2007.09-2012.03   上海交通大學  博士
2005.09-2007.07   上海交通大學  碩士（碩博連讀）
2001.09-2005.07   天津大學        學士

2021-至今     上海交通大學機械與動力工程學院 新能源動力研究所   教授 (碩士生導師、博士生導師）
2017-2021    上海交通大學機械與動力工程學院 新能源動力研究所    副研究員  (碩士生導師、博士生導師）
2014-2016    上海交通大學機械與動力工程學院 新能源動力研究所   講師        (碩士生導師、博士生導師）
2012-2014    上海交通大學機械與動力工程學院                            博士后
2008-2009   香港理工大學機械系                                  Research Associate

#綠色氫基燃料制備與高效利用：
1. 綠色氫基燃料制備：CO2/H2O高溫共電解、電驅動CO2還原
2. 固體氧化物燃料電池/電解池：SOFC/SOEC關鍵器件與電堆
3. 低碳/零碳燃料先進動力系統(tǒng)：氨燃料動力系統(tǒng)，高效增程式發(fā)動機

已有試驗臺架包括：
面向SOFC、SOEC粉體、器件、裝堆、電化學、表征相關的完整研究平臺。
氨燃料/靈活燃料發(fā)動機臺架
與英國劍橋大學、英國帝國理工大學、香港理工大學建立合作關系，并已合作發(fā)表文章，有交流和聯(lián)合培養(yǎng)機會。

