教育經歷
1998.10 - 2000.09, 日本筑波大學工學系博士後研究
1994.04 - 1997.04, 華南理工大學化工學院, 化學工程博士1990.09 - 1993.06, 西安交通大學, 工程熱物理碩士
1986.09 - 1990.07, 西安交通大學, 動力與能源機械工程學士
工作經歷
2005.01 – , 中山大學化學與化學工程學院,教授
2004.01 - 2004.04, 日本九州大學先導物質化學研究所, 訪問教授
2002.07 - 2004.12, 中山大學化學與化學工程學院,副教授
2001.06 - 2002.04, 日本九州大學機能物質科學研究所, 助教授
1998.10 - 2000.09, 日本通產省工業技術院機械技術研究所, 客座研究員
1993.06 - 2001.05, 華南理工大學化工所, 助教、講師、副教授
主要研究方向
1、 熱系統設計與控制,傳熱與流體流動的數值模擬
2、 磁對流、超導磁場作用下的流體流動與傳熱
3、 防凍蛋白、冰晶與中藥提取低溫濃縮技術
4、 納米能源材料與微傳熱技術
講授的主要課程:
《計算流體力學與傳熱學》,《新能源材料與技術》,《化工基礎》,《化工原理》
教學/科研獲獎,專利:
[1] 呂樹申,符遠翔,王曉明,莫冬傳,一種石墨烯片的製備方法,發明專利,專利號:ZL201210459726.2。
[2] 王海燕,呂樹申,倫照榮,具有DSC及微結構觀察功能的真空冷凍乾燥裝置,發明專利,專利號:ZL201010144170.9。
[3] 呂樹申,莫冬傳,一種環路熱管散熱器,發明專利,專利號:ZL200910040109.7。
[4] 呂樹申,王海燕,一種兼容可視化功能的差示掃描量熱儀,發明專利,專利號:ZL200910037287.4。
[5] 呂樹申,莫冬傳,一種高效平板式迴路熱管裝置,發明專利,專利號:ZL200510035406.4。
[6]Europe (registered), Patent No. 1055719 (2004/05/12)
[7]Australia (registered), Patent No. 764175 (2003/11/27)
[8]USA (registered), Patent No. 6430957 (2002/08/13)
[9]Japan (registered) (in Japanese), Patent No. 3111219 (2000/09/22)
[10]Canada (not registered yet), Application No. 2,303,496 (2000/03/30)
[11]、 T. Inada, A. Yabe, S. Grandum, S.S. Lu,Method and apparatus for thermal transportation using poly(vinyl alcohol),
[12]、 呂樹申, 一種中藥提取液的低溫濃縮方法及其裝置, 發明專利, 申請號:0311710.5。
科研項目
[1] 低維材料電子/聲子熱輸運特性的量子分析,國家自然科學基金項目(51276202),2013.1-2016.12。
[2] 大功率LED關鍵熱物理問題的基礎研究,國家自然科學基金-廣東聯合基金合作單位課題(U1034004),2011.1-2014.12。
[3] 納米管陣列修飾表面的沸騰傳熱機理,國家自然科學基金項目(50976126),2010.1-2012.12。
[4] 基於迴路熱管散熱技術的大功率白光LED照明光源模組的研究和產業化,廣東省科技計畫重大專項(2009A080301012),2009.5-2011.4。
[5] 基於生物自然抗凍機理的低溫保存關鍵技術研究(2005CCA01400),2006.1- 2007.12。
主要論著
[1] Zhi-Yong Luo, Kai-Xuan Chen, Ya-Qiao Wang, Jun-Hui Wang, Dong-Chuan Mo* and Shu-Shen Lyu*, Hierarchical nanoparticles-induced superhydrophilic and under-water superoleophobic Cu foam with ultrahigh water permeability for effective oil/water separation, J MATER CHEM A, 2016, Manuscript ID: TA-ART-05-2016-004487.R1.
[2] Zhi-Yong Luo, Kai-Xuan Chen, Ya-Qiao Wang, Jun-Hui Wang, Dong-Chuan Mo* and Shu-Shen Lyu*, Superhydrophilic Nickel Nanoparticles with Core-Shell Structure to Decorate Copper Mesh for Efficient Oil/Water Separation, J PHYS CHEM C, 2016, 120 (23): 12685-12692.
