机械与能源工程系

太阳能转换与利用实验室(SECUL)主要研究高性能太阳能转换材料、装置和系统,为大规模工业应用中所需的电力、热能及燃料提供绿色清洁来源。实验室的主要研究方向如下:1)利用先进的多物理场多尺度耦合仿真技术研究热/热化学/光电化学太阳能转换装置中涉及复杂耦合物理现象之间的相互影响;2)为应用于太阳能燃料发生、能量存储及二氧化碳捕捉的转换系统建立优化、设计及控制策略;3)开发新型的性能表征实验设备,为材料的化学和输运性质的量化以及装置和系统的性能测试提供理想的平台。

个人简介

林蒙博士,南方科技大学机械与能源工程系助理教授,博士生导师。2010年上海理工大学制冷与低温工程系本科毕业。 2013年获得上海交通大学制冷与低温工程专业硕士学位。2018 年获得瑞士联邦理工学院-洛桑机械工程系博士学位。2018年-2019年于加州理工学院化学与化工系和人工光合成联合中心从事博士后研究。主要工作已经发表10余篇国际期刊论文并获批1项国际专利。参加能源类国际会议10余次,并两次担任美国机械工程师协会 (ASME)可持续能源会议-太阳能化学分会场主席(2018和2019年)。担任多个国际期刊的审稿人并两次被评为Solar Energy 优秀审稿人。

工作经历:
◆2019年10月 – 至今 南方科技大学 机械与能源工程系 助理教授
◆2018年5月 – 2019年9月 加州理工学院 化学与化工系 博士后研究员
◆2013年4月 – 2013年8月 上海交通大学 机械与动力工程学院 科研助理
◆2011年12月 – 2012年6月 北达科他州立大学 机械工程系 访问学者

教育经历:
◆2013年 - 2018年 瑞士联邦理工学院-洛桑 博士
◆2010年 - 2013年 上海交通大学 硕士
◆2006年 - 2010年 上海理工大学 学士

获奖经历:
◆2018年 ASME Solar Energy Division - Graduate Student Award
◆2018年 国际期刊 “Solar Energy”优秀审稿人
◆2017年 瑞士自然基金委博士后奖学金
◆2016年 上海市优秀硕士学位论文
◆2015年 国际期刊 “Solar Energy”优秀审稿人
◆2013年 上海交通大学优秀毕业生
◆2012年 国家研究生励志奖学金
◆2010年 上海市优秀毕业生

研究领域

1. 高温太阳能热化学燃料合成技术,

 

2. 太阳能驱动的高温电化学制氢反应器,

 

3. (光)电化学制氢、二氧化碳还原、氨合成技术,

 

4. 新型太阳聚光光热系统设计,

 

5. 高温相变储能系统。


教学

课程:太阳能热利用技术 (2024年 春季); 新能源系统 (2024年 秋季)


学术成果 查看更多

55.Xiaokang Hu, Yangyang Chen, Xin Wang, Kangkang Jia, Huanlei Zhang, Yuxin Wang, Hongwei Chu, Xiaohua Zhong, Meng Lin, Peining Chen, Longbin Qiu*, Huisheng Peng*, Sisi He*,Wearable and Regenerable Electrochemical Fabric Sensing System Based on Molecularly Imprinted Polymers for Real-Time Stress Management.  Adcvanced Functional Materials, 34, 14 04 (3), 2024,2312897.

54.Jinsi Yuan, Yuzhu Chen, Hongyu Yang, Jinxing Sun, Peng Cai, Meng Lin, Ming Chen, Haijiang Wang, Jiaming Bai,Vat photopolymerization 3D printing of NiO-YSZ anode for solid oxide fuel cells.  Journal of the European Ceramic Society, 44, 8,2024, 5068-5079.

