鸿雁, 侯润等. 高性能混凝土填充金属三明治夹层波纹板的抗侵彻性能. 硅酸盐学报 42(2014)75-78.

[3] H.C. Shao, H.Y. Xia*, G.W. Liu, G.J. Qiao, Z.C. Xiao, J.M. Su, et al. Densification Behavior and

Performances of C/C Composites Derived from Various Carbon Matrix Precursors. Journal of Materials Engineering and Performance 23(2014): 133–141.

[4] M. Chen, C. Wang, H.J. Wang, L.Fan, H.Y. Xia, Z.Q. Shi. Fabrication of hierarchically porous Si3N4 foam ceramics with stamen-like cell structure. Materials Letters 128(2014)156-159.

2013年

[1] H.Y. Xia, J.P. Wang, J.P. Lin, G.W. Liu, G.J. Qiao. Thermal conductivity of SiC ceramic fabricated by liquid infiltrating molten Si into mesocarbon microbeads–based preform. Mater. Charact. 82(2013) 1–8.

[2] H.Y. Xia, J.P. Wang, Z.Q. Shi, G.J. Qiao. Reciprocating friction and wear properties of mesocarbon microbeads–based graphite and siliconized graphite. J. Nucl. Mater. 433(2013) 341–344.

[3] H.Y. Xia, G.J. Qiao, S.L. Zhou, J.P. Wang. Reciprocating friction and wear behavior of reaction–formed SiC ceramic against bearing steel ball. Wear 303(2013)276 – 285.

2012年及以前

[1] H.Y. Xia, J.P. Wang, Z.Q. Shi, G.W. Liu, G.J. Qiao. Sliding wear behavior of mesocarbon microbeads based carbon materials. Wear 274– 275(2012) 260–266.

[2] H.Y. Xia, J.P. Wang, B. Huang, et al. The influence of ball-milling on improving the performance of mesocarbon microbeads based carbon blocks. Mater. Sci. Eng. A 529(2011)282-288.

[3] H.Y. Xia, J.P. Wang, G. Liu , et al. Effect of nano-SiC on the sintering behavior and properties of calcined carbon derived from mesocarbon microbeads. J. Nucl. Mater. 403 (2010)42-47.

[4] H.Y. Xia, J.P. Wang, H. Jin, et al. Fabrication and properties of reaction-formed SiC by infiltrating molten Si into mesocarbon microbeads-based carbon preform. Mater. Sci. Eng. A 528(2010) 283-287.

[5]夏鸿雁, 王继平, 黄斌, 乔冠军. 中间相炭微球为炭源反应形成SiC陶瓷及其结构与性能[J]. 固体火箭技术. 2011,34(4):514-519.