代表性论文专著
代表性论文:
[1] J.X. Xu, T.X. Li‡,*, T.S. Tan, S. Wu, M.Q. Wu, J.W. Chao, X.Y. Huo, P.F. Wang, R.Z. Wang. Ultrahigh Solar-Driven Atmospheric Water Production Enabled by Scalable Rapid-Cycling Water Harvester with Vertically Aligned Nanocomposite Sorbent. Energy & Environmental Science 14 (2021) 5979-5994.
(‡Co-first Author and *Co-corresponding Author).
https://doi.org/10.1039/D1EE01723C
[2] T.X. Li‡,*, R.Z. Wang, H. Li. Progress in the Development of Solid-Gas Sorption Refrigeration Thermodynamic Cycle Driven by Low-Grade Thermal Energy. Progress in Energy and Combustion Science 40 (2014) 1-58.
(‡First Author and *Corresponding Author).
http://dx.doi.org/10.1016/j.pecs.2013.09.002
[3] S. Wu, T.X. Li‡,*, Z. Tong, J.W. Chao, T.Y. Zhai, J.X. Xu, T.S. Yan, M.Q. Wu, Z.Y. Xu, H. Bao, T. Deng, R.Z. Wang. High-Performance Thermally Conductive Phase Change Composites by Large-Size Oriented Graphite Sheets for Scalable Thermal Energy Harvesting. Advanced Materials 31(2019) 1905099:1-9.
(‡Co-first Author and *Co-corresponding Author).
https://doi.org/10.1002/adma.201905099
[4] T.S. Yan, T.X. Li‡,*, J.X. Xu, J.W. Chao, R.Z. Wang, Yuri Aristov, L. Gordeeva, P. Dutta, S. Murthy. Ultrahigh-Energy-Density Sorption Thermal Battery Enabled by Graphene Aerogel-based Composite Sorbents for Thermal Energy Harvesting from Air. ACS Energy Letters 6 (2021) 1795-1802.
(‡Co-first Author and *Co-corresponding Author).
https://doi.org/10.1021/acsenergylett.1c00284
[5] J.X. Xu, T.X. Li‡,*, J.W. Chao, S. Wu, T.S. Yan, W.C. Li, B.Y. Cao, R.Z. Wang. Efficient Solar-Driven Water Harvesting from Arid Air with Metal-Organic Frameworks Modified by Hygroscopic Salt. Angewandte Chemie-International Edition 59 (2020) 2-11.
(‡Co-first Author and *Co-corresponding Author).
https://doi.org/10.1002/anie.201915170
Selected as ESI Paper
Selected as Research Highlights by Science Foundation in China of NSFC
[6] J.X. Xu, J.W. Chao, T.X. Li‡,*, T.S. Yan, S. Wu, M.Q. Wu, B.C. Zhao, R.Z. Wang. Near-Zero-Energy Smart Battery Thermal Management Enabled by Sorption Energy Harvesting from Air. ACS Central Science 6 (2020) 1542-1554.
(‡Co-first Author and *Co-corresponding Author).
https://dx.doi.org/10.1021/acscentsci.0c00570
Selected as Cover Paper
[7] S. Wu, T.X. Li‡,*, M.Q. Wu, J.X. Xu, Y.H. Hu, J.W. Chao, T.S. Yan, R.Z. Wang. Highly Thermally Conductive and Flexible Phase Change Composites Enabled by Polymer/Graphite Nanoplatelet-based Dual Networks for Efficient Thermal Management. Journal of Materials Chemistry A 8 (2020) 20011-20020.
(‡Co-first Author and *Co-corresponding Author).
https://doi.org/10.1039/d0ta05904h
[8] S. Wu, T.X. Li‡,*, M.Q. Wu, J.X. Xu, J.W. Chao, Y.H. Hu, T.S. Yan, Q.Y. Li, R.Z. Wang. Dual-Functional Aligned and Interconnected Graphite Nanoplatelet Networks for Accelerating Solar-Thermal Energy Harvesting and Storage within Phase-Change Materials. ACS Applied Materials & Interfaces 13 (2021) 19200-19210.
