1995—1998    中國科學(xué)院力學(xué)研究所 (流體力學(xué)、低溫工程專業(yè))    博士
1992—1995    西安交通大學(xué)能源與動(dòng)力工程學(xué)院 (工程熱物理專業(yè))    碩士
1988—1992    西安交通大學(xué)動(dòng)力機(jī)械工程系 (流體機(jī)械專業(yè))    學(xué)士

1998.07—1998.10 中國科學(xué)院低溫技術(shù)實(shí)驗(yàn)中心, 助理研究員
1998.10—2000.10 荷蘭艾因霍溫(Eindhoven)大學(xué)物理系低溫物理實(shí)驗(yàn)室, 博士后
2000.10—2002.10 中國科學(xué)院理化技術(shù)研究所，副研究員
2002.10—2005.10 美國哥倫比亞大學(xué)物理系Nevis實(shí)驗(yàn)室, Associate Scientist
2005.10—現(xiàn)在 上海交通大學(xué)機(jī)械與動(dòng)力工程學(xué)院，教授（博導(dǎo)）

1、液化天然氣技術(shù) (油田伴生氣、煤層氣)及其冷能綜合利用技術(shù)
2、低溫傳熱及低溫精餾技術(shù)
3、低溫粒子探測(cè)器研制 (暗物質(zhì)、中微子)
4、小型低溫制冷機(jī)技術(shù) (脈管制冷機(jī)、G-M制冷機(jī))

中國制冷學(xué)會(huì) 理事、第一專業(yè)委員會(huì)（低溫工程）委員（2007—至今）
上海市制冷學(xué)會(huì) 常務(wù)理事、第一專業(yè)委員會(huì)（低溫工程）主任（2007—2023）
上海市能源研究會(huì) 監(jiān)事長 （2019—至今）
上海穩(wěn)定同位素工程技術(shù)研究中心 技術(shù)委員（2017—至今）
安徽省稀有氣體分離技術(shù)重點(diǎn)實(shí)驗(yàn)室學(xué)術(shù)委員會(huì) 副主任（2023—至今）

國家能源LNG海上儲(chǔ)運(yùn)裝備重點(diǎn)實(shí)驗(yàn)室 技術(shù)委員（2024—至今）

教育部科技獎(jiǎng)勵(lì)評(píng)審專家 （2011—至今）
科技部國際科技合作計(jì)劃 評(píng)價(jià)專家（2007—至今）
國家自然科學(xué)基金 評(píng)審專家（2002—至今）
中國工程院院刊《Frontiers in Energy》期刊編委（2006—至今）、副主編（2011—至今）
《低溫與超導(dǎo)》，《真空與低溫》, 《低溫工程》編委。

1.   2024 - 2026 工業(yè)和信息化部 “海上液氫運(yùn)輸船關(guān)鍵技術(shù)預(yù)先研究” (工信部重裝[2024]57號(hào))，課題負(fù)責(zé)人

2.   2023 - 2025 工業(yè)和信息化部 “LNG蒸發(fā)氣處理及利用系統(tǒng)研制” (工信部重裝[2022]294號(hào))，課題負(fù)責(zé)人

3.   2022 - 2026 國家自然科學(xué)基金 面上項(xiàng)目“高佩克萊數(shù)條件下氣泡近界面流動(dòng)及傳質(zhì)機(jī)理研究”（52276158），參加

4.   2021 - 2025 國家自然科學(xué)基金 重大項(xiàng)目“基于PANDAX-4T液氙實(shí)驗(yàn)的暗物質(zhì)和中微子研究——暗物質(zhì)粒子實(shí)驗(yàn)研究”（12090061），參加

5.   2023 – 2027 國家重點(diǎn)研發(fā)計(jì)劃“基于PANDAX-4T 的物理和關(guān)鍵技術(shù)研究 課題：面向下一代液氙實(shí)驗(yàn)的極低本底控制技術(shù)研發(fā)”（2023YFA1606204），參加

6.   2018 - 2024 中國工程院“工程院院刊能源分刊發(fā)展戰(zhàn)略研究”，課題負(fù)責(zé)人  

7.   2018 - 2021 上海市科學(xué)技術(shù)委員會(huì) 重點(diǎn)基礎(chǔ)研究項(xiàng)目“4噸級(jí)超高純精餾塔系統(tǒng)設(shè)計(jì)及研制”（18JC1410200），參加

8.   2016 - 2020 國家重點(diǎn)科學(xué)研發(fā)計(jì)劃“基于惰性氣體探測(cè)器的直接暗物質(zhì)探測(cè)實(shí)驗(yàn)” (2016YFA0400300)，參加

9.   2013 - 2017 工業(yè)和信息化部 “新型液化天然氣船液貨圍護(hù)系統(tǒng)預(yù)先研究” (工信部聯(lián)裝[2012]534號(hào))，課題負(fù)責(zé)人

10.  2013 - 2016 航天先進(jìn)技術(shù)聯(lián)合研究中心 “低溫氣瓶的氣液兩相熱質(zhì)傳輸特性研究”，負(fù)責(zé)人

11.  2010 - 2014 科技部973計(jì)劃 “暗物質(zhì)暗能量的理論研究和實(shí)驗(yàn)預(yù)研” (2010CB833005)：暗物質(zhì)噸級(jí)液氙探測(cè)器的預(yù)研，子課題負(fù)責(zé)人

12.  2011 - 2013 國家自然科學(xué)基金“磁流體脈動(dòng)熱管啟動(dòng)與傳熱特性及其機(jī)理的研究” （51006069），負(fù)責(zé)人

13.  2007 - 2010 國防科工委工業(yè)民用專項(xiàng)“LNG船液艙圍護(hù)結(jié)構(gòu)系統(tǒng)研究”(科工技[2007]761號(hào)），負(fù)責(zé)人