53.Fu-Zhi Li, Hai-Gang Qin, Huan-Lei Zhang, Xian Yue, Lin-Ke Fu, Bingjun Xu, Meng Lin*, Jun Gu*,Another role of CO-formation catalyst in acidic tandem CO2 electroreduction: Local pH modulator. Joule, Volume 8, Issue 6,2024, 1772-1789.

52.Yangyang Chen, Xiaokang Hu, Qimin Liang, Xin Wang, Huanlei Zhang, Kangkang Jia, Yuan Li, Anning Zhang, Peining Chen, Meng Lin, Longbin Qiu, Huisheng Peng, Sisi He*,Large-Scale Flexible Fabric Biosensor for Long-Term Monitoring of Sweat Lactate.  Advanced Functional Materials,2024, 2401270.

51.Shang Liu, Shiteng Li, Qijun Yang, Meng Lin*,Theory-guided solar interfacial evaporator designs enabled by quantified multiphysical transport phenomena via a coupled experimental–numerical approach Solar Energy, 273,2024,112508.

50.Shaokuan Gong, Geping Qu,  Ying Qiao, Yifan Wen, Yuling Huang, Siyuan Cai, Letian Zhang, Kui Jiang, Shang Liu, Meng Lin, Zong-Xiang Xu*  and Xihan Chen *.A hot carrier perovskite solar cell with efficiency exceeding 27% enabled by ultrafast hot hole transfer with phthalocyanine derivatives.  Energy & Environmental Science,2024,17, 5080-5090.

49.Qiushi Hu,Shang Liu,Jingjing Liu,Meng Lin*,Ruquan Ye* and Xihan Chen*.Ultrafast Hole Preservation with Undercoordinated Tungsten for Efficient Solar-to-Chemical Conversion. ACS Energy Letters2024, 9, 7, 3252–3260

48.Yuzhu Chen, Chengxiang Xiang  and Meng Lin*. Performance assessment of photoelectrochemical CO2 reduction photocathodes with patterned electrocatalysts: a multi-physical model-based approach Energy & Environmental Science, 2024, 6.

47.Yongbiao Mu , Yu Shixiang , Chen Yuzhu , Chu  Youqi, Wu Buke, Zhang Qing, Guo Binbin,  Zou Lingfeng, Zhang  Ruijie, Fenghua Yu, Han Meisheng , Lin Meng, Yang Jinglei,  Bai Jiaming , Zeng  Lin. Highly Efficient Aligned Ion-Conducting Network and Interface Chemistries for Depolarized All-Solid-State Lithium Metal Batteries Nano-Micro Letters, 16,  86,  2024.

46.Hai-Gang Qin, Fu-Zhi Li, Yun-Fan Du, Lin-Feng Yang, Hao Wang, Yi-Yang Bai, Meng Lin, and Jun Gu*,Quantitative Understanding of Cation Effects on the Electrochemical Reduction of CO2 and H+ in Acidic Solution.  ACS Catalysis, 2023, 13 (2), 916-926.

45.Xinghang Chen, Ming Li, Qi Li* , Yuzhu Chen, Buke Wu, Meng Lin*, Qinyou An, andLiqiang Mai*.Realizing Highly Reversible Zinc Anode via Controlled-current Pre-deposition. Energy & Environmental Materials, 6,  6,09, 2023.

44.Jinsi Yuan, Yuzhu Chen, Jinxing Sun, Yue Wang, Meng Lin, Min Wang, Haijiang Wang, and Jiaming Bai*.3D Printing of Robust 8YSZ Electrolytes with a Hyperfine Structure for Solid Oxide Fuel Cells. ACS Applied Energy Materials, 2023, 6, 8, 4133-4143.

43.Wan, Shusheng & Zhang, Huanlei & Ye, Ke & Li, Jieyang & He, Yucheng & Ge, Xiaolin & Xu, Tongwen & Cai, Wen-Bin & Lin, Meng* & Jiang, Kun*. Improving the Efficiencies of Water Splitting and CO2 Electrolysis by Anodic O2 Bubble Management.  The journal of physical chemistry letters. 14, 2023, 11217-11223. 