(‡Co-first Author and *Co-corresponding Author).
https://doi.org/10.1021/acsami.0c22814
[9] T.X. Li‡,*, M.Q. Wu, S. Wu, J.W. Chao, S.Z. Xiang, J.X. Xu, J.W. Chao, T.S. Yan, T. Deng, R.Z. Wang. Highly Conductive Phase Change Composites Enabled by Vertically-Aligned Reticulated Graphite Nanoplatelets for High-Temperature Solar Photo/Electro-Thermal Energy Conversion, Harvesting and Storage. Nano Energy 89 (2021) 106338:1-11.
(‡Co-first Author and *Co-corresponding Author).
https://doi.org/10.1016/j.nanoen.2021.106338
[10] S. Wu, T.X. Li*, Z.Y. Zhang, T. Li, R.Z. Wang. Photoswitchable Phase Change Materials for Unconventional Thermal Energy Storage and Upgrade. Matter 4 (2021) 3385-3399.
(*Co-corresponding Author).
https://doi.org/10.1016/j.matt.2021.09.017
[11] M.Q. Wu, S. Wu, Y.F. Cai, R.Z. Wang, T.X. Li*. Form-Stable Phase Change Composites: Preparation, Performance, and Applications for Thermal Energy Conversion, Storage and Management. Energy Storage Materials 42 (2021) 380-417.
(*Corresponding Author).
https://doi.org/10.1016/j.ensm.2021.07.019
[12] M.Q. Wu, T.X. Li‡,*, P.F. Wang, S. Wu, R.Z. Wang, J. Lin. Dual-encapsulated highly conductive and liquid-free phase change composites enabled by polyurethane/graphite nanoplatelets hybrid networks for efficient energy storage and thermal management. Small 2105647(2021)1-10.
(*Co-corresponding Author).
https://doi.org/10.1002/smll.202105647
[13] Z.L. Liu, J.X. Xu, M. Xu, C.F. Huang, R.Z. Wang, T.X. Li*, X.L. Huai. Ultralow-temperature-driven water-based sorption refrigeration enabled by low-cost zeolite-like porous aluminophosphate. Nature Communications 13 (2022)193:1-10.
(*Co-corresponding Author).
Selected as Editors' Highlights
国际期刊论文:
[14] T.X. Li*, R.Z. Wang, J.K. Kiplagat, Y.T. Kang. Performance analysis of an integrated energy storage and energy upgrade thermochemical solid-gas sorption system for seasonal storage of solar thermal energy. Energy 50 (2013) 454-467. (‡First Author and *Co-corresponding Author). (ESI高被引研究论文)
[15] T.X. Li*, J.H. Lee‡, R.Z. Wang, Y.T. Kang. Enhancement of heat transfer for thermal energy storage application using stearic acid nanocomposite with multi-walled carbon nanotubes. Energy 55 (2013) 752-761. (*Co-first Author). (ESI高被引研究论文)
[16] T.X. Li*, R.Z. Wang, J.K. Kiplagat. A target-oriented solid-gas thermochemical sorption heat transformer for integrated energy storage and energy upgrade. AIChE Journal 59 (2013) 1334-1347.
[17] T.X. Li*, R.Z. Wang, J. K. Kiplagat, L.W. Wang. Performance improvement of a combined double-way thermochemical sorption refrigeration cycle with reheating process. AIChE Journal 56 (2010) 477-484.
[18] T.X. Li*, R.Z. Wang, R.G. Oliveira, L.W. Wang. Performance analysis of an innovative multimode, multisalt and multieffect chemisorption refrigeration system.AIChE Journal 53 (2007) 3222-3230.
