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學(xué)院首頁(yè) > 師資隊(duì)伍 > 教師名錄 > 教學(xué)科研型

教學(xué)科研型

李曉雅

副教授

所在系所：制冷與低溫工程研究所

辦公電話：

電子郵件：xiaoya.li AT sjtu.edu.cn

通訊地址：上海市東川路800號(hào) 上海交大機(jī)械與動(dòng)力工程學(xué)院A樓432室

個(gè)人主頁(yè)：https://orcid.org/0000-0001-6844-6701 目前招收博士后、博士生、碩士生及本科生！

個(gè)人簡(jiǎn)介

科研工作

指導(dǎo)學(xué)生

榮譽(yù)獎(jiǎng)勵(lì)

其他

教育背景

2014.09-2020.01 天津大學(xué) 動(dòng)力機(jī)械及工程博士
2011.09-2014.07 南開(kāi)大學(xué) 金融學(xué) 學(xué)士
2010.09-2014.07 天津大學(xué) 熱能與動(dòng)力工程學(xué)士

2018.09-2019.09 帝國(guó)理工學(xué)院 Clean Energy Processes 博士聯(lián)合培養(yǎng)

2018.09-2019.09 比利時(shí)根特大學(xué) Applied thermodynamics & heat transfer 博士聯(lián)合培養(yǎng)

工作經(jīng)歷

2023.11-至今上海交通大學(xué) 機(jī)械與動(dòng)力工程學(xué)院副教授
2020.11-2023.11 南洋理工大學(xué) 電氣與電子工程學(xué)院 Research Fellow
2020.06-2020.11 中國(guó)科學(xué)技術(shù)大學(xué) 熱科學(xué)與能源工程系博士后

研究方向

低品位余熱利用

整車/電池?zé)峁芾?/span>

先進(jìn)儲(chǔ)能技術(shù)
智能傳感

歡迎具有工程熱物理、電化學(xué)、能源材料與控制等專業(yè)背景的本科生、碩士生、博士生、博士后加入課題組開(kāi)展學(xué)科交叉研究！
招生情況：每年招收博士生1名，碩士生2名。提供本科生科研見(jiàn)習(xí)崗位。

2025年秋季尚有碩士名額，歡迎郵件聯(lián)系！

學(xué)術(shù)兼職

青年編委：Applied Energy, International Journal of Green Energy
客座編輯：Sustainability, Frontiers in Energy Research, Frontiers in Mechanical Engineering
評(píng)審編輯：Frontiers in Energy Research

分會(huì)場(chǎng)主席（國(guó)內(nèi)會(huì)議）：第十三屆全國(guó)制冷空調(diào)新技術(shù)研討會(huì)

分會(huì)場(chǎng)主席（國(guó)際會(huì)議）：14th International Green Energy Conference (IGEC-XIV), Virtual Conference, July 4-8, 2022; 15th International Green Energy Conference (IGEC-XV), Glasgow, United Kingdom, July 10-13, 2023
技術(shù)委員會(huì)成員：14th International Green Energy Conference (IGEC-XIV), Virtual Conference, July 4-8, 2022; 15th International Green Energy Conference (IGEC-XV), Glasgow, United Kingdom, July 10-13, 2023
期刊同行評(píng)議專家: Nature Communication, Applied Energy, Energy Conversion and Management, Energy, Renewable Energy, Applied Thermal Engineering, Journal of Cleaner Production, International Journal of Energy Research, International Journal of Green Energy等