42.Lei Zhao,Shuai Deng* and Meng Lin*. Optimizing dense particles for efficient thermochemical fuel generation through a unified particle-level model. ” Journal of Materials Chemistry A, 48, 2023.

41.Shusheng Wan, Huanlei Zhang, Ke Ye, Jieyang Li, Yucheng He, Xiaolin Ge, Tongwen Xu, Wen-Bin Cai, Meng Lin*, and Kun Jiang*.Improving the Efficiencies of Water Splitting and CO2 Electrolysis by Anodic O2 Bubble Management.” The journal of physical chemistry letters, 14.49 (2023): 11217–11223.

40.Shang Liu, Shiteng Li, and Meng Lin*. Understanding Interfacial Properties for Enhanced Solar Evaporation Devices: From Geometrical to Physical Interfaces.  ACS Energy Letters, 2023, 8, 4, 1680–1687.

39.Ke Tang , Dongbo Cheng , Meng Lin*. Solar-driven thermally regenerative electrochemical device for continuous electricity production: A thermodynamic analysisJournal of Power Sources,  584, 15 , 2023, 233583. 

38.Huanlei Zhang, Dongbo Cheng, Chengxiang Xiang, and Meng Lin*.Tuning the Interfacial Electrical Field of Bipolar Membranes with Temperature and Electrolyte Concentration for Enhanced Water Dissociation.” ACS sustainable chemistry & engineering, 2023, 11, 21, 8044–8054.

37.Buke Wu, Binbin Guo , Yuzhu Chen , Yongbiao Mu, Hongqiao Qu, Meng Lin* , Jiaming Bai*, Tianshou Zhao*, Lin Zeng* High Zinc Utilization Aqueous Zinc Ion Batteries Enabled by 3D Printed Graphene Arrays.  Energy Storage Materials, 2023, 54: 75-84.

36.Xu, Da, and Meng Lin*. Design Controllable TPMS Structures for Solar Thermal Applications: A Pore-Scale Vs. Volume-Averaged Modeling Approach.”  International journal of heat and mass transfer, 201 (2023): 123625.

35.Yuzhu Chen,and Meng Lin*.An Optical-Electronic-Catalytic Coupled Multi-Physical Simulation for Sunlight-Driven CO2 Reduction Device Based on Light Absorbers Patterned with Island Electrocatalysts. ECS Meeting Abstracts. MA2023-02. 2406-2406. 

34.Yongbiao Mu, Yuzhu Chen, Buke Wu, Qing Zhang, Meng Lin, Lin Zeng*.Dual Vertically Aligned Electrode-Inspired High-Capacity Lithium Batteries.  Advanced Science, 9, 30, 2022,2203321.

33.Xu, Da, and Meng Lin*. Comparative Study on Electrochemical and Thermochemical Pathways for Carbonaceous Fuel Generation Using Sunlight and Air. ACS sustainable chemistry & engineering, 10.42 (2022): 13945–13954. 

32.He, Ning et al. Automatic Snorkeling Electronic Equipment Enabled by Self‐Breathing Flexible Aqueous Aluminum‐Air Battery.” Advanced materials technologies, 8.2 (2023). https://doi.org/10.1002/admt.202201092.

31.Xinghang Chen, Ming Li, Qi Li, Yuzhu Chen, Buke Wu, Meng Lin*, Qinyou An*, Liqiang Mai*. Realizing Highly Reversible Zinc Anode via Controlled‐current Pre‐deposition.  Energy & Environmental Materials,  e12480. 

30.Chen Y, Lin M*. A photo-thermo-electrochemical cell for efficient solar fuel and power production.  Cell Reports Physical Science, 2022, 3(12): 101156.

29.Haodong Huang, Meng Lin*. Dynamic behavior of solar thermochemical reactors for fuel generation: Modeling and control strategies.  Energy Conversion and Management, Volume 270,2022,116232.