[19] T.X. Li*, D.L. Wu, F. He, R.Z. Wang. Experimental investigation on copper foam/hydrated salt composite phase change material for thermal energy storage. International Journal of Heat and Mass Transfer 115 (2017) 148-157
[20] T.X. Li*, R.Z. Wang, T. Yan, T.F. Ishugah. Integrated energy storage and energy upgrade, combined cooling and heating supply, and waste heat recovery with solid-gas thermochemical sorption heat transformer. International Journal of Heat and Mass Transfer 76 (2014) 237-246.
[21] T.X. Li*, J.H. Lee, R.Z. Wang, Y.T. Kang. Heat transfer characteristics of phase change nanocomposite materials for thermal energy storage application. International Journal of Heat and Mass Transfer 75 (2014) 1-11
[22] T.X. Li*, R.Z. Wang, J.K. Kiplagat, H. Chen, L.W. Wang. A new target-oriented methodology of decreasing the regeneration temperature of solid-gas thermochemical sorption refrigeration system driven by low-grade thermal energy. International Journal of Heat and Mass Transfer 54 (2011) 4719-4729.
[23] T.X. Li*, R.Z. Wang, J.K. Kiplagat, H. Chen. Experimental study and comparison of thermochemical resorption refrigeration cycle and adsorption refrigeration cycle. Chemical Engineering Science 65 (2010) 4222-4230.
[24] T.X. Li*, R.Z. Wang, J. K. Kiplagat, L.W. Wang. A conceptual design and performance analysis of a triple-effect sorption refrigeration system with internal heat recovery. Chemical Engineering Science 64 (2009) 3376-3384.
[25] T.X. Li*, R.Z. Wang, L.W. Wang, Z.S. Lu, C.J. Chen. Performance study of a high efficient multifunction heat pipe type adsorption ice making system with novel mass and heat recovery processes. International Journal of Thermal Sciences 46 (2007) 1267-1274.
[26] T.X. Li*, R.Z. Wang, L.W. Wang, Z.S. Lu, J.Y. Wu. Influence of mass recovery on the performance of a heat pipe type ammonia sorption refrigeration system using CaCl2/activated carbon as compound adsorbent. Applied Thermal Engineering 28 (2008) 1638-1646.
[27] T.X. Li*, R.Z. Wang, L.W. Wang, Z.S. Lu. Experimental study on an innovative multifunction heat pipe type heat recovery two-stage sorption refrigeration system. Energy Conversion and Management 49 (2008) 2505-2512.
[28] T.X. Li*, R.Z. Wang, L.W. Wang, J. K. Kiplagat. Study on the heat transfer and sorption characteristics of a consolidated composite sorbent for solar-powered thermochemical cooling systems. Solar Energy 83 (2009) 1742-1755.
[29] T.X. Li*, R.Z. Wang, L.W. Wang. High-efficient thermochemical sorption refrigeration driven by low-grade thermal heat. Science Bulletin 54 (2009) 885-905.
[30] T.X. Li*, R.Z. Wang, L.W. Wang, Z.S. Lu. Experimental investigation of an innovative dual-mode chemisorption refrigeration system based on multifunction heat pipes. International Journal of Refrigeration 31 (2008) 1104-1112.
[31] T.X. Li*, R.Z. Wang, R.G. Oliveira, J.K. Kiplagat, L.W. Wang. A combined double-way chemisorption refrigeration cycle based on adsorption and resorption processes. International Journal of Refrigeration 32 (2009) 47-57.
[32] T.X. Li*, R.Z. Wang, J.K. Kiplagat, L.W. Wang, R.G. Oliveira. Thermodynamic study of a combined double-way solid-gas thermochemical sorption refrigeration cycle. International Journal of Refrigeration 32 (2009) 1570-1578.
[33] T.X. Li*, R.Z. Wang, J.K. Kiplagat, L. Ma. Performance analysis of a multi-mode thermochemical sorption refrigeration system for solar-powered cooling. International Journal of Refrigeration 35 (2012) 532-542.
