个人简历

学习简历
博士：2015.09 – 2019.05 美国堪萨斯大学 工程学院 机械工程
硕士：2012.09 – 2015.07 中国科学院大学 电工研究所 电工理论与新技术
本科：2008.09 – 2012.07 哈尔滨工业大学（威海） 汽车工程学院 热能与动力工程
科研项目
多孔电极浸润性的实验测量及内部有效电导率的数值模拟 (哈尔滨工业大学科研创新基金，5万元)， 主持
Stationary Direct Methanol Fuel Cells Using Pure Methanol (Sponsored by U.S. Department of Energy, $999,399), Principal Participant;
Pore-Scale Transport Phenomena in Li-O2 Battery Electrodes Characterized by Nano-Tomography (Sponsored by U.S. National Science Foundation, $219,312), Principal Participant;
Micro-Tomography and Physical Properties of Additively Manufactured Porous Media (Sponsored by NASA EPSCoR, $750,000 (granted) + $380,121 (match)), Principal Participant;
太阳能热发电用固体颗粒式空气吸热器内传热机理研究（国家自然科学基金面上项目，80万），主要参与；
日本企业IBIDEN吸热材料耐热性实验合作项目（40万），主要参与；
太阳能热发电技术科普电视片（国家自然科学基金专项基金，20万），主要参与；

研究领域

"1. 电化学电池储能 2. 可再生能源电解水制氢储氢"

近期论文

[1] Fangzhou Wang, Kahol P K, Gupta R, et al. Experimental Studies of Carbon Electrodes with Various Surface Area for Li–O2 Batteries[J]. Journal of Electrochemical Energy Conversion and Storage, 2019, 16(4): 041007. (SCI, IF=1.515)
[2] Camila Zequine, Sanket Bhoyate, Fangzhou Wang, et al. Effect of solvent for tailoring the nanomorphology of multinary CuCo2S4 for overall water splitting and energy storage[J]. Journal of Alloys and Compounds, 2019, 784: 1-7. (SCI, IF=4.175)
[3]Camila Zequine, Fangzhou Wang, Xianglin Li, et al. Nanosheets of CuCo2O4 as a High-Performance Electrocatalyst in Urea Oxidation[J]. Applied Sciences, 2019, 9(4): 793. (SCI, IF=2.217)
[4] Fangzhou Wang, and Xianglin Li. Pore-Scale Simulations of Porous Electrodes of Li–O2 Batteries at Different Saturation Levels. ACS applied materials & interfaces 10.31 (2018): 26222-26232. (SCI, IF=8.097)
[5] Fangzhou Wang, and Xianglin Li. Discharge Li-O2 batteries with intermittent current. Journal of Power Sources 394 (2018): 50-56. (SCI, IF=6.945)
[6] Wanqi Chen, Wei Yin, Yue Shen, Zhaoming Huang, Xianglin Li, Fangzhou Wang, Zhe Deng, Zhuoran Zhang, Yunhui Huang. High areal capacity, long cycle life Li-O2 cathode based on highly elastic gel granules. Nano Energy 47 (2018): 353 - 360. (SCI, IF=13.619)
[7] Fangzhou Wang, and Xianglin Li. Effects of the Electrode Wettability on the Deep Discharge Capacity of Li–O2 Batteries. ACS Omega 3.6 (2018): 6006-6012. (SCI)
[8] Fangzhou Wang, and Xianglin Li. The stagnant thermal conductivity of porous media predicted by the random walk theory. International Journal of Heat and Mass Transfer 107 (2017): 520-533. (SCI, IF=3.891)
[9] Mohazabrad, Farhad, Fangzhou Wang, and Xianglin Li. Influence of the Oxygen Electrode Open Ratio and Electrolyte Evaporation on the Performance of Li–O2 Batteries. ACS applied materials & interfaces 9.18 (2017): 15459-15469. (SCI, IF=8.097)
[10] Fangzhou Wang, Fengwu Bai, Tianjian Wang, Qing Li, and Zhifeng Wang. Experimental study of a single quartz tube solid particle air receiver. Solar Energy 123 (2016): 185-205. (SCI, IF=4.374)
[11] Mohazabrad, Farhad, Fangzhou Wang, and Xianglin Li. Experimental Studies of Salt Concentration in Electrolyte on the Performance of Li-O2 Batteries at Various Current Densities. Journal of The Electrochemical Society 163.13 (2016): A2623-A2627. (SCI, IF=3.662)
[12] Fangzhou Wang, Fengwu Bai, Zhifeng Wang and Xiliang Zhang. Numerical simulation of quartz tube solid particle air receiver. Energy Procedia 69 (2015): 573-582. (EI)
[13] Fengwu Bai, Yanan Zhang, Xiliang Zhang, Fangzhou Wang, Yan Wang and Zhifeng Wang. Thermal performance of a quartz tube solid particle air receiver. Energy Procedia49 (2014), 284-294. (EI)
[14] Yanan Zhang, Fengwu Bai, Xiliang Zhang, Fangzhou Wang and Zhifeng Wang. Experimental study of a single quartz tube solid particle air receiver. Energy Procedia 69 (2015), 600-607. (EI)