招收：致遠榮譽博士、申請考核博士、碩士、本科實習生。
招聘：SOFC/SOEC方向博士后、零碳燃料發(fā)動機方向博士后

中國船舶工業(yè)協(xié)會船舶動力分會 副主任委員

中國汽車工程學會低碳燃料與氫動力汽車技術分會 副主任委員

中國內燃機學會青年工作委員會 副主任委員

中國內燃機工業(yè)協(xié)會十五五發(fā)展規(guī)劃撰寫組 組長

JKW某領域十四五規(guī)劃論證專家

中國工程院院刊《ENGINEERING Energy》SCI期刊 青年編委

《Results in Engineering》SCI期刊 副主編

2023-2026 工信部船用發(fā)動機重大工程“?奧托循環(huán)氨燃料發(fā)動機燃燒關鍵技術研究”，項目負責人

2023-2026 國家自然科學基金葉企孫聯(lián)合基金重點項目“?碳氫燃料重整條件下寬域高效高密度燃燒機制與調控研究”，項目負責人

2022-2025 寧波市級重大專項 “氨-柴油混合燃料船舶發(fā)動機研制” ，課題負責人

?2022-2023 某領域重大工程項目“新型高效高密度燃燒”，項目負責人

2022-2026 上海市市級科技重大專項“?高溫共電解H2O和CO2關鍵技術和電解池堆研發(fā)”項目負責人

2022-2025 教育部集成攻關大平臺“?氨燃料發(fā)動機燃燒關鍵技術研究”課題負責人

2021-2024 上海市基礎研究特區(qū)計劃“基于多載能子耦合的光/電-熱有序可控轉化與能質循環(huán)”，項目負責人

2021-2024 國家自然科學基金面上項目 “船用低速雙燃料發(fā)動機重油模型燃料超臨界高壓微噴多場耦合調控機制研究”，項目負責人
2021-2022 上海交通大學“深藍計劃”
2019-2022 上海市“青年科技啟明星”人才計劃
2018-2020 上海市“青年拔尖”人才計劃
2018-2020 國家自然科學基金重大研究計劃“基于固相萃取技術的航空煤油模型燃料構建及其碳煙生成與演化”  項目負責人
2018-2020 上海交通大學“晨星-副教授”A類
2017-2020 國家自然科學基金面上項目“缸內熱化學燃料改質機理及與燃燒耦合控制的基礎研究”項目負責人 
2016-2019 國家重點研發(fā)計劃“基于可控熱化學燃燒模式和低成本后處理裝置的天然氣發(fā)動機減排關鍵技術研究”項目負責人 
2016-2020 船用低速機工程（一期）“天然氣/柴油雙燃料著火與燃燒及低速機先進燃燒模式的研究” 項目負責人
2016-2018 上海交通大學“SMC晨星青年學者獎勵計劃”B類 
2014-2016 國家自然科學基金青年基金“生物柴油微觀分子結構對柴油機顆粒物形成機理的影響研究”項目負責人 
2014-2017 上海交通大學科技創(chuàng)新專項-新進教師科研起步項目 “生物柴油模型燃料擴散火焰碳煙生成基礎研究”負責人 
2014-2016 內燃機燃燒學國家重點實驗室開放基金“典型長鏈脂肪酸甲酯(C12-18)的顆粒物排放形成機理研究”負責人 
2013-2014 中國博士后科學基金特別資助“生物柴油發(fā)動機顆粒物形成機理基礎研究”負責人 
2012-2014 中國博士后科學基金面上項目“基于生物柴油微觀分子機構的發(fā)動機低溫燃燒基礎研究”負責人 
2015-2017 上海交通大學多學科交叉培育項目（醫(yī)工）“基于數(shù)字化血流動力學分析與3D打印患者個體化研究在小兒先心病Fontan手術規(guī)劃中的探索與應用”工科負責人 
2017-2019 上海交通大學多學科交叉培育項目（醫(yī)工） “交通相關細顆粒物對兒童變應性鼻炎Th2細胞亞群極化影響及其表觀遺傳調控研究”工科負責人 

2015-2019 國家自然科學基金重點項目 “車用生物柴油模型燃料及其燃燒的基礎研究”；主要完成人  
2012-2015 國家科技支撐計劃“養(yǎng)殖場生物燃氣清潔高效多元化利用集成技術研究與示范”；主要完成人 
2010-2014 國家自然科學基金重點項目 “壓燃式發(fā)動機高效低溫燃燒的基礎研究”；主要完成人 
2011-2013 科技部國際合作項目“面向中美清潔能源合作的電動汽車前沿技術研究—生物燃料低溫燃燒特性研究”；主要完成人  
2007-2009 教育部重大項目 “燃用生物柴油的壓燃式柴油發(fā)動機的研究”；主要完成人