14.  2006 - 2009 科技部863計(jì)劃“浮式海上油田伴生氣液化儲(chǔ)卸裝置FPSO研究開發(fā)” (2006AA09Z317)，負(fù)責(zé)人

15.  2006 - 2009 科技部863計(jì)劃“煤層氣液化流程及裝置的研究與開發(fā)”(2006AA06Z234)，參加

16.  2006 - 2008 上海市科委浦江人才計(jì)劃“低溫電子學(xué)用微型脈管制冷機(jī)關(guān)鍵技術(shù)研究及樣機(jī)研制” （06PJ14052），負(fù)責(zé)人

17.  2002 - 2004 國家自然科學(xué)基金“超導(dǎo)磁體冷卻用4K脈沖管制冷機(jī)系統(tǒng)研究”（50176052），負(fù)責(zé)人

2024

1.               Yin, L. Lin, Q. G. Ju, Y.L.* An integrated solution of energy storage and CO2 reduction: Trans-critical CO2 energy storage system combining carbon capture with LNG cold energy, Journal of Cleaner Production, 2024, 482:144228

2.               Yin, L. Yang, H.N. Ju, Y.L.* Review on the key technologies and future development of insulation structure for liquid hydrogen storage tanks, International Journal of Hydrogen Energy, 2024, 57:1302-1315

3.               Bi, Y. J. Ju, Y.L.* Dynamic simulation and analysis of a hydrogen liquefaction process with single-stage helium reverse Brayton cycle, International Journal of Hydrogen Energy, 2024, 93:403-415

4.               Bi, Y. J. Xu, Y. F. Ju, Y.L.* Experimental investigation and simulation on a small-scale open hydrogen liquefaction system with stepwise cooling, International Journal of Hydrogen Energy, 2024, 80:370-280

5.               Xu, Y. F. Bi, Y. J. Ju, Y.L.* The thermodynamic analysis on the catalytical ortho-para hydrogen conversion during the hydrogen liquefaction process, International Journal of Hydrogen Energy, 2024, 54:1329-1342

6.               Yan, X. et al. (PandaX-4T Collaboration), Searching for two-neutrino and neutrinoless double beta decay of Xe 134 with the PandaX-4T experiment, Physical Review Letters, 2024, 132(15): 152502

7.               Shang, X. et al. (PandaX-4T Collaboration), Search for cosmic-ray boosted sub-MeV dark matter-electron scatterings in PandaX-4T, Physical Review Letters, 2024, 133(10), 101805

8.               Luo, Y. et al. (PandaX-4T Collaboration), Signal response model in PandaX-4T, 2024, Physical Review D, 2024, 110(2): 023029

9.               Bo, Z. et al. (PandaX-4T Collaboration), First indication of Solar B neutrino flux through coherent elastic neutrino-nucleus scattering in PandaX-4T, Physical Review Letters, 2024, 133: 191001

2023

10.            Wu, S.X. Ju, Y.L.* Numerical study on pressure drops and thermal response of cryogenic fuel storage tanks under sinusoidal sloshing excitation, International Journal of Hydrogen Energy, 2023, 48: 36523-36540.

11.            Li, S. Ju, Y.L.* Wu, S.X. A new analytical model of condensation outside low-finned tubes for refrigerants at low temperatures and high heat flux, International Journal of Heat and Mass Transfer, 2023. 217:124667.

12.            Ning, X. et al. (PandaX-4T Collaboration), Limits on the luminance of dark matter from xenon recoil data, Nature, 2023, 618: 47-50.

13.            Ning, X. et al. (PandaX-4T Collaboration), Search for light dark matter from the atmosphere in PandaX-4T, Physical Review Letters, 2023, 131(4): 041001.

14.            Huang, D. et al. (PandaX-4T Collaboration), Search for dark-matter nucleon interactions with a dark mediator in PandaX-4T, Physical Review Letters, 2023, 131(19):191002.

15.            Li, S. (PandaX-4T Collaboration), Search for light dark matter with ionization signals in the PandaX-4T experiment, Physical Review Letters, 2023, 130(26): 261001.

16.            Ma, W. B. et al. (PandaX-4T Collaboration), Search for solar B8 neutrinos in the PandaX-4T experiment using neutrino-nucleus coherent scattering, Physical Review Letters, 2023, 130(2): 021802.

2022

17.            Bi, Y.J. Ju, Y.L.* Design and analysis of an efficient hydrogen liquefaction process based on helium reverse Brayton cycle integrating with steam methane reforming and liquefied natural gas cold energy utilization, Energy, 2022, 252:124047.

18.            Bi, Y.J. Yin, L. He, T. B. Ju, Y.L.* Optimization and analysis of a novel hydrogen liquefaction process for circulating hydrogen refrigeration, International Journal of Hydrogen Energy, 2022, 47(1): 348-364.

19.            Bi, Y.J. Ju, Y.L.* Conceptual design and optimization of a novel hydrogen liquefaction process based on helium expansion cycle integrating with mixed refrigerant pre-cooling, International Journal of Hydrogen Energy, 2022, 47(38): 16949-16963.

20.            Bi, Y.J. Ju, Y.L.* Review on cryogenic technologies for CO2 removal from natural gas, Frontiers in Energy, 2022, 16(5): 793-811.

21.            Li, S. Ju, Y.L.* Numerical study on the condensation characteristics of various refrigerants outside a horizontal plain tube at low temperatures, International Journal of Thermal Sciences, 2022, 176: 107508.

22.            Wang, C. Ju, Y.L.* Wang, T. Zhou, S. Transient performance study of high pressure fuel gas supply system for LNG fueled ships, Cryogenics, 2022, 125(6):103510.

23.            Yin, L. Qi, M. Ju, Y.L.* Moon, I.I. Advanced design and analysis of BOG treatment process in LNG fueled ship combined with cold energy utilization from LNG gasification, International Journal of Refrigeration, 2022, 135: 231-242.