28. Meng Lin*, Clemens Suter, Stefan Diethelm, JanVan herle, Sophia Haussener. Integrated solar-driven high-temperature electrolysis operating with concentrated irradiation Joule, 23 August 2022. 

27.Yongbiao Mu,Yuzhu Chen,Buke Wu,Qing Zhang,Meng Lin*,Lin Zeng. Dual Vertically Aligned Electrode-Inspired High-Capacity Lithium Batteries Advanced Science. 23 August 2022. 

26.Xing, Shuang ; Zhao, Chen ; Zou, Jiexin ; Zaman, Shahid ; Yu, Yang ; Gong, Hongwei ; Wang, Yajun ; Chen, Ming ; Wang, Min ; Lin, Meng ; Wang, Haijiang. Recent advances in heat and water management of forced-convection open-cathode proton exchange membrane fuel cells. ” Renewable & sustainable energy reviews, 2022, Vol.165, p.112558. 

25.Wandong Bai, Haodong Huang, Clemens Suter, Sophia Haussener, and Meng Lin*.Enhanced Solar-to-Fuel Efficiency of Ceria-Based Thermochemical Cycles via Integrated Electrochemical Oxygen Pumping.  ACS Energy Letters, 2022, 7, 2711−2716. 

24.Jieyang Li, Jinpeng Hu, Meng Lin*. A flexibly controllable high-flux solar simulator for concentrated solar energy research from extreme magnitudes to uniform distributions Renewable and Sustainable Energy Reviews. Volume 157,2022,112084. 

23.Lin, Meng* , I. A. Digdaya , and C. Xiang* . Modeling the electrochemical behavior and interfacial junction profiles of bipolar membranes at solar flux relevant operating current densities.”  Sustainable Energy & Fuels, 5(2021).

22.Hongyang Zuo, Mingyang Wu, Kuo Zeng*, Yuan Zhou, Jiayue Kong, Yi Qiu, Meng Lin , Gilles Flamant.Numerical investigation and optimal design of partially filled sectorial metal foam configuration in horizontal latent heat storage unit.”  Energy, 2021, 237: 121640. 

21.Haodong HuangMeng Lin*. Optimization of solar receivers for high-temperature solar conversion processes: Direct vs. Indirect illumination designs. ” Applied Energy, 2021, 304(September): 117675. 

20. Ian Sullivan, Huanlei Zhang, Cheng Zhu, Marissa Wood, Art Nelson, Sarah Baker, Christopher Spadaccini, Tony Van Buuren, Meng Lin*, Eric Duoss*, Siwei Liang*, Chengxiang Xiang*. 3D Printed Nickel − Molybdenum-Based Electrocatalysts for Hydrogen Evolution at Low Overpotentials in a Flow-Through Con Fi Guration.” ACS Applied Materials &Interfaces, 2021, 13 (17), 20260–20268.

19. Meng Lin*, Ibadillah Digdaya, and Chengxiang Xiang*. Modeling the electrochemical behavior and interfacial junction profiles of bipolar membranes at solar flux relevant operating current densities.” Sustainable Energy & Fuels, 2021, 5 (7), 2149–2158. 

18.Bu-ke Wu, Yi-ze Wu, Zhen-dong Lu, Jian-shuo Zhang, Ning Han, Ya-meng Wang, Xiao-min Li, Meng Lin*, Lin Zeng*, Cation Selective Separator Induces Cathode Protective Layer and Regulated Zinc Deposition for High-performance and Low-Cost Zinc Ion Batteries Journal of Materials Chemistry A, 2021. 

17.Jieyang Li, and Meng Lin*. Unified Design Guidelines for High Flux Solar Simulator with Controllable Flux Vector. Applied Energy, 281, no. August 2020 (2021): 116083. 