2024年論文：
1. Toward High CO Selectivity and Oxidation Resistance Solid Oxide Electrolysis Cell with High-Entropy Alloy. ACS Catal. 2024, 14, 5, 2897–2907
2. Performance optimization of solid oxide electrolysis cell for syngas production by high temperature co-electrolysis via differential evolution algorithm with practical constraints. Energy Conversion and Management, 2024, 300.
3. Control strategy of solid oxide electrolysis cell operating temperature under real fluctuating renewable power. Energy Conversion and Management, 2024, 299.
4. Effects of Transition Metals on the Electrical Conductivity of M-Doped MnCo2O4 (M = Cu, Ni, Zn) as Contact Layer on Precoated SUS441 in Solid Oxide Cells. ACS Appl. Energy Mater. 2024, 7, 6, 2542–2551.
5. Air-Promoted Light-Driven Hydrogen Production from Bioethanol over Core/Shell Cr2O3@GaN Nanoarchitecture. Angewandte Chemie. 2024, 136.
6. Rh/InGaN1?xOx nanoarchitecture for light-driven methane reforming with carbon dioxide toward syngas. Science Bulletin, 2024.
7. An Active and Robust Catalytic Architecture of NiCo/GaN Nanowires for Light-Driven Hydrogen Production from Methanol. Small, 2024.
8. Fuel reactivity stratification assisted jet ignition for low-speed two-stroke ammonia marine engine. International Journal of Hydrogen Energy 2024, 49.
9. Combustion and emission characteristics of ammonia-hydrogen fueled SI engine with high compression ratio. International Journal of Hydrogen Energy 2024, 62.
10. Effect of Gliding Arc Plasma Reforming of Methane on Large-Bore Low-Speed Two-Stroke Marine Engine. Book: Proceedings of the 5th International Symposium on Plasma and Energy Conversion. DOI : 10.1007/978-981-97-2245-7
2023年論文：
1. Nitrogen-doped carbon confined Cu-Ag bimetals for efficient electroreduction of CO2 to high-order products. Chemical Engineering Journal, 2023, 468.
2. Predicting 3D soot field from luminosity in turbulent flame based on conditional-generative adversarial networks. Combustion and Flame 2023, 247.
3. Influence of operating conditions on the fuel electrode degradation of solid oxide electrolysis cell investigated by phase field model with wettability analysis. Journal of Power Sources, 2023, 587.
4. Numerical analysis of ammonia HCCI combustion in a free piston engine through trajectory-based combustion control, Fuel, 2023, 341.
5. Photocatalytic syngas production from bio-derived glycerol and water on AuIn-decorated GaN nanowires supported by Si wafer. Green Chem., 2023, 25, 288-295
6. An experimental and kinetic modeling study on the effects of molecular structure on oxidation of propanol isomers at engine-relevant condition in a variable pressure laminar flow reactor. Chemical Engineering Science, 2023, 265.
7. A semiconducting hybrid of RhOx/GaN@InGaN for simultaneous activation of methane and water toward syngas by photocatalysis. PNAS Nexus, 2023, 2.
8. Insight of soot nanostructure and oxidation behavior in ammonia / ethylene coaxial diffusion flame. Fuel, 2023, 349.
9. Experimental study of a dual-fuel spark-assisted compression ignition engine with polyoxymethylene dimethyl ether and methanol as fuels. Applied Thermal Engineering, 2023, 232.
10. Fundamental study on oxidation properties at elevated pressure of typical renewable synthetic liquid fuels through low-temperature CO2 electroreduction. Fuel, 2023, 331.
11. An experimental and kinetic modeling study on the effects of molecular structure on oxidation of propanol isomers at engine-relevant condition in a variable pressure laminar flow reactor. Chemical Engineering Science, 2023, 265.
12. A comparative study on soot and PAH formation of C10 naphthenic ring-containing species in laminar coflow diffusion flames. Fuel, 2023, 332.
13. Fundamental study on oxidation properties at elevated pressure of typical renewable synthetic liquid fuels through low-temperature CO2 electroreduction. Fuel 2023, 331.
14. An experimental study on combustion and emissions characteristics in a dual-injection spark-assisted compression ignition engine fueled with PODE/gasoline. Thermal Science, 2023, 27.
15. A Kinetic Modeling and Engine Simulation Study on Ozone-Enhanced Ammonia Oxidation. SAE 2023-01-1639
16. A Novel Approach to Constructing Reactivity-Based Simplified Combustion Model for Dual Fuel Engine. SAE 2023-01-1627

2022年論文：
1、A comparative study of PODE/gasoline and n-heptane/gasoline in a spark-assisted homogeneous charge compression ignition engine with dual-injection strategies and EGR. International Journal of Engine Research, 2022, 24.
2、Ren, F.; Cheng, X.; Gao, Z.; Huang, Z.; Zhu, L., Effects of NH3 addition on polycyclic aromatic hydrocarbon and soot formation in C2H4 co-flow diffusion flames. Combustion and Flame 2022, 241.
3、Xia, C.; Zhao, T.; Fang, J.; Zhu, L.; Huang, Z., Experimental study of stratified lean burn characteristics on a dual injection gasoline engine. Frontiers in Energy 2022.
4、Liu, A.; Gao, Z.; Rigopoulos, S.; Luo, K. H.; Zhu, L., Modelling of laminar diffusion flames with biodiesel blends and soot formation. Fuel 2022, 317.
5、Ma, C.; Zou, X.; Li, A.; Gao, Z.; Luo, L.; Shen, S.; Zhang, J.; Huang, Z.; Zhu, L., Rapid flame synthesis of carbon doped defective ZnO for electrocatalytic CO2 reduction to syngas. Electrochimica Acta 2022, 411.
6、Huang, Z.; Zhu, L.; Li, A.; Gao, Z., Renewable synthetic fuel: turning carbon dioxide back into fuel. Frontiers in Energy 2022, 16, (2), 145-149.
7、Zhu, L.; Gao, Z.; Cheng, X.; Ren, F.; Huang, Z., An assessment of surrogate fuel using Bayesian multiple kernel learning model in sight of sooting tendency. Frontiers in Energy 2022, 16, (2), 277-291
8、Cheng, X.; Ren, F.; Gao, Z.; Zhu, L.; Huang, Z., Synergistic effect analysis on sooting tendency based on soot-specialized artificial neural network algorithm with experimental and numerical validation. Fuel 2022, 315.
9、The effects of 1-methylnaphthalene addition to n-dodecane on the formation of soot and polycyclic aromatic hydrocarbons in laminar coflow diffusion flames. Fuel 2022, 329.