科研項(xiàng)目

主持項(xiàng)目：

2025-2027 國(guó)家級(jí)高層次青年人才計(jì)劃項(xiàng)目

2025-2027 國(guó)家自然科學(xué)基金青年科學(xué)基金項(xiàng)目

2024-2027 上海市“科技創(chuàng)新行動(dòng)計(jì)劃”啟明星培育（揚(yáng)帆專項(xiàng)）

2023-2026 上海交通大學(xué)“雙一流”建設(shè)項(xiàng)目

參與項(xiàng)目：

2020-2023 新加坡MOE Academic Research Fund (AcRF) TIER 2項(xiàng)目，Highly efficient electrochemical low-grade heat harvesting，參加
2018-2019 英國(guó)EPSRC項(xiàng)目，Energy-Use Minimisation via High Performance Heat-Power-Cooling Conversion and Integration: A Holistic Molecules to Technologies to Systems Approach，參加
2018-2020 國(guó)家重點(diǎn)研發(fā)計(jì)劃，基于CO2基非共沸混合工質(zhì)循環(huán)的發(fā)動(dòng)機(jī)余熱回收技術(shù)研究，參加
2018-2020 國(guó)家重點(diǎn)研發(fā)計(jì)劃，提高中載及重載卡車能效關(guān)鍵技術(shù)中美聯(lián)合研究，參加
2017-2020 國(guó)家自然科學(xué)基金重點(diǎn)項(xiàng)目，移動(dòng)裝置內(nèi)燃機(jī)余熱回收CO2動(dòng)力循環(huán)多能流耦合關(guān)鍵問(wèn)題研究，參加
2014-2015 科技部973項(xiàng)目，高效、節(jié)能、低碳內(nèi)燃機(jī)余熱能梯級(jí)利用基礎(chǔ)研究，參加
2012-2013 天津大學(xué)大學(xué)生創(chuàng)新創(chuàng)業(yè)訓(xùn)練計(jì)劃（國(guó)家級(jí)），內(nèi)燃機(jī)廢氣余熱回收有機(jī)朗肯循環(huán)系統(tǒng)設(shè)計(jì)，參加

代表性論文專著

2024：

[1] Wenshuai Que#, Xiaoya Li#, Xiaoting Chen, Mingzhang Pan*, Changcheng Fu, Lu Liang, Tiecheng Su. Potential of solid oxide fuel cells as marine engine assisted by combined cooling and power cogeneration systems. Applied Thermal Engineering, 2024, 254: 123821.

[2] Xiaoya Li, Ruzhu Wang*. Towards integrated thermal management systems in battery electric vehicles: A review. eTransportation, 2025, 24: 100396.