[34] T.X. Li*, S. Wu, T. Yan, J.X. Xu, R.Z. Wang. A novel solid-gas thermochemical multilevel sorption thermal battery for cascaded solar thermal energy storage. Applied Energy 161 (2016) 1-10
[35] T.X. Li*, R.Z. Wang, L.W. Wang, J.K. Kiplagat. Performance study of a consolidated manganese chloride-expanded graphite compound for sorption deep-freezing processes. Applied Energy 86 (2009) 1201-1209.
[36] T.X. Li*, R.Z. Wang, T. Yan, T. F. Ishugah. Solid-gas thermochemical sorption thermal battery for solar cooling and heating energy storage and heat transformer. Energy 84 (2015) 745-758
[37] T.X. Li*, J.X. Xu, T. Yan, R.Z. Wang. Development of sorption thermal battery for low-grade waste heat recovery and combined cold and heat energy storage. Energy 107 (2016) 347-359
[38] T.X. Li*, S. Wu, T. Yan, R.Z. Wang J. Zhu, Experimental investigation on a dual-mode seasonal solar thermochemical sorption energy storage system. Energy 140 (2017) 383-394.
[39] T. Yan, T.X. Li*, H. Li, R.Z. Wang. Experimental study of the ammonia sorption characteristics on the composite sorbent of CaCl2 and multi-walled carbon nanotubes. International Journal of Refrigeration 46(2014)165-172.
[40] T. Yan, T.X. Li*, Wang R.Z., R. Jia. Experimental investigation on the ammonia adsorption and heat transfer characteristics of the packed multi-walled carbon nanotubes. Applied Thermal Engineering 77 (2015) 20-29.
[41] S. Wu, T.X. Li*, Wang R.Z. High performance form-stable expanded graphite/stearic acid composite phase change material for modular thermal energy storage. International Journal of Heat and Mass Transfer 102 (2016) 733-744.
[42] S. Wu, T.X. Li*, T. Yan, R.Z. Wang. Experimental investigation on a novel solid-gas thermochemical sorption heat transformer for energy upgrade with a large temperature lift. Energy Conversion and Management 148 (2017)330-338.
[43] S. Wu, T.X. Li*, T. Yan, R.Z. Wang. Experimental investigation on a thermochemical sorption refrigeration prototype using EG/SrCl2–NH3 working pair. International Journal of Refrigeration 88 (2018) 8-15.
[44] S. Wu, T.X. Li*, R.Z. Wang. Experimental identification and thermodynamic analysis of ammonia sorption equilibrium characteristics on halide salts. Energy 161 (2018) 955-962.
[45] S. Wu, T.X. Li*, T. Yan, R.Z. Wang. Advanced thermochemical resorption heat transformer for high-efficiency energy storage and heat transformation. Energy 175 (2019) 1222-1233.
[46] T.X. Li*, J.X. Xu, D.L. Wu, F. He, R.Z. Wang. High energy-density and power-density thermal storage prototype with hydrated salt for hot water and space heating. Applied Energy 248 (2019) 406-414.
[47] T.S. Yan, T.X. Li*, J.X. Xu, R.Z. Wang. Water sorption properties, diffusion and kinetics of zeolite NaX modified by ion-exchange and salt impregnation. International Journal of Heat and Mass Transfer 139 (2019) 990-999.
[48] J.X. Xu, T.X. Li*, J.W. Chao, T.S. Yan, R.Z. Wang. High energy-density multi-form thermochemical energy storage using multi-step sorption processes. Energy 185 (2019) 1131-1142.
[49] T.S. Yan, T.X. Li*, J.X. Xu, J.W. Chao. Understanding the transition process of phase change and dehydration reaction of salt hydrate for thermal energy storage. Applied Thermal Engineering 166 (2020) 114655: 1-7.
[50] J.X. Xu, T.X. Li*, T.S. Yan, J.W. Chao, R.Z. Wang. Dehydration Kinetics and Thermodynamics of Magnesium Chloride Hexahydrate for Thermal Energy Storage. Solar Energy Materials and Solar Cells 219 (2021) 110819:1-11.