2021年論文：
1、Zhang, Z.; Li, A.; Ren, F.; Gao, Z.; Zhu, L.; Huang, Z., Effect of Ester Molecular Structure Difference on Its Soot Tendency: A Comparative Study of Methyl Butanoate and Methyl Crotonate. Energy and Fuels 2021, 35, (13), 10805-10819.
2、Zhu, L.; Li, A.; Zhang, Z.; Li, B.; Ma, C.; Cheng, X.; Zou, X.; He, Z.; Lu, X.; Huang, Z., Effects of alcohol enrichment on thermochemical fuel reforming (TFR): Insights from chemical kinetics. International Journal of Hydrogen Energy 2021, 46, (1), 1197-1209.
3、Ma, C.; Zou, X.; Li, A.; Li, H.; Rigopoulos, S.; Zhu, L.; Huang, Z., Evolution of MoO3nanobelts and nanoplatelets formation with flame synthesis. Proceedings of the Combustion Institute 2021, 38, (1), 1289-1297.
4、Cheng, X.; Gao, Z.; Ren, F.; Rigopoulos, S.; Zhu, L.; Huang, Z., Experimental and kinetic modeling study on sooting tendencies of alkylbenzene isomers. Fuel 2021, 283.
5、Zou, X.; Ma, C.; Li, A.; Gao, Z.; Shadike, Z.; Jiang, K.; Zhang, J.; Huang, Z.; Zhu, L., Nanoparticle-Assisted Ni-Co Binary Single-Atom Catalysts Supported on Carbon Nanotubes for Efficient Electroreduction of CO2to Syngas with Controllable CO/H2Ratios. ACS Applied Energy Materials 2021.
6、Li, H.; Ma, C.; Zou, X.; Li, A.; Huang, Z.; Zhu, L., On-board methanol catalytic reforming for hydrogen Production-A review. International Journal of Hydrogen Energy 2021, 46, (43), 22303-22327.
7、夏淳,趙廷鈺,方俊華,朱磊,黃震.冷起動及暖機工況下雙噴射汽油機燃燒和顆粒物排放試驗研究[J].車用發(fā)動機,2021(05):1-7.
8、張真英男,李昂,朱磊,黃震.小分子醇對天然氣發(fā)動機熱化學重整的影響[J].工程熱物理學報,2021,42(01):222-231.