2023年及以前：

[1] Mingzhang Pan, Wenshuai Que, Xiaoya Li*, Zongrun Wang, Yue Zeng, Xiaorong Zhou. A novel multi-generation energy harvesting system integrating photovoltaic and solid oxide fuel cell technologies. Journal of Cleaner Production, 2023, 425, 138770.
[2] Xiaoya Li, Angyin Wu, Jia Li, Zongkang Li, Donghoon Lee, Seok Woo Lee*. Anion Effects on Thermopower of Electrochemical Systems for Low-Grade Heat Harvesting. ACS Energy Letters, 2023, 8, 4061-4068. (副封面論文Supplementary Cover)
[3] Xiaoting Chen, Xiaoya Li*, Mingzhang Pan, Zongrun Wang. Superstructure-free synthesis and multi-objective optimization of supercritical CO2 cycles. Energy Conversion and Management, 2023, 284: 116966.
[4] Xiaoya Li, Angyin Wu, Caitian Gao, Zongkang Li, Seok Woo Lee*. Copper hexacyanoferrate as a long-life cathode for aqueous aluminum ion batteries. Materials Today Energy, 2023, 31: 101205.
[5] Xiaoya Li, Jia Li, Jeonghun Yun, Angyin Wu, Caitian Gao, Seok Woo Lee*. Continuous thermally regenerative electrochemical systems for directly converting low-grade heat to electricity. Nano Energy, 2022, 101: 107547.
[6] Xiaoya Li, Wen Su*, Weicong Xu, Baomin Dai, Jian Li, Liang Li. Editorial: CO2-based energy systems for cooling, heating, and power. Frontiers in Energy Research, 2022, 10: 993093.
[7] Xiaoting Chen, Mingzhang Pan, Xiaoya Li*, Ke Zhang. Multi-mode operation and thermo-economic analyses of combined cooling and power systems for recovering waste heat from data centers. Energy Conversion and Management, 2022, 266: 115820.
[8] Mingzhang Pan#, Xiaoting Chen#, Xiaoya Li*. Multi-objective analysis and optimization of cascade supercritical CO2 cycle and organic Rankine cycle systems for waste-to-energy power plant. Applied Thermal Engineering, 2022, 214: 118882.
[9] Ke Zhang#, Mingzhang Pan#, Xiaoya Li*. A novel efficient and economic integrated energy system based on solid oxide fuel cell with energy storage and carbon dioxide capture. Energy Conversion and Management, 2022, 252: 115084.
[10] Xiaoting Chen, Mingzhang Pan, Xiaoya Li*. Novel supercritical CO2/organic Rankine cycle systems for solid-waste incineration energy harvesting: Thermo-environmental analysis. International Journal of Green Energy, 2022, 19(7): 786-807.
[11] Mingzhang Pan, Ke Zhang, Xiaoya Li*. Optimization of supercritical carbon dioxide based combined cycles for solid oxide fuel cell-gas turbine system: Energy, exergy, environmental and economic analyses. Energy Conversion and Management, 2021, 248: 114744.
[12] Xiaoya Li, Bin Xu*, Hua Tian, Gequn Shu. Towards a novel holistic design of organic Rankine cycle (ORC) systems operating under heat source fluctuations and intermittency. Renewable and Sustainable Energy Reviews, 2021, 147: 111207.
[13] Xiaoya Li*, Steven Lecompte*, Jera Van Nieuwenhuyse, Kenny Couvreur, Hua Tian, Gequn Shu, Michel De Paepe, Christos N. Markides. Experimental investigation of an organic Rankine cycle with liquid-flooded expansion and R1233zd(E) as working fluid. Energy Conversion and Management, 2021, 234: 113894.
[14] Bin Xu, Xiaoya Li*. A Q-learning based transient power optimization method for organic Rankine cycle waste heat recovery system in heavy duty diesel engine applications. Applied Energy, 2021, 286: 116532.
[15] Xiaoya Li, Hua Tian*, Gequn Shu*, Mingru Zhao, Christos N. Markides, Chen Hu. Potential of carbon dioxide transcritical power cycle waste-heat recovery systems for heavy-duty truck engines. Applied Energy, 2019, 250: 1581-1599.
[16] Xiaoya Li, Gequn Shu*, Hua Tian*. Integrating off-design performance in designing CO2 power cycle systems for engine waste heat recovery. Energy Conversion and Management, 2019, 201: 112146.
[17] Xiaoya Li, Jian Song, Guopeng Yu, Youcai Liang, Hua Tian, Gequn Shu*, Christos N. Markides*. Organic Rankine cycle systems for engine waste-heat recovery: heat exchanger design in space-constrained applications. Energy Conversion and Management, 2019, 199: 111968.
[18] Xiaoya Li, Gequn Shu, Hua Tian*, Guangdai Huang, Peng Liu, Xuan Wang, Lingfeng Shi. Experimental comparison of dynamic responses of CO2 transcritical power cycle systems used for engine waste heat recovery. Energy Conversion and Management, 2018, 161: 254-265.
[19] Xiaoya Li, Hua Tian*, Gequn Shu*, Chen Hu, Rui Sun, Ligeng Li. Effects of external perturbations on dynamic performance of carbon dioxide transcritical power cycles for truck engine waste heat recovery. Energy, 2018, 163: 920-931.
[20] Xiaoya Li, Gequn Shu, Hua Tian*, Lingfeng Shi, Guangdai Huang, Tianyu Chen, Peng Liu. Preliminary tests on dynamic characteristics of a CO2 transcritical power cycle using an expansion valve in engine waste heat recovery. Energy, 2017, 140: 696-707.

