马骁婧
时间: 2022-02-28 来源:
姓名:马骁婧
职称:讲师、硕导
院系:英国威廉希尔公司
研究方向:微纳尺度流动与相变传热,格子玻尔兹曼多相流数值模拟,传热传质强化与智慧节能技术
联系方式:
邮箱:mxj@ncepu.edu.cn
地址:主楼F802
个人简介及主要荣誉称号:
马骁婧,博士毕业于上海交通大学,师从郑平院士。面向高功率散热设备热管理设计、超临界二氧化碳动力循环装置,围绕“多相流界面气泡/液滴动力学”关键问题开展学术研究。相关研究成果在 Energy 、 International Journal of heat and mass transfer 等本领域国际权威期刊发表SCI 英文论文,共计发表SCI论文13篇(第一作者及通讯作者),受学科领域权威期刊Energy(SCI一区)主编邀请发表Boiling heat transfer强化传热表面热设计综述论文一篇。
作为负责人承担北京市自然科学基金面上项目一项、中央高校科研项目一项,作为主要承担人负责企业横向项目两项,一项科研成果获得第十届高校科技成果展示推介会二等奖。
教学与人才培养:作为第一指导教师指导华电本科学生在全国第十四届节能减排大赛获得国家级特等奖。作为指导教师指导大一本科生参加大学生创新创业训练计划项目。指导学生参加华电首届大学生创新创业年会并获得一等奖。作为负责人建设“双一流”研究生培养核心课程建设——“微纳尺度流动与传热”
代表性论著及特邀报告:
[1] X. Ma, J. Xu, J. Xie*, In-situ phase separation to improve phase change heat transfer performance, Energy , 230 (2021) 120845.
[2] X. Ma, J. Lei, J. Xu*, Line Tension of Nanodroplets on a Concave Surface, Langmuir , 37(15) (2021) 4432-4440.
[3] X. Yan, G. Liu, J. Xu, X. Ma*, In Situ Oil Separation and Collection from Water under Surface Wave Condition, Langmuir, 37(20) (2021) 6257-6267.
[4]曹春蕾,何孝天,马骁婧,徐进良.液态金属软表面池沸腾传热的实验研究[J].物理学报,2021,70(13):302-312.
[5]李文,马骁婧,徐进良,王艳,雷俊鹏.纳米结构及浸润性对液滴润湿行为的影响[J].物理学报,2021,70(12):300-310.
[6] C. Cao, X. Ma, X. He, J. Xu*, J. Xie*, G. Liu, Self-activated elastocapillary wave promotes boiling heat transfer on soft liquid metal surface, International Communications in Heat and Mass Transfer, 120 (2021).
[7]J. Xu, Y. Wang, X. Ma*, Phase distribution including a bubblelike region in supercritical fluid, Physical Review E, 104(1) (2021) 014142.
[8] T. Lin, X. Ma, X. Quan, P. Cheng*, G. Chen, Enhanced pool boiling heat transfer on freeze-casted surfaces, International Journal of Heat and Mass Transfer, 153 (2020).
[9] X. Ma, P. Cheng*, Dry spot dynamics and wet area fractions in pool boiling on micro-pillar and micro-cavity hydrophilic heaters: A 3D lattice Boltzmann phase-change study, International Journal of Heat and Mass Transfer , 141 (2019) 407-418.
[10] X. Ma, P. Cheng*, 3D simulations of pool boiling above smooth horizontal heated surfaces by a phase-change lattice Boltzmann method, International Journal of Heat and Mass Transfer , 131 (2019) 1095-1108.
[11] X. Ma, P. Cheng*, Numerical Simulation of Complete Pool Boiling Curves: From Nucleation to Critical Heat Flux Through Transition Boiling to Film Boiling, Nuclear Science and Engineering , 193(1-2) (2019) 1-13.
[12] X. Ma, P. Cheng*, X. Quan, Simulations of saturated boiling heat transfer on bio-inspired two-phase heat sinks by a phase-change lattice Boltzmann method, International Journal of Heat and Mass Transfer , 127 (2018) 1013-1024.
[13] X. Ma, P. Cheng*, S. Gong, X. Quan, Mesoscale simulations of saturated pool boiling heat transfer under microgravity conditions, International Journal of Heat and Mass Transfer , 114 (2017) 453-457.
2)会议情况
[1] Ma XJ, Xu JL*, Gong L, Hong HR, Cao CL,Wang CQ, Low thermal conductivity substrate accelerates droplet evaporation in transition boiling regime: an abnormal Leidenfrost Phenomenon, ASCHT-2021, Best Paper Award.
[2] Ma XJ ,On the effect of the substrate thermal conductivity on droplet evaporation, International symposium on thermal fluid dynamic,2021(ISTFD), Beijing, 2021-7-31-2021-8-3. (Keynote speech)
[3] Ma XJ,3D-LBM Simulations of Surface Structure Effects on Pool Boiling, International Symposium on Numerical Methods in Heat and Mass Transfer, 2020 (ISNMHMT), Ning Bo, 2020.12.11-2020.12.13. (Keynote speech)
实验室:
低品位能源多相流与传热北京市重点实验室,网址:https://bjmfht.ncepu.edu.cn/