24.            Yin, L. Ju, Y.L.* Review on the design and optimization of BOG re-liquefaction process in LNG ship, Energy, 2022, 244(4): 123065.

25.            He, T. B. Ju, Y. L. Lee, M. Y. et al. Green and sustainable LNG supply chain: A bridge to a low carbon energy society, 2022, Frontiers in Energy Research, 2022, 10: 975713.

26.            Huang, Z. et al. (PandaX-4T Collaboration), Constraints on the axial-vector and pseudo-scalar mediated WIMP-nucleus interactions from PandaX-4T experiment, Physics Letters B, 2022, 834(12), 137487.

27.            Huang, Z. et al. (PandaX-4T Collaboration), Neutron-induced nuclear recoil background in the PandaX-4T experiment, Chinese Physics C, 2022, 46:115001.

28.            Cui, X. et al. (PandaX-II Collaboration), Search for cosmic-ray boosted sub-GeV dark matter at the PandaX-II experiment, Physical Review Letters, 2022, 128 (17):171801.

29.            Yuan, Y. et. al. (PandaX-II Collaboration), A search for two-component Majorana dark matter in a simplified model using the full exposure data of PandaX-II experiment, Physics Letters B, 2022, 832(10) :137254.

30.            Qian, Z. et al. (PandaX-4T Collaboration), Low radioactive material screening and background control for the PandaX-4T experiment, Journal of High Energy Physics, 2022, 6: 147.

31.            Gu, L. et. al. (PandaX-4T Collaboration), First search for the absorption of Fermionic dark matter with the PandaX-4T experiment, Physical Review Letters, 2022, 129: 161803.

32.            Zhang, D. et al. (PandaX-4T Collaboration), Search for light Fermionic dark matter absorption on electrons in PandaX-4T, Physical Review Letters, 2022, 129(16): 161804.

33.            Abdukerim, et al. (PandaX-II Collaboration), Study of background from accidental coincidence signals in the PandaX-II experiment, Chinese Physics C, 2022, 46:03001.

34.            Si, L. et al. (PandaX-4T Collaboration), Determination of Double Beta Decay Half-Life of 136Xe with the PandaX-4T Natural Xenon Detector, Research, 2022, 2022: 9798721.

2021

35.            Bi, Y.J. Ju, Y.L.* Design and analysis of CO2 cryogenic separation process for the new LNG purification cold box, International Journal of Refrigeration, 2021, 130:1-9.

36.            Wu, S.X. Ju, Y.L.* Numerical study of the boil-off gas (BOG) generation characteristics in a type C independent liquefied natural gas (LNG) tank under sloshing excitation, Energy, 2021, 223: 120001.  

37.            Wang, C. Ju, Y.L.* Fu, Y. Z. Comparative life cycle cost analysis of low pressure fuel gas supply systems for LNG fueled ships, Energy, 2021, 218: 119541.

38.            Wang, C. Ju, Y.L.* Fu, Y. Z. Dynamic modeling and analysis of LNG fuel tank pressurization under marine conditions, Energy, 2021, 232: 121029.

39.            Wang. C. Ju, Y.L.* Modeling, simulation and analysis of tank thermodynamic behaviors during no-vent LNG bunkering operations, Cryogenics, 2021,?120(12): 103373.

40.            Wang, X.L. Ju, Y.L.* et. al. Performance of cryogenic demountable indium seal at high pressures, Review of Scientific Instruments, 2021, 92(9): 093905.

41.            Niu, W. C. Ju, Y.L.* Fu, Y. Z. Li, L. System design and experimental verification of an internal insulation panel system for large-scale cryogenic wind tunnel, Cryogenics, 2021,?115: 103279.

42.            Cui, X. Y. Wang, Z. Ju, Y.L.* et. al. Design and commissioning of the PandaX-4T cryogenic distillation system for krypton and radon removal, Journal of Instrumentation, 2021, 16(7) 07046.

43.            Yang, J.J. et al. (PandaX-II Collaboration), Constraining self-interacting dark matter with the full dataset of PandaX-II, Science China Physics, Mechanics & Astronomy, 2021, 64(11): 111062.

44.            Yan, B.B. et al. (PandaX-II Collaboration), Determination of responses of liquid xenon to low energy electron and nuclear recoils using a PandaX-II detector, Chinese Physics C. 2021, 45(7): 075001.

45.            Zhou, X.P. et al. (PandaX-II Collaboration), A search for solar axions and anomalous neutrino magnetic moment with the complete PandaX-II data, Chinese Physics Letter, 2021, 38(1): 011301.

46.            Cheng, C. et al. (PandaX-II Collaboration), Search for light dark matter–electron scattering in the PandaX-II experiment, Physical Review Letters, 2021, 126(21): 211803.

47.            Meng, Y. et al. (PandaX-4T Collaboration), Dark matter search results from the PandaX-4T commissioning run, Physical Review Letters, 2021, 127(26): 261802.

2020

48.            Yin, L. Ju, Y.L.* Process optimization and analysis of a novel hydrogen liquefaction cycle, International Journal of Refrigeration, 2020, 110: 219-230.

49.            Yin, L. Ju, Y.L.* Review on the design and optimization of hydrogen liquefaction processes, Frontiers in Energy, 2020, 14(3): 530-544.

50.            Wu, S.X. Ju, Y.L.* Lin, J.C. Fu, Y.Z. Numerical simulation and experiment verification of the static boil-off rate and temperature field for a new independent type B liquefied natural gas ship mock up tank, Applied Thermal Engineering, 2020, 173:115265.