16.Digdaya, Ibadillah A, Ian Sullivan, Meng Lin*, Lihao Han, Wen-Hui Cheng, Harry A Atwater*, and Chengxiang Xiang*. A Direct Coupled Electrochemical System for Capture and Conversion of CO2 from Oceanwater.” Nature Communications, 11, no. 1 (2020): 1–10.

15.Ma, Shuai, Meng Lin, Tzu-en Lin, Tian Lan, Xun Liao, François Mar, Jan Van, Yongping Yang, Changqing Dong, and Ligang Wang. Fuel Cell-Battery Hybrid Systems for Mobility and off-Grid Applications : A Review”  Renewable and Sustainable EnergyReviews, 135, no. July 2020 (2021). 

14.Cao, Jinshan, Zhiqiang Cheng, Lijuan Kang, Meng Lin, and Lihao Han. Patterned Nanofiber Air Filters with High Optical Transparency, Robust Mechanical Strength, and Effective PM2.5capture Capability.” RSC Advances, 10, no. 34 (2020): 20155–61. 

13.Sullivan Ian, Lihao Han, Soo Hong Lee, Meng Lin, David M. Larson, Walter S. Drisdell, and Chengxiang Xiang. A Hybrid Catalyst-Bonded Membrane Device for Electrochemical Carbon Monoxide Reduction at Different Relative Humidities.” ACS Sustainable Chemistry & Engineering, 7, no. 20 (2019): 16964-16970.

12.Meng Lin, Lihao Han, Meenesh R. Singh, Chengxiang Xiang. “An Experimental- and Simulation-Based Evaluation of the CO2 Utilization Efficiency of Aqueous-Based Electrochemical CO2Reduction Reactors with Ion-Selective Membranes.” ACS Applied Energy Materials,  2019, 2, 8, 5843–5850.

11.Meng Lin, Sophia Haussener. “An integrated concentrated solar fuel generator utilizing a tubular solid oxide electrolysis cell as solar absorber.Journal of Power Sources,  400 (2018), 592–604.

10.Meng Lin, Jan Reinhold, Nathalie Monnerie, and Sophia Haussener. Modeling and design guidelines for direct steam generation solar receivers.” Applied Energy,  216 (2018): 761-776.

9.Meng Lin, and Sophia Haussener. “Techno-economic modeling and optimization of solar-driven high temperature electrolysis systems.” Solar Energy, 155 (2017): 1389–1402.

8.Meng Lin, and Sophia Haussener. “Solar fuel processing efficiency for ceria redox cycling using alternative oxygen partial pressure reduction methods.” Energy, 88 (2015): 667-679.

7.Meng Lin, Krishnan Sumathy, Yanjun Dai, and Xiaokai Zhao. Performance investigation on a linear Fresnel lens solar collector using cavity receiver.” Solar Energy, 107 (2014): 50-62.

6.Meng Lin, Krishnan Sumathy, Yanjun Dai, Ruzhu Wang, and Yu Chen. “Experimental and theoretical analysis on a linear Fresnel reflector solar collector prototype with V-shaped cavity receiver.” Applied Thermal Engineering, 51, no. 1 (2013): 963-972.

5.Xian Li, Meng Lin, Yanjun Dai, and Chi-Hwa Wang. Comparison-based optical assessment of hyperboloid and ellipsoid reflectors in a beam-down solar tower system with linear Fresnel heliostats.” Journal of Solar Energy Engineering, 139 (2017): 6, 61003.

4.Lihao Han, Meng Lin, and Sophia Haussener. “Reliable Performance Characterization of Mediated Photocatalytic Water‐Splitting Half Reactions.” Chemistry Sustainability Energy Materials10 (2017): 2158–2166.

3.Enqian Dai, Meng Lin, Jiahao Xia, and Yanjun Dai, “Experimental investigation on a GAX based absorption heat pump driven by hybrid liquefied petroleum gas and solar energy.” Solar Energy,  169 (2018): 167–178.