軟件版權(quán)登記及專利

[1] 舒歌群，李曉雅，田華，胡琛，石凌峰。一種回收內(nèi)燃機(jī)余熱的小型化集成系統(tǒng)及其控制方法。專利號(hào)：ZL201810359915.X，授權(quán)公告日：2020-07-21。
[2] 舒歌群，石凌峰，田華，黃廣岱，李曉雅。適用于二級(jí)有機(jī)朗肯循環(huán)的雙工質(zhì)膨脹機(jī)。專利號(hào)：ZL201510434392.7，授權(quán)公告日：2017-06-16。
[3] Gequn Shu, Lingfeng Shi, Hua Tian, Guangdai Huang, Xiaoya Li, Double-working-medium expander used for two-stage organic Rankine cycle, 2017.12.25, 美國(guó), US15/739,760
[4] 石凌峰，田華，舒歌群，衛(wèi)海橋，梁興雨，王悅，李曉雅。一種可調(diào)式二氧化碳煙氣換熱器。專利號(hào)：ZL201720224886.7，授權(quán)公告日；2017-10-27。

博士

穆碩碩

2024級(jí)

沙樂(lè)

2025級(jí)

程志豪

2025級(jí)

碩士

沈屹晨

2024級(jí)

李雨卿

2024級(jí)

丁禛

2025級(jí)

本科

陳俊卿

2022級(jí)

孫一凡

2023級(jí)

劉超杰

2024級(jí)

吳沛洵

2023級(jí)

2025 上海交通大學(xué)機(jī)動(dòng)學(xué)院2024年度班主任考核優(yōu)秀

2024 國(guó)家級(jí)高層次青年人才

2024 上海市白玉蘭人才(青年）

2020 中國(guó)汽車工程學(xué)會(huì)優(yōu)秀博士學(xué)位論文
2020 天津大學(xué)優(yōu)秀畢業(yè)生
2019 寶鋼教育基金優(yōu)秀學(xué)生獎(jiǎng)
2018 博士研究生國(guó)家獎(jiǎng)學(xué)金
2014 天津大學(xué)優(yōu)異生

特邀報(bào)告：

[1] 第16屆國(guó)際綠色能源會(huì)議/第5屆能源與人工智能國(guó)際會(huì)議/化學(xué)工程與人工智能研討會(huì)，Entropy change regulation in thermally regenerative electrochemical cycles, 2024年7月3日。

[2] 第6期清潔能源科學(xué)與技術(shù)青年科技論壇，低溫余熱利用熱電轉(zhuǎn)換技術(shù)研究, 2024年12月27日。

會(huì)議論文：
[1] Xiaoya Li, Seok Woo Lee*. Ion-specific effects on the electrochemical thermopower in nickel hexacyanoferrate. The 18th International Conference on Nano/Micro Engineered and Molecular Systems (IEEE NEMS 2023).
[2] Xiaoya Li, Jia Li, Jeonghun Yun, Angyin Wu, Caitian Gao, Seok Woo Lee*. A continuously operated electrochemical system driven by low-grade thermal energy. 2022 MRS Spring Meeting & Exhibit.
[3] Xiaoya Li, Jian Song, Michael Simpson, Kai Wang, Paul Sapin, Gequn Shu*, Hua Tian, Christos N. Markides*. Thermo-economic comparison of organic Rankine and CO2-cycle systems for low-to-medium temperature applications. 5th International Seminar on ORC Power Systems (ORC2019).
[4] Xiaoya Li, Gequn Shu, Hua Tian*, Chen Hu, Rui Sun, Ligeng Li. Effects of pump speed perturbation on dynamic responses of CO2 transcritical power cycle. 6th International Conference on Cryogenics and Refrigeration (ICCR2018).