51.            Wu, J. T. Ju, Y.L.* Comprehensive comparison of small-scale natural gas liquefaction processes, Frontiers in Energy, 2020, 14(4): 683-698

52.            Niu, W. C. Lin, J. C. Ju, Y.L.* Fu, Y. Z. The daily evaporation rate test and conversion method for a new independent type B LNG mock-up tank, Cryogenics, 2020, 111:103168

53.            Yin, L. Ju, Y.L.* Comparison and analysis of two processes for BOG Re-liquefaction in LNG carrier with normal-temperature compressor, International Journal of Refrigeration, 2020, 115:9-17

54.            Yin, L. Ju, Y.L.* Conceptual design and analysis of a novel process for BOG reliquefaction combined with absorption refrigeration cycle, Energy, 2020, 205: 118008. 

55.            Yin, L. Ju, Y.L.* Design and analysis of a process for directly re-liquefying BOG using subcooled LNG for LNG carrier, Energy, 2020, 199: 117445

56.            Cheng, H. Ju, Y.L.* Fu, Y. Z. Experimental study on heat transfer characteristics of cooling falling film outside a vertical tube in open rack vaporizer, Applied Thermal Engineering, 2020, 172:115187.

57.            Cheng, H. Yin, L. Ju, Y.L.* Fu, Y.Z. Experimental investigation on heat transfer characteristics of supercritical nitrogen in a heated vertical tube, International Journal of Thermal Sciences, 2020, 152: 106327.

58.            Cheng, H. Ju, Y.L.* Fu, Y.Z. Experimental and simulation investigation on heat transfer characteristics of supercritical nitrogen in a new rib tube of open rack vaporizer, International Journal of Refrigeration, 2020, 110: 219-230.

59.            Ma, W.B. et al. (PandaX-II Collaboration), Internal calibration of the PandaX-II detector with radon gaseous sources, Journal of Instrumentation, 2020, 15(12) 12038.

60.            Wang, Q.H. et al. (PandaX-II Collaboration), An improved evaluation of the neutron background in the PandaX-II experiment, Science China Physics, Mechanics & Astronomy, 2020, 63(3): 231011.

61.            Wang, Q.H. et al. (PandaX-II Collaboration), Results of dark matter search using the full PandaX-II exposure, Chinese Physics C, 2020, 44(12): 125001.

2019

62.            He, T. B. Chong, Z. R. Zheng, J. J. Ju, Y.L. Parvez, A. M. LNG cold energy utilization: Prospects and challenges, Energy, 2019, 170: 557-568

63.            He, T. B. Liu, Z. M. Ju, Y.L.* Parvez, A. M. A comprehensive optimization and comparison of modified single mixed refrigerant and parallel nitrogen expansion liquefaction process for small-scale mobile LNG plant, Energy, 2019, 167: 1-12

64.            Yin, L. Ju, Y.L.* Comparison and analysis of two nitrogen expansion cycles for BOG Re-liquefaction systems for small LNG ships, Energy, 2019, 172: 769-776

65.            Cheng, H. Ju, Y.L.* Fu, Y. Z. Thermal performance calculation with heat transfer correlations and numerical simulation analysis for typical LNG open rack vaporizer, Applied Thermal Engineering, 2019, 149(7): 1069-1079

66.            Wu, J. T. Ju, Y.L.* Design and optimization of natural gas liquefaction process using brazed plate heat exchangers based on the modified single mixed refrigerant process, Energy, 2019, 186:115819

67.            Ni, K. X. et al. (PandaX-II Collaboration), Searching for neutrino-less double decay of 136Xe with PandaX-Ⅱ liquid xenon detector, Chinese Physics C, 2019, 43(11):113001

68.            Xia, J. K. et al. (PandaX-II Collaboration), PandaX-II constraints on spin-dependent WIMP-nucleon effective interactions, Physics Letters B, 2019, 792: 193~198

69.            Zhang, H. Z. et al. (PandaX-II Collaboration), Dark matter direct search sensitivity of the PandaX-4T experiment, Science China Physics, Mechanics & Astronomy, 2019, 62(3) 031011

2018

70.            He, T. B. Karimia, I. A. Ju, Y.L.* Review on the design and optimization of natural gas liquefaction processes for onshore and offshore applications, Chemical Engineering Research and Design, 2018, 132: 89-114

71.            Wu, J. T. He, T. B. Ju, Y.L.* Experimental study on CO2 frosting and clogging in a brazed plate heat exchanger for natural gas liquefaction process, Cryogenics, 2018, 91:128-135

72.            Ren, X. X. et al. (PandaX-II Collaboration), Constraining Dark Matter Models with a Light Mediator at the PandaX-II Experiment, Physical Review Letters, 2018,121, 021304

2017

73.            Sha, L.L Ju, Y.L.* Zhang, H. and Wang, J.X. Experimental investigation on the convective heat transfer of Fe3O4/water nanofluids under constant magnetic field, Applied Thermal Engineering, 2017, 113(11): 566-574

74.            Sha, L.L Ju, Y.L.* Zhang, H. Wang, J.X. The influence of the magnetic field on the convective heat transfer characteristics of Fe3O4/water nanofluids, Applied Thermal Engineering, 2017, 126(7): 108-116.

75.            Xue, F. R. Chen, Y. Ju, Y.L.* Design and optimization of a novel cryogenic Rankine power generation system employing binary and ternary mixtures as working fluids based on the cold exergy utilization of liquefied natural gas (LNG), Energy, 2017, 138: 706-720.

76.            Niu, W.C. Li, G. L. Ju, Y.L.* Fu, Y. Z. Design and analysis of the thermal insulation system for a new independent type B LNG carrier, Ocean Engineering, 2017, 142:51-61.

77.            Chen, M. Ju, Y. L.* Experimental study of quasi-periodic on-off phenomena in a small-scale traveling wave thermoacoustic heat engine, Cryogenics, 2017, 85:23-29.

78.            Li, M.F. Ju, Y.L.* The analysis of the operating performance of a chiller system based on hierarchal cluster method, Energy and Buildings, 2017, 138: 695-703.

