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创造、创新、创业

Creation, innovation and Entrepreneurship

副高级专业技术职称

刘辉东

分类:院内新闻 作者: 来源: 时间:2021-03-04 访问量:

一、个人基本情况

姓名:刘辉东

学历:博士

性别:男

职称:特聘副研究员、硕士生导师

电子邮箱:liuhuidong30@whu.edu.cn

二、学习及工作经历

(1)教育经历

2008.09-2012.06,武汉大学金属材料工程专业,工学学士

2012.09-2018.06,武汉大学热能工程专业,工学博士

(2)工作经历

2018.07-2021.06,武汉大学新普京澳门娱乐场app网站,博士后

2021.07-至今,武汉大学新普京澳门娱乐场app网站,特聘副研究员

三、学术和社会兼职

Nano Letters, Nano Energy, Applied Energy, Solar Energy Materials and Solar Cells等国际知名期刊审稿人

四、主要研究方向

异质介质中辐射传输基础理论

热光伏系统及储能技术

五、主教课程

《新能源科学与技术》

六、科研成果

(1)代表性论文

[1] H.D. Liu#, Z. Huang#, K. Liu*, X.J. Hu*, J. Zhou*. Interfacial Solar-to-Heat Conversion for Desalination [J]. Advanced Energy Materials 2019, 9(21): 1900310. (IF=21.87)

[2] H.D. Liu#, C.Y. Wang#, G.R. Chen#, K. Liu*, J. Chen*. Moisture assisted photo-engineered textiles for visible and self-adaptive infrared dual camouflage [J]. Nano Energy, 2022, 93: 106855.IF= 16.60

[3] C.Z. Feng#, P.H. Yang#, H.D. Liu# (共同一作), H.J. Fan*, K. Liu*, et al, Bilayer Porous Polymer for Efficient Passive Building Cooling [J]. Nano Energy, 2021, 85: 105971.IF= 16.60

[4] H.D. Liu, X.T. Zhang, B. Yang, X. Liu, H.F. jiang*, X.J. Hu*, et al. A bioinspired capillary-driven pump for solar vapor generation [J]. Nano Energy, 2017, 42:115-121.IF= 12.34

[5] L. Huang, Y.P. Wang, H.D. Liu*, K. Liu, X.J. Hu*, et al. Solar-driven co-generation of electricity and water by evaporation cooling [J]. Desalination 2020, 488: 114533. (IF=7.01)

[6] D. Yang, X. Zhao, Y Liu, J.Y. Li, H.D. Liu*, B. Yang*, et al. Enhanced thermal stability of solar selective absorber based on nano-multilayered AlCrSiO films [J]. Solar Energy Materials & Solar Cells 2020, 207: 110331. (IF=6.98)

[7] L. Huang, H.F. Jiang, Y.P. Wang, Z.Q. Ouyang, B. Yang, H.D. Liu*, X.J. Hu*, et al. Enhanced water yield of solar desalination by thermal concentrated multistage distiller [J]. Desalination 2020, 477: 114260. (IF=7.01)

[8] H.D. Liu, T.R. Fu, B. Yang*, X.J. Hu*, et al. Structure and thermal stability of spectrally selective absorber based on AlCrON coating for solar-thermal conversion applications [J]. Solar Energy Materials & Solar Cells, 2016, 157:108-116.IF=4.78

[9] H.D Liu, B. Yang*, X.J. Hu*, et al. Optimization of AlCrO-based absorber with Mo infrared reflector for solar selective applications [J]. Vacuum, 2016, 128:27-33.IF=1.53

[10] H.D. Liu, X.J. Hu, Yang B*, et al. Long-term thermal stability of CrAlO-based solar selective absorbing coating in elevated temperature air [J]. Solar Energy Materials & Solar Cells, 2015, 134:261-267.IF=4.73

[11] H.D. Liu, Q. Wan, B. Yang*, et al. The spectral properties and thermal stability of CrAlO-based solar selective absorbing nanocomposite coating [J]. Solar Energy Materials & Solar Cells, 2014, 122(3):226-232.IF=5.34

[12] P.H. Yang, C.Z. Feng, Y.P. Liu, T. Cheng, X.L. Yang, H.D. Liu, K. Liu, H.J. Fan. Thermal Self-Protection of Zinc-Ion Batteries Enabled by Smart Hygroscopic Hydrogel Electrolytes [J]. Advanced Energy Materials 2020, 10(48): 2002898. (IF=25.2)

[13] H.Q. Jiang, L. Tong, H.D. Liu, J. Xu, S.Y. Jin, C. Wang, X.J. Hu, L. Ye, H.X. Deng, G.J. Cheng. Graphene-Metal-Metastructure Monolith via Laser Shock-Induced Thermochemical Stitching of MOF Crystals [J]. Mater 2020, 2:1535-1549.