[51] S. Wu, Q.Y. Li, T. Ikuta, K. Morishita, K. Takahashi, R.Z. Wang, T.X. Li*. Thermal conductivity measurement of an individual millimeter-long expanded graphite ribbon using a variable-length T-type method. International Journal of Heat and Mass Transfer 171(2021)121115:1-9.
[52] M.Q.Wu, T.X. Li*, Q.F. He, R.X. Du Yan, R.Z. Wang. Thermally conductive and form-stable phase change composite for building thermal management. Energy 239 (2022) 121938:1-9.
[53] J.W. Chao, J.X. Xu, T.S. Yan, P.F. Wang, X.Y. Huo, R.Z Wang, T.X. Li*. Enhanced thermal conductivity and sorption rate of zeolite 13X sorbent by compression-induced method for sorption thermal battery. Energy 240(2022)1-10.
[54] Z.S. Lu, R.Z. Wang, T.X. Li, L.W. Wang, C.J. Chen. Experimental investigation of a novel multifunction heat pipe solid sorption icemaker for fishing boats using CaCl2/activated carbon compound–ammonia. International Journal of Refrigeration 30 (2007) 76-85.
[55] R.G. Oliveira, R.Z. Wang, T.X. Li. Transient analysis of a chemisorption air conditioning system operating under different kinds of cycle. Industrial & Engineering Chemistry Research 47 (2008) 1102-1110.
[56] R.G. Oliveira, R.Z. Wang, T.X. Li. Adsorption Characteristic of Methanol in Activated Carbon Impregnated with Lithium Chloride. Chemical Engineering & Technology 33 (2010) 1679-1686.
[57] J.K. Kiplagat, R.Z. Wang, R.G. Oliveira, T.X. Li. Lithium chloride – Expanded graphite composite sorbent for solar powered ice maker. Solar Energy 84 (2010) 1587-1594.
[58] L. Xu, R.Z. Wang, T.X. Li, L.W. Wang. Experimental study on a combined double-way chemisorption refrigeration system. International Journal of Refrigeration 34 (2011) 914-921.
[59] L. Xu, R.Z. Wang, T.X. Li, L.W. Wang. Experimental study on the performance of double-effect and double-way thermochemical sorption refrigeration cycle. Applied Thermal Engineering 31(2011) 3658-3663.
[60] J.K. Kiplagat, R.Z. Wang, T.X. Li. Renewable energy in Kenya: resource potential and status of exploitation. Renewable and Sustainable Energy Reviews 15 (2011) 2960–2973.
[61] J.K. Kiplagat, R.Z. Wang, T.X. Li, R.G. Oliveira. Enhancement of heat and mass transfer in solid-gas sorption systems. International Journal of Air Conditioning and Refrigeration 20 (2012):1130001-16
[62] H.S. Bao, R.Z. Wang, R.G. Oliveira, T.X. Li. Resorption system for cold storage and long-distance refrigeration. Applied Energy 93(2012)479-487.
[63] C. Li, R.Z. Wang, L.W. Wang, T.X. Li, Y. Chen. Experimental study on an adsorption icemaker driven by parabolic trough solar collector. Renewable Energy 57(2013)223-233.
[64] C. Li, T. Yan, R.Z. Wang, L.W. Wang, T.X. Li, X. Li, M. Lin, W. T Xie. An experimental investigation of an adsorption ice-maker driven by parabolic trough collector. Heat Transfer Research 46(2015)347-368.
[65] R.Z. Wang, X. Yu, T.S. Ge, T.X. Li. The present and future of residential refrigeration, power generation and energy storage. Applied Thermal Engineering 53(2013)256-270.
[66] R.Z. Wang, Z.Z. Xia, L.W. Wang, Z.S. Lu, S.L. Li, T.X. Li, J.Y. Wu, S. He. Heat transfer design in adsorption refrigeration systems for efficient use of low-grade thermal energy. Energy 36(2011)5425-5439
[67] J.K. Kiplagat, R.Z. Wang, R.G. Oliveira, T.X. Li. Experimental study on the effects of the operation conditions on the performance of a chemisorption air conditioner powered by low grade heat. Applied Energy 103(2013)571-580.