79.            Li, M.F. Ju, Y.L.* Experimental measurements and evaluation of the expanded water repellent perlite used for the cargo containment system of LNG carrier, Cryogenics, 2017, 87:49-57.

80.            Li, M.F. Ju, Y.L.* Experimental investigation on the thermal performance of wraparound loop heat pipe heat exchanger for heat recovery in air handling units, Heat Transfer Research, 2017, 48(14):1313–1326.

81.            Chen, X. et al. (PandaX-II Collaboration), Exploring the dark matter inelastic frontier with 79.6 days of PandaX-II data, Phys. Rev. D, 2017, 96, 102007.

82.            Fu, C. B. et al. (PandaX-II Collaboration), Limits on axion couplings from the first 80 days of data of the PandaX-II Experiment, Phys. Rev. Lett. 2017, 119(18), 181806.

83.            Fu, C. B. et al. (PandaX-II Collaboration), Spin-dependent weakly-interacting-massive-particle–nucleon cross section limits from first data of PandaX-II experiment, Phys. Rev. Lett. 2017, 118(07), 071301.

84.            Cui, X. Y. et al. (PandaX-II Collaboration), Dark matter results from 54-ton-day exposure of PandaX-II experiment, Phys. Rev. Lett. 2017, 119(18), 181302.

2016

85.            Xue, F.R. Chen, Y. Ju, Y.L.* A review of cryogenic power generation cycles with liquefied natural gas cold energy utilization, Frontiers in Energy, 2016,10 (3): 363-374

86.            He, T.B. Ju, Y.L.* Dynamic simulation of mixed refrigerant process for small-scale LNG plant in skid mount packages, Energy, 2016, 97: 350-358.

87.            Chen, M. Ju, Y. L.* Simulation and experimental improvement on a small-scale Stirling thermo-acoustic engine, Frontiers in Energy, 2016, 10(1): 37-45

88.            Tan A. D. et al. (PandaX-II Collaboration). Dark matter search results from the commissioning run of PandaX-II, Phys. Rev. D. 2016, 93: 122009

89.            Tan A. D. et al. (PandaX-II Collaboration). Dark matter results from first 98.7 days of data from the PandaX-II experiment, Physical Review Letters, 2016, 117, 121303.

2015

90.            He, T.B. Ju, Y.L.* Optimal synthesis of expansion liquefaction cycle for distributed-scale LNG plant, Energy, 2015, 88: 268-280.

91.            Chen, M. Ju, Y. L.* Effect of different working gases on the performance of a small thermoacoustic Stirling engine, International Journal of Refrigeration, 2015, 51: 41-51.

92.            Xiao, X. et al. (PandaX-II Collaboration). Low-mass dark matter search results from full exposure of the PandaX-I experiment, Physical Review D, 2015, 92(5), 052004.

2014

93.            He, T.B. Ju, Y.L.* Design and optimization of a novel mixed refrigerant cycle integrated with NGL recovery process for small-scale LNG plant, Industrial & Engineering Chemistry Research, 2014, 53 (13): 5545–5553.

94.            He, T.B. Ju, Y.L.* A novel conceptual design of parallel nitrogen expansion liquefaction process for small-scale LNG (liquefied natural gas) plant in skid-mount packages. Energy. 2014, 75: 349-359.

95.            He, T.B. Ju, Y.L.* Performance improvement of nitrogen expansion liquefaction process for small-scale LNG plant, Cryogenics, 2014, 61(5):111-119.

96.            He, T.B. Ju, Y.L.* A novel process for small-scale pipeline natural gas liquefaction, Applied Energy, 2014 (115): 17–24.

97.            Wang, Z. Bao, L. Hao, X. H. Ju, Y.L.* Design and construction of a cryogenic distillation device for removal of krypton for liquid xenon dark matter detectors, Review of Scientific Instruments, 2014, 85: 015116.

98.            Wang, Z. Bao, L. Hao, X. H. Ju, Y.L.* Large scale xenon purification using cryogenic distillation for dark matter detectors, Journal of Instrumentation, 2014, 9(11): 11024.

99.            Cao, X. G. et al. (PandaX-II Collaboration). PandaX: a liquid xenon dark matter experiment at CJPL, Science China: Physics, Mechanics & Astronomy, 2014, 57(8): 1476-1494.

100.         Xiao, M. J. et al. (PandaX-II Collaboration). First dark matter search results from the PandaX-I experiment, Science China Physics, Mechanics & Astronomy, 2014, 57(11): 2024-2030.

已公開專利：

1.      巨永林，楊浩楠，殷靚，液氫球罐的絕熱系統(tǒng)及液氫球罐，中國發(fā)明專利，專利號(hào)：CN202411914508.2，申請(qǐng)日：2024.12.24

2.      巨永林，楊浩楠，殷靚，液氫球罐的絕熱系統(tǒng)及液氫球罐，實(shí)用新型專利，專利號(hào)：CN202423210705.4，申請(qǐng)日：2024.12.24

3.      巨永林，殷靚，基于朗肯循環(huán)的液化天然氣船蒸發(fā)氣再液化系統(tǒng)及其方法，中國發(fā)明專利，專利號(hào)：CN202211605753.6，申請(qǐng)日：2022.12.14，公開號(hào)：CN115950205A，公開日：2023.04.11

4.      巨永林，殷靚，基于供氣系統(tǒng)的LNG蒸發(fā)器再液化一體化系統(tǒng)及其方法，中國發(fā)明專利，專利號(hào)：CN202211619167.7，申請(qǐng)日：2022.12.14，公開號(hào)：CN115930094A，公開日：2023.04.07

5.      巨永林，畢于敬，殷靚，基于雙回路循環(huán)氫氣制冷的氫氣液化系統(tǒng)及使用方法, 中國發(fā)明專利，專利號(hào)：CN202111279555.0，申請(qǐng)日：2021.10.28，公開號(hào)：CN114034159A，公開日：2022.02.17