[14] R.Y. Wang, H.D. Liu, B. Yang*, et al. Unconventional gas-based bottom-up, meter-area-scale fabrication of hydrogen-bond free g-CN nanorod arrays and coupling layers with TiO2 toward high-efficiency photoelectrochemical performance[J]. Nanoscale, 2018, 10:3342-3349. (IF=7.367)

[15] C.Z. Li, K. Liu, H.D. Liu, et al. Capillary driven electrokinetic generator for environmental energy harvesting [J]. Materials Research Bulletin, 2017, 90: 81–86. (IF=2.435)

[16] Q. Wan, Y.M. Chen, H.D. Liu, B. Yang*, et al. Microstructure and mechanical properties of 3-D Ti-Si-N bulk materials synthesized by spark plasma sintering [J]. Journal of Alloys & Compounds, 2016, 674:131-135. (IF=3.133)

[17] Q. Wan, B. Yang, H.D. Liu, Q.S. Mei, Y.M Chen, et al. Ion irradiation tolerance of Ti-Si-N nanocomposite coating [J]. Surface & Coatings Technology, 2016, 305:165-169. (IF=2.589)

[18] Q. Wan, H. Ding, M.I. Yousaf, Y.M. Chen, H.D. Liu, L.W. Hu, B. Yang*. Corrosion behaviors of TiN and Ti-Si-N coatings by electrochemical impedance spectroscopy [J]. Thin Solid Films, 2016, 616:601-607. (IF=1.879)

[19] D.Q. Gong, H.D. Liu, G. Luo, et al. Thermal aging test of AlCrNO-based solar selective absorbing coatings prepared by cathodic arc plating [J]. Solar Energy Materials & Solar Cells, 2015, 136:167-171.IF=4.732

[20] Y.R. Xu, H.D. Liu, Y.M. Chen, et al, In situ synthesized TiC-DLC nanocomposite coatings on titanium surface in acetylene ambient [J]. Applied Surface Science 349 (2015) 93-100. (IF=3.387)

[21] B. Yang, C.X. Tian, Q. Wang, S.J. YanH.D. Liu, et al. Synthesis and characterization of AlTiSiN/CrSiN multilayer coatings by cathodic arc ion-plating [J]. Applied Surface Science, 2014, 314(10):581-585. (IF=3.387)

(2)发明专利

[1] 一种结合辐射制冷和发汗冷却的复合薄膜,ZL202010293419.6  (实审)

[2] 一种智能红外与可见光双波段伪装薄膜及其制备方法,ZL202010173658.8  (授权)

[3] 太阳能电池发汗冷却及多级海水淡化耦合系统,ZL201811613428.8   (实审)

[4] 一种太阳能全光谱利用的水电联产系统,ZL201811205107.4  (实审)

[5] 太阳能热聚焦毛细驱动多级海水淡化系统,ZL 201811204287.4  (授权)

[6] 风光互补耦合海水淡化装置,ZL201710331371.1 (授权)

[7] 多能耦合的海水淡化系统,ZL201710330940.0  (授权)

[8]  一种双相纳米复合太阳能吸收涂层及制造方法,ZL201610931796.1 (授权)

[9]  一种纳米复合Cr-Al-O太阳光谱选择吸收涂层及其制备方法,ZL201310189629.0(授权)

七、科研项目

[1] 过渡金属氮化物纳米晶多层复合陶瓷薄膜的结构调控及光谱选择性吸收机理 国家自然科学基金委员会,青年基金项目,520022912021.01-2023.12

[2] 高温热稳定陶瓷纳米晶复合涂层的光谱选择吸收特性研究 全国博士后管理委员会,博士后创新人才支持计划,BX201902542019.07-2021.06

[3] 基于调幅分解的TiAlN纳米复合涂层辐射特性研究 中国博士后科学基金委员会,面上项目,2019M6527042019.01-2020.12