2020年發(fā)表論文：
1、Gao, Z.; Cheng, X.; Ren, F.; Zhu, L.; Huang, Z., Compositional Effects on Sooting Tendencies of Diesel Surrogate Fuels with Four Components. Energy and Fuels 2020, 34, (7), 8796-8807.
2、Zhu, L.; Li, A.; Zhang, Z.; Huang, Z., Development and Validation of Multi-Component Surrogate for Heavy Fuel Oil. Neiranji Gongcheng/Chinese Internal Combustion Engine Engineering 2020, 41, (6), 36-45.
3、Li, A.; Zhang, Z.; Cheng, X.; Lu, X.; Zhu, L.; Huang, Z., Development and validation of surrogates for RP-3 jet fuel based on chemical deconstruction methodology. Fuel 2020, 267.
4、Huang, G.; Li, Z.; Zhao, W.; Zhang, Y.; Li, J.; He, Z.; Qian, Y.; Zhu, L.; Lu, X., Effects of fuel injection strategies on combustion and emissions of intelligent charge compression ignition (ICCI) mode fueled with methanol and biodiesel. Fuel 2020, 274.
5、Zhu, L.; Li, B.; Li, A.; Ji, W.; Qian, Y.; Lu, X.; Huang, Z., Effects of fuel reforming on large-bore low-speed two-stroke dual fuel marine engine combined with EGR and injection strategy. International Journal of Hydrogen Energy 2020, 45, (53), 29505-29517.
6、Ji, W.; Li, A.; Zhu, L.; Lü, X.; Huang, Z., Effects of Multiple Injection on the Combustion and Emissions of Marine Low-speed Two-stroke Diesel Engine. Ranshao Kexue Yu Jishu/Journal of Combustion Science and Technology 2020, 26, (2), 139-145.
7、He, Z.; Wang, J.; Li, B.; Zhu, L.; Qian, Y.; Lu, X.; Huang, Z., Effects of n-heptane enrichment on in-cylinder thermochemical fuel reforming (TFR) characteristics and performances of spark ignition natural gas engine: A comparison with natural gas and methanol enrichment. Fuel 2020, 271.
8、Li, B.; Sun, Q.; Li, A.; Shao, Y.; He, Z.; Lu, X.; Huang, Z.; Zhu, L., Effects of propanol isomers enrichment on in-cylinder thermochemical fuel reforming (TFR) in spark ignition natural gas engine. International Journal of Hydrogen Energy 2020, 45, (18), 10932-10950.
9、Ma, C.; Zou, X.; Li, H.; Li, A.; Gao, Z.; Zhu, L.; Huang, Z., Flame synthesized MoO3 nanobelts and nanoparticles coated with BiVO4 for photoelectrochemical hydrogen production. Energy Conversion and Management 2020, 205.
10、Sun, Q.; Li, B.; Li, A.; Shao, Y.; He, Z.; Lu, X.; Zhu, L.; Huang, Z., Insight into fuel reactivity effects on thermochemical fuel reforming (TFR). International Journal of Hydrogen Energy 2020, 45, (15), 9010-9024.
11、朱磊,李昂,張真英男,黃震.船用重油多元模型燃料的構建與驗證[J].內燃機工程,2020,41(06):36-45.

2019年論文
1. Predicting sooting tendencies of oxygenated hydrocarbon fuels with machine learning algorithms. Fuel, 2019, 242: 438-446.
2. Experimental and kinetic modeling study of ignition characteristics of RP-3 kerosene over low-to-high temperature ranges in a heated rapid compression machine and a heated shock tube, Combustion and Flame, 2019, 203:157-169.
3. Effects of natural gas, ethanol, and methanol enrichment on the performance of in-cylinder thermochemical fuel reforming (TFR) spark-ignition natural gas engine. Applied Thermal Engineering. 2019, 159:113913.
4. Predictions of Oxidation and Autoignition of Large Methyl Ester with Small Molecule Fuels. Fuel, 2019, 251, 162-174.
5. Experimental and Modeling Study on Autoignition of a Biodiesel/n-Heptane Mixture and Related Surrogate in a Heated Rapid Compression Machine. Energy & Fuels, 2019, 33:4552-4563.
6. Experimental and modeling validation of a large diesel surrogate: Autoignition in heated rapid compression machine and oxidation in flow reactor. Combustion and Flame, 2019, 202:195-207.
7. Engine performance and octane on demand studies of a dual fuel spark ignition engine with ethanol/gasoline surrogates as fuel. Energy Conversion and Management, 2019, 183: 296-306.
8. An experimental and kinetic modeling study of n-butylcyclohexane over low-to-high temperature ranges. Combustion and Flame, 2019, 206:83-97.
9. An experimental study on combustion and particulate emissions characteristics on a dual-injection gasoline engine. Applied Thermal Engineering. 2019, 156:722-729.

2018年論文
[1] Z Gao, L Zhu*, X Zou, C Liu, B Tian, Z Huang. Soot reduction effects of dibutyl ether (DBE) addition to a biodiesel surrogate in laminar coflow diffusion flames. Proceedings of combustion institute, 2019, 37:1265-1272.
[2] C Liu, L Zhu*, Z Gao, H Li, Z Huang. Effects of molecular O2 and NO2 on particle size distribution, morphology and nanostructure of diffusion flame soot oxidized in a flow reactor. Fuel, 2018, 234：335-346.
[3] Ang Li, Lei Zhu*,Yebing Mao, Jiaqi Zhai, Dong Han, Xingcai Lyu, Zhen Huang. Surrogate Formulation Methodology for Biodiesel Based on Chemical Deconstruction in Consideration of Molecular Structure and Engine Combustion Factors. Combustion and Flame, 2019, 199:152-167.
[4] Wenxia Ji, Lei Zhu*, Xingcai Lv, Zhen Huang. Numerical Study of NOx and ISFC Co-optimization on a Low-speed Two-stroke Engine by Miller Cycle, EGR, Intake Air Humidification and Injection strategy. Applied Thermal Engineering, 2019, 153:398-408.