6.      李海冰，巨永林，船用蒸發(fā)氣再液化系統(tǒng)，中國發(fā)明專利，申請(qǐng)?zhí)枺?/span>CN202022577162.5，申請(qǐng)日：2020.11.09，公開號(hào)：CN213599654U，公開日：2021.07.02

7.      耑銳，王承，巨永林，陳煜，趙棟梁，蔣贊，張亮，火箭氧箱冷氦增壓系統(tǒng)中增壓氣瓶環(huán)狀布置方式,中國發(fā)明專利，專利號(hào)：201710692730.6，申請(qǐng)日：2017.08.14，公開號(hào)：CN107587953A，公開日：2018.01.16

8.      王剛，張華，巨永林，基于LNG冷能的高純特種氣體節(jié)能型生產(chǎn)方法及系統(tǒng)，中國發(fā)明專利，專利號(hào)：CN201710963932.X, 申請(qǐng)日：2017.10.16，公開號(hào)：CN107576148A，公開日：2018.01.12

9.      陳煜，巨永林，一種船用液化天然氣冷能用于冷庫制冷的系統(tǒng)與方法，中國發(fā)明專利，專利號(hào)：201710456749.0, 申請(qǐng)日：2017.06.16，公開號(hào)：CN107345728A，公開日：2017.11.14

已授權(quán)專利：

10.   巨永林，殷靚，一種結(jié)合吸收式制冷的LNG船BOG再液化系統(tǒng)及其使用方法, 中國發(fā)明專利，專利號(hào)：CN202110594091.6，申請(qǐng)日：2021.05.28，授權(quán)號(hào)：CN113266999B，授權(quán)日：2025.1.28

11.   巨永林，鮑雨凝，王承，適用于小型船舶的低壓燃?xì)夤?yīng)系統(tǒng), 中國發(fā)明專利，專利號(hào)：CN201911180650.8，申請(qǐng)日：2019.11.27，授權(quán)號(hào)：CN110761920B，授權(quán)日：2024.06.21

12.   巨永林，謝世紀(jì)，顧婉加，李金超，一種大功率的斯特林制冷機(jī)裝置，中國發(fā)明授權(quán)，專利號(hào)：CN202311041980.5，申請(qǐng)日：2023.08.18，授權(quán)號(hào)：CN116804498B，授權(quán)日：2023.12.01

13.   巨永林，謝世紀(jì)，顧婉加，李金超，一種整體式自由活塞斯特林制冷機(jī)裝置，中國發(fā)明專利：專利號(hào)：CN202311041936.4，申請(qǐng)日：2023-08-18，授權(quán)號(hào)：CN116753636B，授權(quán)日：2023.11.07

14.   巨永林，謝世紀(jì)，顧婉加，李金超，一種用于自由活塞斯特林制冷機(jī)的排出器結(jié)構(gòu)，中國發(fā)明專利，專利號(hào)：CN202311042583.X，申請(qǐng)日：2023.08.18，授權(quán)號(hào)：CN116772445B，授權(quán)日：2023.11.03

15.   巨永林，畢于敬，殷靚，基于雙回路循環(huán)氫氣制冷的氫氣液化系統(tǒng)，實(shí)用新型專利，專利號(hào)：CN202122612086.1，申請(qǐng)日：2021.10.28，授權(quán)號(hào)：CN216204684U，授權(quán)日：2022.04.05

16.   巨永林，殷靚，一種結(jié)合吸收式制冷的LNG船BOG再液化系統(tǒng), 實(shí)用新型專利，專利號(hào)：CN202121174089.5，申請(qǐng)日：2021.06.28，授權(quán)號(hào)：CN215113524U，授權(quán)日：2021.12.10

17.   巨永林，鮑雨凝，王承，適用于小型船舶的低壓燃?xì)夤?yīng)系統(tǒng), 實(shí)用新型專利，專利號(hào)：ZL2019220844951，申請(qǐng)日：2019.11.27，授權(quán)號(hào)：CN211174386U，授權(quán)日：2020.08.04

18.   巨永林，成赫，傅允準(zhǔn)，適用于LNG開架式氣化器的換熱管，實(shí)用新型專利，專利號(hào)：ZL2019217298001，申請(qǐng)日：2019.10.12，授權(quán)號(hào)：CN 211012611U，授權(quán)日：2020.07.14

19.   王承，耑銳，巨永林，陳煜，程光平，何鵬，張亮，火箭氧箱冷氦增壓系統(tǒng)中增壓氣瓶布置方式，中國發(fā)明專利，專利號(hào)：201611178318.4，申請(qǐng)日：2016.12.19，授權(quán)號(hào)：CN106628265A，授權(quán)日：2019.08.05

20.   巨永林，薛菲爾，陳煜，利用LNG冷能的混合工質(zhì)梯級(jí)發(fā)電與剩余冷量輸出系統(tǒng)，中國發(fā)明專利，專利號(hào)：201710235556.2，申請(qǐng)日：2017.04.12，授權(quán)號(hào)：CN106939802B，授權(quán)日：2019.07.12

21.   王剛，張華，巨永林，基于LNG冷能的高純特種氣體節(jié)能型生產(chǎn)系統(tǒng)，實(shí)用新型專利，專利號(hào)：CN201721333022.5, 申請(qǐng)日：2017.10.16，授權(quán)號(hào)：CN207280081U，授權(quán)日：2018.04.27

22.   陳煜，巨永林，一種發(fā)電系統(tǒng)以及基于該系統(tǒng)的發(fā)電方法，中國發(fā)明專利，專利號(hào)： 201510279905.1，授權(quán)號(hào)：CN104989473B，授權(quán)日：2016.10.19