[3] Kai-Xuan Chen, Zhi-Yong Luo, Dong-Chuan Mo* and Shu-Shen Lyu*, WSe Nanoribbons: New High-performance Thermoelectric Materials, PHYS CHEM CHEM PHYS, 2016, 18: 16337-16344.
[4] Zhi-Yong Luo, Kai-Xuan Chen,Dong-Chuan Mo* and Shu-Shen Lyu*, A New Route for Surface Modification: Fluorine-Induced Superhydrophilicity, J PHYS CHEM C, 2016, 120 (22): 11882-11888.
[5] Yue Chen, Yuanxiang Fu, Jin Huang, Zhiyong Luo, Dongchuan Mo, Shushen Lyu, Droplet bouncing on hierarchical branched nanotube arrays above and below the freezing temperature, APPL SURF SCI, 2016, 375: 127-135.
[6] Chen, Kai-Xuan; Wang, Xiao-Ming; Mo, Dong-Chuan*; Lyu, Shu-Shen*, Thermoelectric Properties of Transition Metal Dichalcogenides: From Monolayers to Nanotubes, J PHYS CHEM C, 2015, 119: 26706−26711.
[7] M. Aguilar et al. (AMS Collaboration), Precision Measurement of the Proton Flux in Primary Cosmic Rays from Rigidity 1 GV to 1.8 TV with the Alpha Magnetic Spectrometer on the International Space Station, PHYS REV LETT, 2015, 114: 171103.
[8] Xiao-Ming Wang, Shu-Shen Lu*, First-principles Study of the Transport Properties of Graphene-hexagonal Boron Nitride Superlattice, J NANOSCI NANOTECHNO, 2015, 15(4): 3025-3028.
[9] Chen, K.-X., Wang, X.-M., Mo, D.-C. *, Lyu, S.-S. *, Substrate effect on thermal transport properties of graphene on SiC(0001) surface, CHEM PHYS LETT, 2015, 618: 231-235.
[10] M. Aguilar et al. (AMS Collaboration), Electron and Positron Fluxes in Primary Cosmic Rays Measured with the Alpha Magnetic Spectrometer on the International Space Station, PHYS REV LETT, 2014, 113: 121102.
[11] L. Accardo et al. (AMS Collaboration), High Statistics Measurement of the Positron Fraction in Primary Cosmic Rays of 0.5–500 GeV with the Alpha Magnetic Spectrometer on the International Space Station, PHYS REV LETT, 2014, 113:121101.
[12] Hai-Yan Wang, Yan-Zi Wen, Zhao-Rong Lun, Shu-Shen Lu*, Visual Observation of African Trypanosome during Cryopreservation, BIOPRESERV BIOBANK, 2014,12(4): 265-268.
[13] Yuan-Xiang Fu, Zhuo-Xian He, Dong-Chuan Mo*, Shu-Shen Lu*, Thermal conductivity enhancement of epoxy adhesive by filling graphene sheets, INT J THERM SCI, 2014, 86:276-283.
[14] Zhi-Yong Luo, Dong-Chuan Mo* and Shu-Shen Lu*, The key factor for fabricating through-hole TiO2 nanotube arrays: A fluoride-rich layer between Ti substrate and nanotubes, J MATER SCI, 2014, 49(19): 6742-6749.
[15] G.Alberti et al. (AMS TTCS Collaboration), Active CO Two-Phase Loops for the-AMS-O2 Trecker, IEEE A&E SYSTEMS MAGAZINE. 2014: page 1-13.
[16] Yuan-Xiang Fu, Zhuo-Xian He, Dong-Chuan Mo, Shu-Shen Lu*, Thermal conductivity enhancement with different fillers for epoxy resin adhesives, APPL THERM ENG, 2014, 66:493-498.
[17] Dong-chuan Mo, Guan-sheng Zou, Ya-Qiao Wang and Shu-shen Lu*, Flat Loop Heat Pipe with Bi-transport Loops for Graphics Card Cooling, Heat Transfer Engineering, 2014, 35(11-12): 1071-1076.
[18] Yuan-Xiang Fu, Xiao-Ming Wang, Dong-Chuan Mo, Shu-Shen Lu*, Production of monolayer, trilayer and multi-layer graphene sheets by a re-expansion and exfoliation method, J MATER SCI, 2014, 49: 2315-2323.