2.Shuangjun Li, Shuai Deng, Li Zhao, Ruikai Zhao, Meng Lin, Yanping Du, Yahui Lian, Mathematical modeling and numerical investigation of carbon capture by adsorption: Literature review and case study,” Applied Energy,  221(2018): 437–449.

1.Li Cheng, Yan Ting, Ruzhu Wang, Liwei Wang, Tingxian Li, Xian Li, Meng Lin, and Wentao Xie. “An experimental investigation of an adsorption ice-maker driven by parabolic trough collector.” Heat Transfer Research,46, no. 4 (2015).

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招聘岗位:博士后
联系方式:linm@sustech.edu.cn
课题组研究方向:
1. 高温太阳能热化学燃料合成技术;
2. 太阳能驱动的高温电化学制氢反应器;
3. (光)电化学制氢、二氧化碳还原、氨合成技术;
4. 新型太阳聚光光热系统设计;
5. 高温相变储能系统;
博士后岗位-1 (1名,高温太阳能转化方向)
要求:
1. 博士学位,具有动力工程及工程热物理(欢迎具有其他与研究方向相关专业背景的博士申请);
2. 优先考虑具有太阳能转化与应用方向研究经验的申请者;
3. 有高聚光比太阳模拟器使用经验的申请者优先考虑;
4. 熟悉流动、传热、传质、光学以及化学反应多物理场耦合仿真;
5. 具有良好的英语听说读写能力(有过国际期刊论文发表经验);
6. 具有团队协作精神和勤奋踏实的工作态度;
【太阳能热化学制氢方向与麻省理工学院Ahmed Ghoniem教授合作,有机会前往MIT交流6-12个月】
博士后岗位-2 (1名,太阳能驱动的电化学储能器件方向)
要求:
1. 博士学位,电化学相关专业背景(尤其欢迎有高温固体氧化物燃料电池背景的申请者,同时欢迎其他专业背景申请者);
2. 熟悉电极材料的制备和组装,具有电化学电池测试经验;
3. 熟悉燃料电池或电解池器件的多物理场仿真;
4. 具有良好的英语听说读写能力(有过国际期刊论文发表经验);
5. 具有团队协作精神和勤奋踏实的工作态度;
待遇:
(1)博士后聘用期两年,年薪33万元起,含广东省生活补贴15万元及深圳市生活补贴6万元,并按深圳市有关规定参加社会保险及住房公积金。博士后福利费参照学校教职工标准发放。
(2)特别优秀候选人可以申请校长卓越博士后,年薪可达50万元以上。(含广东省及深圳市在站生活补贴)。
(3)在站期间,可依托学校申请深圳市公租房,未依托学校使用深圳市公租房的博士后,可享受两年税前2800元/月的住房补贴。
(4)拥有优良的工作环境和境内外合作交流机会,博士后在站期间享受两年共计2.5万学术交流经费资助。
(5)课题组协助符合条件的博士后申请“广东省海外人才支持项目”。即在世界排名前200名的高校(不含境内,排名以上一年度泰晤士、USNEWS、QS和上海交通大学的世界大学排行榜为准)获得博士学位,在广东省博士后设站单位从事博士后研究,并承诺在站2年以上的博士后,申请成功后省财政给予每名进站博士后资助60万元生活补贴(与广东省及深圳市在站博士后生活补贴不同时享受);对获得本项目资助,出站后与广东省用人单位签订工作协议或劳动合同,并承诺连续在粤工作3年以上的博士后,省财政给予每人40万元住房补贴。
(6)博士后出站选择留深从事科研工作,且与本市企事业单位签订3年以上劳动(聘用)合同的,可以申请深圳市博士后留深来深科研资助。深圳市政府给予每人每年10万元科研资助,共资助3年(以深圳市最新申报要求为准)。
(7)根据《深圳市新引进博士人才生活补贴工作实施办法》规定,新引进博士人才生活补贴(10万元)与省市博士后在站生活补贴不同时享受。
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联系地址

广东深圳南山区学苑大道1088号

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linm@sustech.edu.cn

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