合作論文：
[1] Jia Li, Xiaoya Li, Donghoon Lee, Jeonghun Yun, Angyin Wu, Cheng Jiang, Seok Woo Lee*. Engineering of Solvation Entropy by Poly(4-styrenesulfonic acid) Additive in an Aqueous Electrochemical System for Enhanced Low-Grade Heat Harvesting. Nano Letters, 2023, 23, 6164?6170.
[2] Zongkang Li, Jeonghun Yun, Xiaoya Li, Moobum Kim, Jia Li, Donghoon Lee, Angyin Wu, Seok Woo Lee*. Power-free contact lens for glucose sensing. Advanced Functional Materials, 2023, 2304647.
[3] Jeonghun Yun#, Zongkang Li#, Xinwen Miao, Xiaoya Li, Jae Yoon Lee, Wenting Zhao, Seok Woo Lee*. A tear-based battery charged by biofuel for smart contact lenses. Nano Energy, 2023, 110: 108344.
[4] Angyin Wu, Xiaoya Li, Donghoon Lee, Jia Li, Jeonghun Yun, Cheng Jiang, Zongkang Li, Seok Woo Lee*. Thermoresponsive ionic liquid for electrochemical low-grade heat harvesting. Nano Energy, 2023, 105: 108022.
[5] Jia Li#, Peihua Yang#,*, Xiaoya Li, Cheng Jiang, Jeonghun Yun, Wenqi Yan, Kang Liu, Hong Jin Fan*, Seok Woo Lee*. Ultrathin smart energy-storage devices for skin-interfaced wearable electronics. ACS Energy Letters, 2023, 8: 1-8. (封面論文Front Cover)
[6] Yezhou Liu, Caitian Gao, Jeonghun Yun, Yeongae Kim, Jia Li, Xiaoya Li, Seok Woo Lee*. Thermally assisted alkali/zinc ion hybrid battery for high roundtrip efficiency. ACS Applied Energy Materials, 2022, 5, 3: 2780-2785.
[7] 陳崇輝，歐少端，蘇文*，李曉雅，藺新星，周乃君．基于有機(jī)工質(zhì)及CO2的跨臨界動(dòng)力循環(huán)研究進(jìn)展[J/OL]．潔凈煤技術(shù). https://kns.cnki.net/kcms/detail/11.3676.TD.20211119.1818.003.html
[8] Jian Song, Xiaoya Li, Kai Wang, Christos N. Markides*. Parametric optimisation of a combined supercritical CO2 (S-CO2) cycle and organic Rankine cycle (ORC) system for internal combustion engine (ICE) waste-heat recovery. Energy Conversion and Management, 2020, 218: 112999.
[9] Bin Xu, Dhruvang Rathod*, Adamu Yebi, Xueyu Zhang, Darui Zhang, Xiaoya Li, Zoran Filipi. Parametric study on reinforcement learning optimized energy management strategy for a hybrid electric vehicle. Applied Energy, 2020, 259: 114200.
[10] Rui Wang, Gequn Shu*, Xuan Wang*, Hua Tian, Xiaoya Li, Mingtao Wang, Jinwen Cai. Dynamic performance and control strategy of CO2-mixture transcritical power cycle for heavy-duty diesel engine waste-heat recovery. Energy Conversion and Management, 2020, 205: 112389.
[11] Gequn Shu, Rui Wang, Hua Tian*, Xuan Wang*, Xiaoya Li, Jinwen Cai, Zhiqiang Xu. Dynamic performance of the transcritical power cycle using CO2-based binary zeotropic mixtures for truck engine waste heat recovery. Energy, 2020, 194: 116825.
[12] Jian Song, Xiaoya Li, Xiaodong Ren, Hua Tian, Gequn Shu, Chunwei Gu, Christos N. Markides*. Thermodynamic and economic investigations of transcritical CO2-cycle systems with integrated radial-inflow turbine performance predictions. Applied Thermal Engineering, 2019, 165: 114604.
[13] Gequn Shu, Chen Hu, Hua Tian*, Xiaoya Li, Zhigang Yu, Mingtao Wang. Analysis and optimization of coupled thermal management systems used in vehicles. Energies, 2019, 12(7): 1265.
[14] Chinedu K. Unamba, Paul Sapin, Xiaoya Li, Jian Song, Kai Wang, Gequn Shu, Hua Tian, Christos N. Markides. Operational optimisation of a non-recuperative 1-kWe organic Rankine cycle engine prototype. Applied Sciences, 2019, 9(15): 3024.