2017年發(fā)表論文
[1] L. Zhu*, Z.Y. He, Z. Xu, X.C. Lu, J.H. Fang, W.G. Zhang, Z. Huang. In-cylinder thermochemical fuel reforming (TFR) in a spark-ignition natural gas engine. Proceedings of combustion institute, 2017, 36: 3487-3497.
[2] Z.Y. He, L. Zhu*, Z. Xu, O.T. Kaario, A. Li, Z. Huang. Effects of ethanol enrichment on in-cylinder thermochemical fuel reforming (TFR) spark ignition natural gas engine. Fuel, 2017, 197: 334-342.
[3] O.T. Kaario, V. Vurinen, L. Zhu, M. Larmi, R. Liu. Mixing and evaporation analysis of a high-pressure SCR system using a hybrid LES-RANS approach. Energy, 2017, 120:827-841.
[4] L. Zhu*, Z.Y. He, Z. Xu, Z. Gao, A. Li, Z. Huang. Improving cold start, combustion and emission characteristics of a lean burn spark ignition natural gas engine with multi-point hydrogen injection. Applied Thermal Engineering 2017, 121:83-89.
[5] Z Xu, L Zhu*, Z He, A Li, Y Shao, Z Huang. Performance optimization of in-cylinder thermochemical fuel reforming (TFR) with compression ratio in an SI natural gas engine. Fuel 2017, 203:162-170.
[6] Z Gao, L Zhu*, C Liu, A Li, Z He, C Zhang, Z Huang. A comparison of soot formation, evolution and oxidation reactivity of two biodiesel surrogates. Energy & Fuels 2017, 31: 8655-8664.
[7] A Li, L Zhu*, ZW Deng, Z Gao, Z Huang. A Fundamental Investigation into Chemical Effects of Carbon Dioxide on Intermediate Temperature Oxidation of Biodiesel Surrogate with Laminar Flow Reactor. Energy 2017, 141:20-31.
[8] A Li, ZW Deng, L Zhu*, Z Huang. Development and Validation of a Binary Surrogate Model for Biodiesel. SAE Technical Paper 2017-01-2326.
[9] ZW Deng, A Li, L Zhu*, Z Huang. Experimental and Kinetic Analyses of Thermochemical Fuel Reforming (TFR) with Alcohol Enrichment in Plug Flow Reactor: a Verification of In-Cylinder TFR. SAE Technical Paper 2017-01-2278.
[10] Z Gao, L Zhu*, X Zou, C Liu, Z Huang. Partial Premixing Effects on the Evolution of Soot Morphology and Nanostructure in Co- Flow Flames of a Biodiesel Surrogate. SAE Technical Paper 2017-01-2397.

2016年發(fā)表論文
[1] L. Zhu*, C.S. Cheung, Z. Huang. Impact of chemical structure of individual fatty acid esters on combustion and emission characteristics of diesel engine. Energy 2016, 107: 305-320.
[2] L. Zhu*, C.S. Cheung, Z. Huang. Combustion, gaseous and particulate emission of a diesel engine fueled with n-pentanol (C5 alcohol) blended with waste cooking oil biodiesel. Applied Thermal Engineering 2016, 102: 73-79.
[3] L. Zhu*, C.S. Cheung, Z. Huang. A comparison of particulate emission for rapeseed oil methyl ester, palm oil methyl ester and soybean oil methyl ester in perspective of their fatty ester composition. Applied Thermal Engineering 2016, 94: 249-255.
[4] Z He, Z Gao, L. Zhu*, S Li, A Li, W Zhang, Z Huang. Effects of H 2 and CO enrichment on the combustion, emission and performance characteristics of spark ignition natural gas engine. Fuel 2016, 183: 230:237.
[5] L. Zhu*, Z.Y. He, Z. Xu, X.C. Lu, J.H. Fang, W.G. Zhang, Z. Huang. In-cylinder thermochemical fuel reforming (TFR) in a spark-ignition natural gas engine. 36th International Symposium on Combustion, Korea, 2016.
[6] He, Z., Xu, Z., Zhu, L.*, Zhang, W. et al., The Performances of a Spark Ignition Natural Gas Engine Coupled with In-Cylinder Thermochemical Fuel Reforming (TFR). SAE Technical Paper 2016-01-2239.