23.   張華，巨永林，一種液態(tài)有機(jī)燃料多用途節(jié)能燃燒系統(tǒng)，中國發(fā)明專利，專利號(hào)： 201510225519.4，授權(quán)號(hào)：CN104832230B，授權(quán)日：2016.08.24

24.   巨永林，傅允準(zhǔn)，李國隆，帶有防濺屏結(jié)構(gòu)的獨(dú)立B型LNG船液貨艙絕熱系統(tǒng), 中國發(fā)明專利，專利號(hào)：CN201610074852.4，授權(quán)號(hào)：CN105736903B，授權(quán)日：2018.05.01

25.   巨永林，傅允準(zhǔn)，李國隆，B型獨(dú)立LNG液貨艙絕熱層安裝固定機(jī)構(gòu)及固定方法，中國發(fā)明專利，專利號(hào)：201410579504.3，授權(quán)號(hào)：CN104443282B，授權(quán)日：2017.10.31

26.   巨永林，傅允準(zhǔn)，李國隆，液化天然氣船B型獨(dú)立液貨艙絕熱系統(tǒng)及其構(gòu)造方法，中國發(fā)明專利，專利號(hào)：201410577557.1，授權(quán)號(hào)：CN104443284B，授權(quán)日：2017.05.10

27.   周天赤，巨永林，傅允準(zhǔn)、劉家琛，一種浸沒燃燒式氣化器設(shè)計(jì)方法，中國發(fā)明專利，專利號(hào)： 201410540678.9，授權(quán)號(hào)：CN104318092B，授權(quán)日：2017.04.26

28.   周天赤，巨永林，傅允準(zhǔn)、劉家琛，一種開架式氣化器設(shè)計(jì)方法，中國發(fā)明專利，專利號(hào)： 201410540372.3，授權(quán)號(hào)：CN104315884B，授權(quán)日：2016.08.17

29.   周天赤，巨永林，傅允準(zhǔn)、劉家琛，一種帶有中間換熱介質(zhì)的氣化器設(shè)計(jì)方法，中國發(fā)明專利，專利號(hào)：201410540345.6，授權(quán)號(hào)：CN104406426B，授權(quán)日：2016.05.25

30.   西安倍更能源技術(shù)有限公司，巨永林，傅允準(zhǔn)，劉家琛，三種液化天然氣氣化器計(jì)算仿真軟件，軟件登記號(hào)：2014SR211994，授權(quán)日：2014.09.01.

31.   西安倍更能源技術(shù)有限公司，巨永林，傅允準(zhǔn)，劉家琛，LNG氣化器設(shè)計(jì)及仿真軟件，軟件登記號(hào)：2014SR047704，授權(quán)日：2014.04.23

32.   巨永林，傅允準(zhǔn)，劉家琛，LNG船液貨艙絕熱設(shè)計(jì)計(jì)算軟件，軟件登記號(hào)：2014SR145685，授權(quán)日：2014.09.28

33.   李海冰，巨永林，朱弘等，工業(yè)氣體回收設(shè)備及儲(chǔ)存系統(tǒng)，中國發(fā)明專利，專利號(hào)：CN201510410374.5，授權(quán)號(hào)：CN105157345A，授權(quán)日：2017.09.01

34.   巨永林，郝熙歡，祝鐵軍，李海冰，小型撬裝式液化天然氣蒸發(fā)氣再液化回收裝置，中國發(fā)明專利，專利號(hào)：201410020562.2，授權(quán)號(hào)：CN103759496B，授權(quán)日：2016.02.10

35.   巨永林，郝熙歡，祝鐵軍，小型撬裝式液化天然氣蒸發(fā)氣再液化回收裝置的安裝結(jié)構(gòu)，中國發(fā)明專利，專利號(hào)：201410020565.6，授權(quán)號(hào)：CN103759497B，授權(quán)日：2016.01.13  (已轉(zhuǎn)讓)

36.   巨永林，郝熙歡，祝鐵軍，小型撬裝式液化天然氣蒸發(fā)氣再液化回收無泵循環(huán)方法，中國發(fā)明專利，專利號(hào)：201410020588.7，授權(quán)號(hào)：CN103759498B，授權(quán)日：2016.02.10 (已轉(zhuǎn)讓)

37.   巨永林，賀天彪，小型撬裝式混合制冷劑天然氣液化和NGL回收一體系統(tǒng)，中國發(fā)明專利，專利號(hào)：201410083220.5，授權(quán)號(hào): CN103868324B，授權(quán)日：2015.10.14 (已轉(zhuǎn)讓)

38.   巨永林，賀天彪，利用膨脹機(jī)直接液化管道天然氣的裝置及方法，中國發(fā)明專利，專利號(hào)：201310159550.3，授權(quán)號(hào)：CN103292574A，授權(quán)日：2016.03.02 (已轉(zhuǎn)讓)

39.   巨永林，賀天彪，利用管道壓力能制備液化天然氣的裝置及使用方法，中國發(fā)明專利, 專利號(hào)：201310086863.0，授權(quán)號(hào)：CN103175379A，授權(quán)日：2015.10.14 (已轉(zhuǎn)讓)

40.   巨永林，賀天彪，小型撬裝式單階混合制冷劑天然氣液化系統(tǒng)及其方法，中國發(fā)明專利, 專利號(hào)：201310082270.7, 授權(quán)號(hào)：CN103363778A，授權(quán)日：2015.07.08 (已轉(zhuǎn)讓)

41.   巨永林，賀天彪，小型撬裝式氮膨脹天然氣液化系統(tǒng)及其方法，中國發(fā)明專利, 專利號(hào)： 201310082291.5, 授權(quán)號(hào)CN103215093A，授權(quán)日：2014.6.18 (已轉(zhuǎn)讓)