[68] Y.J. Zhao, R.Z. Wang, T.X. Li, Y. Nomura. Investigation of a 10 kWh sorption heat storage device for effective utilization of low-grade thermal energy. Energy 113 (2016) 739-747.
[69] H.Y. Bai, J. Zhu, Z.W. Chen, L.N. Ma, R.Z. Wang, T.X. Li. Performance testing of a cross-flow membrane-based liquid desiccant dehumidification system. Applied Thermal Engineering 119(2017)119-131.
[70] T. Yan, R.Z. Wang*, T.X. Li, L.W. Wang. A review of promising candidate reactions for chemical heat storage. Renewable and Sustainable Energy Reviews 43(2015)13-31. (ESI高被引论文)
[71] Y.N. Zhang, R.Z. Wang, T.X. Li, Y.J. Zhao. Thermochemical characterizations of novel vermiculite-LiCl composite sorbents for low-temperature heat storage. Energies 9 (2016):2-15.
[72] Y.N. Zhang, R.Z. Wang, Y.J. Zhao, T.X. Li, S.B. Riffat, N.M. Wajid. Development and thermochemical characterizations of vermiculite/SrBr2 composite sorbents for low-temperature heat storage. Energy 115 (2016) 120-128.
[73] Y.N. Zhang, R.Z. Wang, T.X. Li. Experimental investigation on an open sorption thermal storage system for space heating. Energy 141 (2017) 2421-2433.
[74] Y.N. Zhang, R.Z. Wang, T.X. Li. Thermochemical characterizations of high-stable activated alumina/LiCl composites with multistage sorption process for thermal storage. Energy 156 (2018) 240-249.
[75] T. Yan, R. Z. Wang, T.X. Li. Experimental investigation on thermochemical heat storage using manganese chloride/ammonia. Energy 143(2018) 562-574.
[76] B.C. Zhao, T.X. Li, J.C. Gao, R.Z. Wang. Latent heat thermal storage using salt hydrates for distributed building heating: A multi-level scale-up research. Renewable & Sustainable Energy Reviews 121 (2020)109712
[77] I.S. Girnik, A.D. Grekova, T.X. Li, R.Z. Wang, P. Dutta, S. Srinivasa Murthy, Yu.I. Aristov. Composite "LiCl/MWCNT/PVA" for adsorption thermal battery: Dynamics of methanol sorption. Renewable & Sustainable Energy Reviews 123(2020) 109748.
国际会议论文:
[78] T.X. Li, R.Z. Wang, R.G. Oliveira, L.W. Wang. Performance analysis of an innovative chemisorption refrigeration system with very high COP. International Symposium on Innovative Materials for Processes in Energy Systems (IMPRES), Kyoto, Japan, 2007.
[79] T.X. Li, R.Z. Wang, L.W Wang, Z.S. Lu. Experimental investigation of an innovative dual-mode chemisorption refrigeration system based on multifunction heat pipes. The 22nd IIR International Congress of Refrigeration (ICR), Beijing, China, 2007.
[80] T.X. Li, R.Z. Wang, R.G. Oliveira, L.W. Wang, J.Y. Wu. The conceptual design and experimental verification of a double-way chemisorption refrigeration cycle. International Conference on Cryogenics and Refrigeration (ICCR2008), Shanghai, China, 2008.
[81] T.X. Li, R.Z. Wang, R.G. Oliveira, L.W. Wang, J.Y. Wu. Experimental investigation on a combined double-way solid-gas chemisorption refrigeration system using consolidated composite adsorbent. International Sorption Heat Pump Conference (ISHP 2008), Seoul, Korea, 2008.
[82] T.X. Li, R.Z. Wang, J.K. Kiplagat, L. Ma. Performance analysis of a multimodal thermochemical sorption refrigeration cycle for solar-powered cooling systems, SET2010 - 9th International Conference on Sustainable Energy Technologies; Shanghai, China. 24-27 August, 2010
[83] S. Wu. T.X. Li*, T. Yan, R.Z. Wang. Experimental study on a solar-powered thermochemical sorption refrigeration system using strontium chloride/EG-ammonia working pair. 16th International Refrigeration and Air Conditioning Conference, Purdue, USA, July 11-14, 2016.