[15] Xuan Wang, Gequn Shu*, Hua Tian*, Wei Feng, Peng Liu, Xiaoya Li. Effect factors of part-load performance for various organic rankine cycles using in engine waste heat recovery. Energy Conversion and Management, 2018, 174: 504-515.
[16] Xuan Wang, Gequn Shu, Hua Tian*, Peng Liu, Dongzhan Jing, Xiaoya Li. The effects of design parameters on the dynamic behavior of organic ranking cycle for the engine waste heat recovery. Energy, 2018, 147: 440-450.
[17] Gequn Shu, Xiaonan Ma, Hua Tian*, Haoqi Yang, Tianyu Chen, Xiaoya Li. Configuration optimization of the segmented modules in an exhaust-based thermoelectric generator for engine waste heat recovery. Energy, 2018, 160: 612-624.
[18] Lingfeng Shi, Gequn Shu, Hua Tian*, Guangdai Huang, Xiaoya Li, Tianyu Chen, Ligeng Li. Experimental investigation of a CO2-based transcritical Rankine cycle (CTRC) for exhaust gas recovery. Energy, 2018, 165(Part B): 1149-1159.
[19] Hua Tian*, Linqing Li, Gequn Shu*, Nanhua Yan, Xiaoya Li, Zhigang Yu. Composition shift in zeotropic mixture-based organic Rankine cycle system for harvesting engine waste heat. International Journal of Energy Research, 2018, 42(14): 4345-4359.
[20] Gequn Shu, Xiaoya Li, Hua Tian*, Lingfeng Shi, Xuan Wang, Guopeng Yu. Design condition and operating strategy analysis of CO2 transcritical waste heat recovery system for engine with variable operating conditions. Energy Conversion and Management, 2017, 142: 188-199. (導(dǎo)師一作，本人二作)
[21] Lingfeng Shi, Gequn Shu, Hua Tian*, Guangdai Huang, Tianyu Chen, Xiaoya Li, Daiqiang Li. Experimental comparison between four CO2-based transcritical Rankine cycle (CTRC) systems for engine waste heat recovery. Energy Conversion and Management, 2017, 150: 159-171.
[22] Xuan Wang, Gequn Shu*, Hua Tian*, Peng Liu, Dongzhan Jing, Xiaoya Li. Dynamic analysis of the dual-loop organic Rankine cycle for waste heat recovery of a natural gas engine. Energy Conversion and Management, 2017, 148: 724-736.
[23] Gequn Shu, Xuan Wang, Hua Tian*, Peng Liu, Dongzhan Jing, Xiaoya Li. Scan of working fluids based on dynamic response characters for organic Rankine cycle using for engine waste heat recovery. Energy, 2017, 133: 609-620.
[24] Xuan Wang, Gequn Shu*, Hua Tian, Peng Liu, Xiaoya Li, Dongzhan Jing. Engine working condition effects on the dynamic response of organic Rankine cycle as exhaust waste heat recovery system. Applied Thermal Engineering, 2017, 123: 670-681.
[25] Lingfeng Shi, Gequn Shu, Hua Tian*, Guangdai Huang, Liwen Chang, Tianyu Chen, Xiaoya Li. Ideal point design and operation of CO2-based transcritical Rankine cycle (CTRC) system based on high utilization of engine's waste heats. Energies, 2017, 10(11): 1692.
[26] Gequn Shu, Lingfeng Shi, Hua Tian*, Shuai Deng, Xiaoya Li, Liwen Chang. Configurations selection maps of CO2-based transcritical Rankine cycle (CTRC) for thermal energy management of engine waste heat. Applied Energy, 2017, 186: 423-435.
[27] Gequn Shu, Lingfeng Shi, Hua Tian*, Xiaoya Li, Guangdai Huang, Liwen Chang. An improved CO2-based transcritical Rankine cycle (CTRC) used for engine waste heat recovery. Applied Energy, 2016, 176: 171-182.