42.   巨永林，王剛，唐鑫，張華，礦井軟體救生艙用無外界電源空調(diào)制冷系統(tǒng)，中國發(fā)明專利, 專利號(hào)：201110292739.0，授權(quán)號(hào)：CN102330563B，授權(quán)日：2013.07.17(已轉(zhuǎn)讓)

43.   唐鑫，巨永林，王剛，李滿峰，一種適用于機(jī)房精密控制空調(diào)的節(jié)能裝置，中國發(fā)明專利, 專利號(hào)：201110273366.2，授權(quán)號(hào)：CN102425828B，授權(quán)日：2013.08.07 (已轉(zhuǎn)讓)

44.   李滿峰，巨永林，劉華萱，液氮溫區(qū)用雙試件防護(hù)熱板導(dǎo)熱系數(shù)測(cè)定儀，中國發(fā)明專利，專利號(hào)：201010245604.4，授權(quán)號(hào)：CN101915783B，授權(quán)日：2012.04.25 (已轉(zhuǎn)讓)

45.   巨永林，李滿峰，劉立東，邢培永，液化天然氣船用膨脹珍珠巖憎水系統(tǒng)，中國發(fā)明專利, 201110143623.0, 授權(quán)號(hào)：CN102226498B，授權(quán)日：2012.07.25

46.   李滿峰，巨永林，劉華萱，防護(hù)熱板裝置用線熱源式加熱器, 中國發(fā)明專利, 專利號(hào)： 201010255460.0，授權(quán)號(hào)：CN101938861B，授權(quán)日：2013.01.02

47.   巨永林，王剛，組合熱管換熱器，中國發(fā)明專利, 專利號(hào)：200910307503.2，授權(quán)號(hào)：CN101666589，授權(quán)日：2010.12.01 (已轉(zhuǎn)讓)

48.   劉軼倫，謝鑫，竺仁，顧妍，巨永林，雙自由度海洋浮動(dòng)平臺(tái)仿真裝置，中國發(fā)明專利, 專利號(hào)：200910052463.1，授權(quán)號(hào)：CN101576433，授權(quán)日：2011.05.04 (已轉(zhuǎn)讓)

49.   郝熙歡，巨永林，劉華萱，低溫制冷機(jī)回?zé)崞髡髟?/span>, 中國發(fā)明專利, 專利號(hào)： 201010284842.6，授權(quán)號(hào)：CN101936630B，授權(quán)日：2012.01.05 (已轉(zhuǎn)讓)

50.   李秋英，巨永林，含氧煤層氣的液化精餾方法，中國發(fā)明專利，專利號(hào)：201010274504.4，授權(quán)號(hào)：CN101922849A，授權(quán)日：2012.05.23  (已轉(zhuǎn)讓)

51.   謝鑫，劉軼倫，竺仁，顧妍，巨永林，雙自由度可調(diào)振幅平臺(tái)，中國發(fā)明專利, 專利號(hào)：200910050466.4，授權(quán)號(hào)：CN101544271，授權(quán)日：2011.04.20 (已轉(zhuǎn)讓)

52.   顧妍，巨永林，單自由度可調(diào)振幅平臺(tái)，中國發(fā)明專利,專利號(hào)：200810201923.8，公開號(hào)：CN101391648，授權(quán)日：2010.09.29  (已轉(zhuǎn)讓)

53.   巨永林，蘇偉，劉華萱，螺紋焊接整體狹縫式同軸脈管制冷機(jī)，中國發(fā)明專利, 專利號(hào)：200810039570.6，授權(quán)號(hào)：CN101298947，授權(quán)日：2010.06.09  (已轉(zhuǎn)讓)

54.   巨永林，蘇偉，劉華萱，用于同軸脈管制冷機(jī)的螺紋焊接整體狹縫式冷頭，中國發(fā)明專利, 專利號(hào)：200810039571.0，授權(quán)號(hào)：CN101298948，授權(quán)日：2010.01.27  (已轉(zhuǎn)讓)

55.   巨永林，楊康俊，顧妍，頻率及角度可調(diào)的海洋浮動(dòng)平臺(tái)仿真裝置，中國發(fā)明專利, 專利號(hào)：2007101707607，授權(quán)號(hào)：CN101201291，授權(quán)日：2009.11.18

56.   巨永林，王坤，雙冷頭狹縫冷指同軸脈管制冷機(jī)，中國發(fā)明專利, 專利號(hào)：200610026666.X, 授權(quán)號(hào)：CN1851355，授權(quán)日：2008.04.23

57.   張隆滿，巨永林，吳亦農(nóng)，一種用于同軸型脈管制冷機(jī)的整體式冷頭，中國發(fā)明專利, 專利號(hào)：200710041611.0，授權(quán)號(hào)：CN101067523，授權(quán)日：2008.10.08

58.   巨永林，黨海政，周遠(yuǎn)，無磁低振同軸脈沖管制冷機(jī)，中國發(fā)明專利, 專利號(hào)：02123951.7，授權(quán)號(hào)：CN1467461，授權(quán)日：2006.01.10

59.   巨永林，張利紅，侯宇葵, 梁驚濤，熱管式脈沖管制冷機(jī)冷量輸送裝置，中國發(fā)明專利，專利號(hào)：02123950.9，授權(quán)號(hào)：CN1467460，授權(quán)日：2005.10.19

60.   巨永林，袁鵾，靖葳，侯宇葵, 梁驚濤，用于冷卻高溫超導(dǎo)濾波器件的兩級(jí)同軸脈沖管制冷機(jī)，中國發(fā)明專利, 專利號(hào)：02125555.5，授權(quán)號(hào)：CN1470819，授權(quán)日：2005.6.15

61.   巨永林, 一種無回?zé)崞鞯姆聪鄽怏w循環(huán)低溫制冷機(jī), 中國發(fā)明專利，專利號(hào)：01109092.8，授權(quán)號(hào)：CN1373335，授權(quán)日：2004.03.03