[84] R.Z. Wang, N. Yu, T.X. Li, L.W. Wang. Sorption Thermal Energy Storage: Concept, Progress and Prospects. 2014 International Sorption Heat Pump Conference (ISHP 2014), Maryland, USA, 2014. March 31-April 3, 2014.
[85] R.Z. Wang, Z.Z. Xia, L.W. Wang, Z. S. Lu, S.L. Li, T.X. Li, J.Y. Wu, S. He. Heat transfer design in adsorption refrigeration systems for efficient use of low grade thermal energy, 14th International Heat Transfer Conference,Washington, DC,2010.8.8-2010.8.13. ISTP
[86] L. Xu, R.Z. Wang, T.X. Li, L.W Wang. Experimental investigation on a combined double-way thermochemical and adsorption refrigeration system. 5th Asian Conference on Refrigeration and Air Conditioning (ACRA 2010), Tokyo, Japan, June 7-9, 2010.
[87] S. Wu,T.X. Li*, T. Yan, R.Z. Wang. An innovative solid-gas chemisorption heat transformer system with a large temperature lift for high-efficiency energy upgrade. 8th Heat Powered Cycles Conference, September 16th-19th, 2018, University of Bayreuth, Germany.
[88] S. Wu, T.X. Li*, R.Z. Wang. Ultrahigh thermal conductive phase change composites for highly efficient thermal energy harvesting. International Conference of Polygeneration (ICP 2019). May 14th-17th, 2019, Fukuoka, Japan.
[89] J.X. Xu, T.X. Li*, R.Z. Wang. Tuning Sorption Characteristics of Metal-organic Framework for High Efficient Sorption Thermal Energy Storage and Atmospheric Water Harvesting. International Conference of Polygeneration (ICP 2019). May 14th-17th, 2019, Fukuoka, Japan.
[90] T.S. Yan, T.X. Li*, J.X. Xu, R.Z. Wang. Hygroscopic salt in graphene oxide hydrogel-derived matrix used for thermochemical energy storage. 5th International Workshop on Heat/Mass Transfer Advances for Energy Conservation and Pollution Control. August 13th-16th, 2019, Novosibirsk, Russia
[91] M.Q. Wu, T.X. Li*, Wu, S. and R.Z Wang. A novel shape-stabilized phase change material for light-thermal conversion and energy storage. 5th International Workshop on Heat/Mass Transfer Advances for Energy Conservation and Pollution Control. August 13th-16th, 2019, Novosibirsk, Russia.
代表性中文论文:
[1] 李廷贤,王如竹,王丽伟 ,低品位热能驱动的高效热化学吸附式制冷研究 ,科学通报,2008, 24:2978-2993.
[2] 仵斯,李廷贤*,闫霆,代彦军,王如竹. 高性能定形复合相变储材料的制备及热研究.化工学报, 2015, 66:5127-5134. 【封面文章】
[3] 许嘉兴,李廷贤*,王如竹. 氯化镁/沸石复合材料的吸附特性及储热性能研究. 化工学报, 2016, 67:348-355. 【封面文章】
[4] 吴东灵,李廷贤*,何峰,王如竹. 三水醋酸钠相变储能复合材料改性制备及储/放热特性. 化工学报, 2018, 69:2860-2868. 【封面文章】
[5] 许嘉兴,晁京伟,李廷贤*,王如竹. 膨胀石墨/有机金属骨架复合吸附材料的制备及性能研究. 化工学报, 2018, 69:2860-2868. 【封面文章】
[6] 翟天尧,李廷贤*,仵斯,王如竹. 高导热膨胀石墨/硬脂酸定形相变储能复合材料的制备及储/放热特性. 科学通报,2018, 63: 674-683. 【封面文章】