[19] Xiaoming Wang and Shushen Lu*, Thermoelectric Transport in Graphyne Nanotubes, J PHYS CHEM C, 2013, 117(38): 19740-19745.
[20] Hai-Yan Wang, Shu-Shen Lu*, Study on thermal properties of phase change material by an optical DSC system, APPL THERM ENG, 2013, 60: 132-136.
[21] Xiaoming Wang, Tianlan Huang and Shushen Lu*, High Performance of the Thermal Transport in Graphene Supported on Hexagonal Boron Nitride, APPL PHYS EXPRESS, 2013, 6, 075202.
[22] Xiao-ming Wang, Dong-chuan Mo, and Shu-shen Lu*, On the thermoelectric transport properties of graphyne by the first-principles method, J CHEM PHYS, 2013, 138: 204704.
[23] M. Aguilar et al. (AMS Collaboration), First Result from the Alpha Magnetic Spectrometer on the International Space Station: Precision Measurement of the Positron Fraction in Primary Cosmic Rays of 0.5–350 GeV, Selected for a Viewpoint in Physics, PHYS REV LETT, 2013, 110: 141102.
[24] Shu-Shen Lu, Hiroyuki Ozoe, Effects of thermal boundary conditions on magnetically controlled air flow in a pipe, Progress in Computational Fluid Dynamics, Special Issue of Heat Transfer Processes, 2004, (accepted: 2004-01-21).
[25] Takaaki Inada, Shu-Shen Lu, Thermal hysteresis caused by non-equilibrium antifreeze activity of poly(vinyl alcohol), Chemical Physics Letters, 2004, Vol.394, pp.361-365.
[26] Gangfeng Ouyang, Yangyi Yang, Shu-Shen Lu, Zhongqi Huang, Beisheng Kang, Eaxcess Molar Volumes and Surface Tensions of Xylene with Acetone or 2-Butanone at 298.15 K, J. Chem. Eng. Data, March 2004, Vol.49, No.2, 330-332.
[27] M.Kaneda, R.Noda, T.Tagawa, H.Ozoe, S.S.
Lu and B.Hua, "Effect of inclination on the convection of air in a cubic enclosure under both magnetic and gravitational fields with flow visualization," Journal of Chemical Engineer of Japan, 2004, Vol.37, No.2, pp.338-346.
[28] Shu-Shen Lu, Chang-Ho Lee, Toshio Tagawa, Hiroyuki Ozoe And Ben Hua, Magnetically controlled air flow and heat transfer in a pipe with uniform wall heat flux on its latter half length, Numerical Heat Transfer A, 2004, Vol.45, No.4, 377-390.
[29]呂樹申、楊茉、華賁,磁熱場協同作用下的傳熱傳質強化,《工程熱物理學報》,2004年5月第25卷第3期,460-462
[30] Shu-Shen Lu, Chang Ho Lee, Toshio Tagawa, Hiroyuki Ozoe, Ben Hua, Enhancement of heat transfer and air flow rates in a pipe with application of a magnetic field, Journal of Enhanced Heat Transfer, 2003, Vol.10, No.1, pp.45-60.
[31] T. Inada, S.S. Lu, Inhibition of recrystallization of ice grains by adsorption of poly vinyl alcohol onto ice surfaces, Crystal Growth & Design, 2003, Vol.3, No.5, pp.747-752.
[32] Chang Ho LEE, Shu-Shen Lu, Toshio TAGAWA, Hiroyuki OZOE and Jae Min HYUN, Numerical Analysis of Magnetic Effect on Human Breathing, JSME International Journal, 2003 June, Vol.46, No.2, pp.572-582.
[33] S.S. Lu, T. Inada, A. Yabe, X. Zhang and S. Grandum, Microscale study of poly(vinyl alcohol) as an effective additive for inhibiting recrystallization in ice slurries, Int. J. of Refrigeration, 2002,Vol.25, pp.562-568.
[34] 呂樹申、張正國、高學農, 碎冰式冷量輸送系統參數的最佳化設計原理, 《暖通空調Journal of HV &AC》, 2002, Vol.32, No.4, pp.29-31
[35] X. Zhang, T. Inada, A. Yabe, S.S. Lu and Y. Kozawa, Active control of phase change from supercooled water to ice by ultrasonic vibration 2. Generation of ice slurries and effect of bubble nuclei, International J. of Heat/Mass Transfer, Dec. 2001, Vol.44, No.23, pp. 4533-4539.