2015年發(fā)表論文
[1] L. Zhu*, C.S. Cheung, W.G. Zhang, Z. Huang. Compatibility of Different Biodiesel Composition with Acrylonitrile Butadiene Rubber (NBR). Fuel 2015, 158: 288-292.
[2] Z.Y. He, Q.J. Jing, L. Zhu*, W.G. Zhang, Z Huang. The effects of different intake charge diluents on the combustion and emission characteristics of a spark ignition natural gas engine. Applied Thermal Engineering 2015, 89: 958-967.
[3] Y.Q. Luo, L. Zhu*, J.H. Fang, Z.Y. Zhuang, C. Guan, C. Xia, X.M. Xie, Z. Huang. Size distribution, chemical composition and oxidation reactivity of particulate matter from gasoline direct injection (GDI) engine fueled with ethanol-gasoline fuel. Applied Thermal Engineering 2015, 89: 647-655.

2010-2014年發(fā)表SCI論文
[1] L. Zhu, C.S. Cheung, W.G. Zhang, Z. Huang. Emissions characteristics of a diesel engine operating on biodiesel and biodiesel blended with ethanol and methanol. Science of The Total Environment 2010, 408:914-921.
[2] L. Zhu, W.G. Zhang, W. Liu, Z. Huang. Experimental study on particulate and NOx emissions of a diesel engine fueled with ultra low sulfur diesel, RME-diesel blends and PME-diesel blends. Science of The Total Environment 2010, 408:1050-1058.
[3] L. Zhu, C.S. Cheung, W.G. Zhang, Z. Huang. Influence of methanol-biodiesel blends on the particulate emissions of a direct injection diesel engine. Aerosol Science and Technology 2010, 44:362-369.
[4] L. Zhu, C.S. Cheung, W.G. Zhang, Z. Huang. Combustion, performance and emission characteristics of a DI diesel engine fueled with ethanol-biodiesel blends. Fuel 2011, 90:1743-1750.
[5] L. Zhu, W.G. Zhang, Z. Huang. Influence of biodiesel-methanol blends on the emissions in the low-temperature combustion of a direct-injection diesel engine using high levels of exhaust gas recirculation. Proc. IMechE Part D: J. Automobile Engineering 2011, 225:1044-1054.
[6] L. Zhu, C. S. Cheung, W.G. Zhang, Z. Huang. Effect of charge dilution on gaseous and particulate emissions from a diesel engine fueled with biodiesel and biodiesel blended with methanol and ethanol. Applied Thermal Engineering 2011, 31:2271-2278.
[7] L. Zhu, C.S. Cheung, W.G. Zhang, J.H. Fang, Z. Huang. Effects of ethanol-biodiesel blends and diesel oxidation catalyst (DOC) on particulate and unregulated emissions. Fuel 2013, 113, 690-696.
[8] C.S. Cheung, L. Zhu, Z. Huang. Regulated and unregulated emissions from a diesel engine fueled with biodiesel and biodiesel blended with methanol. Atmospheric Environment 2009, 43: 4865-4872.
[9] W. Liu, W.G. Zhang, L. Zhu, X.L. Li, Z. Huang. Characteristics of ultrafine particle from a compression-ignition engine fueled with low-sulfur diesel. Chinese Science Bulletin 2009, 54: 1773-1778.
[10] Q. Fang, Z. Huang, L. Zhu, J.J. Zhang, J. Xiao. Study on low nitrogen oxide and low smoke emissions in a heavy-duty engine fuelled with dimethyl ether. Proc. IMechE Part D: J. Automobile Engineering, 2011, 225: 779-786.
[11] Z.Z. Li, J.Y. Zhang, K.Q. Zhang, L. Zhu, Z. Huang. An experimental study of HCCI high load extension of HCCI engine with gasoline and n-heptane. Proc. IMechE Part D: J. Automobile Engineering, 2014,0954407014524183
[12] J.Y. Zhang, Z.Z. Li, K.Q. Zhang, L. Zhu, Z. Huang An experiment study of HCCI combustion and emission in a gasoline engine. Thermal Science 2013, 18, 295-306.
[13] 劉煒,張武高,李新令,朱磊,黃震。低硫柴油直噴燃燒超細顆粒排放特性研究。 科學通報 2009, 54: 1773-1778. (SCI).
[14] L. Zhu, J.H. Fang, W.G. Zhang, Z. Huang. The Effects of Diesel Oxidation Catalyst on Particulate Emission of Ethanol-Biodiesel Blend Fuel. SAE Technical Paper 2014-01-2730.

部分會議論文：
[1] 李昂，朱磊，鄧志偉，黃震 基于流動反應器的丁酸甲酯氧化實驗與模擬研究[C] 2016中國工程熱物理學會會議論文
[2] 李昂，朱磊，鄧志偉，黃震 二氧化碳在生物柴油替代燃料丁酸甲酯氧化中的化學作用[C] 2016中國內燃機學會燃燒節(jié)能凈化分會會議論文
[3] 高展，劉春鵬，朱磊，黃震 醇基支鏈長度對短碳鏈脂肪酸酯擴散火焰碳煙顆粒生成及演變的影響[C] 2016中國工程熱物理學會會議論文
[4] 高展，劉春鵬，朱磊，黃震 摻混醇類對丁酸甲酯擴散火焰碳煙顆粒形貌演變及微觀結構影響的實驗研究[C] 2016中國內燃機學會燃燒節(jié)能凈化分會會議論文
[5] 劉春鵬，高展，朱磊，黃震 乙醇對丁酸甲酯擴散火焰碳煙顆粒形貌演變及微觀結構影響的實驗研究[C] 2016中國工程熱物理學會會議論文
[6] 徐震，朱磊，何卓遙，黃震 壓縮比對缸內熱化學燃料重整天然氣發(fā)動機燃燒與排放特性的影響[C] 2016中國工程熱物理學會會議論文
[7] Lei Zhu. Low temperature combustion mode and particulate emission characteristics of biofuels [Invited report]. 6th International Symposium on “Clean and High-Efficiency Combustion in Engines”, Tianjin, 2015.
[8] 何卓遙，徐震，朱磊，黃震 合成氣對天然氣發(fā)動機的燃燒排放性能的影響[C] 中國內燃機學會燃燒節(jié)能凈化分會會議論文
[9] L. Zhu, J.H. Fang, Z. Huang. Low temperature combustion of biodiesel [Oral report]. US-China Clean Energy Research Center for Clean Vehicles Annual Joint Conference, Michigan, 2012.
[10] L. Zhu, J.H. Fang, Z. Huang. Fundamental research of low temperature combustion of biodiesel [Oral report]. US-China Clean Energy Research Center for Clean Vehicles Annual Joint Conference, Beijing, 2013.
[11] L. Zhu, C.S. Cheung, Z. Huang. NOx and Particulate Emissions of a Diesel Engine Operating on biodiesel and biodiesel blended with ethanol and methanol[C]. 7th Asia-Pacific Conference on Combustion, Taiwan, 2009 .
[12] L. Zhu, W.G. Zhang, Z. Huang. Experimental Study on the Particulate Emissions and Unregulated Emissions of DI Diesel Engine Fueled with Ethanol-Biodiesel Blended Fuel[C], Conference of International Council on Combustion Engines (CIMAC), 2012.
[13] 朱磊,張武高,黃震。生物燃料對柴油機低溫燃燒影響的研究。中國內燃機學會燃 燒、節(jié)能、凈化分會 2010 年學術年會,重慶。
[14] 朱磊,張武高,朱浩月,黃震。生物柴油微觀結構對發(fā)動機燃燒排放特性的影響。 中國工程熱物理學會,2011 年燃燒學學術會議,杭州。