千葉大学 大学院工学研究科・工学部


luyun.jpg
魯 云
ロ  ウン
Yun Lu
教授
人工システム科学専攻
機械系コース
機械工学科
工11-221室、工11-201(実験室)、工16-209
043-290-3514
043-290-3039
luyun@
(@マーク以下にfaculty.chiba-u.jpと入力してください。)
http://apei.tu.chiba-u.jp/Luyun-HP.html
ハルビン工業大学材料系1981 工学学士,ハルビン工業大学大学院1984 工学修士,広島大学工学研究科1993 工学博士
重慶大学冶金系助手,千葉大学工学部助手,2002現職
日本機械学会,日本複合材料学会,日本材料学会,日本金属学会,日本熱電学会
新エネルギー材料,環境材料,材料創製,材料特性評価,粉末冶金工学,複合材料工学
環境改善と新エネルギー利用の観点から複合化、ナノ化、多孔質、薄膜等の手法を有効に活用して実験研究、理論解析、実用開発、計算機シミュレーションの”四輪”で熱電材料と環境浄化機能材料の創製およびその実用を目指して邁進する。
[1]熱電材料・素子の創製、特性評価およびその応用
[2]環境浄化機能材料の創製とその高機能化
[3]複合材料と金属間化合物の作製および力学・機能特性評価
(Since 2011)
[1] Effect of Ce addition on the microstructure, thermal conductivity and mechanical properties of Mg–0.5Mn alloys, Journal of Alloys and Compounds, 661(2016), 402–410.
[2] Influence of heat treatment process on photocatalytic activity of photocatalyst TiO2/TiCxOy coatings during heat treatment in carbon powder, J. Mater. Sci-Mater. Electron., 2016. DOI 10.1007/s10854-016-5126-9
[3] C, N co-doped TiO2/TiC0.7N0.3 composite coatings prepared from TiC0.7N0.3 powder using ball milling followed by oxidation, Appl. Surf. Sci., 2016. DOI 10.1016/j.apsusc.2016.06.026
[4] Fabrication of oxygen-deficient TiO2 coatings with nano-fiber morphology for visible-light photocatalysis, Materials Science in Semicondutor Processing, 41 (2016), 358-363.
[5] Influence of carbon atmosphere on surface morphology and photocatalytic activity of TiO2 coatings by multi-heat treatment, Journal of Materials Science Materials in Electronics; DOI: 10.1007/s10854-015-4236-0.
[6] Enhanced photocatalytic activity of photocatalyst coatings by heat treatment in carbon atmosphere, Materials Letters, 167(2016), 43–46.
[7] Surface topography evolution of TiO2/SnO2 coatings during thermal oxidation of Ti/Sn composite coatings, Surface and Coatings Technology, 291(2016), 325–333.
[8] Fabrication and electrochemical properties of porous VN hollow nanofibes, Journal of Alloys and Compounds, Vol.651, No.5(2015), 785-792. http://dx.doi.org/10.1016/j.jallcom.2015.06.111.
[9] Fabrication of Photocatalyst Composite Coatings of Cr-TiO2 by Mechanical Coating Technique and Oxidation Process, Coatings, Vol.5, No.3(2015), 545-556; doi:10.3390/coatings5030545.
[10] Review on the Photocatalyst Coatings of TiO2: Fabrication by Mechanical Coating Technique and Its Application, Coatings, Vol.5, No.3(2015), 425-464; doi:10.3390/coatings5030425.
[11] Formation Process of Ti Coatings in Mechanical Coating with Different Rotation Speed, Materials Science Forum, Vol. 833(2015), 161-164. DOI:10.4028/www.scientific.net/MSF.833.161
[12] Influence of Oxidation Temperature on Photocatalytic Activity of Cr-TiO2 Coatings by Mechanical Coating Technique Materials Science Forum, Vol. 833(2015), 177-180.DOI: 10.4028/www.scientific.net/MSF.833.177
[13] Effect of extrusion temperature on the microstructure and thermal conductivity of Mg–2.0Zn–1.0Mn–0.2Ce alloys,Materials & Design, Vol. 87, No.15 (2015), 914-919; DOI:10.1016/j.jallcom.2015.03.197
[14] 融塩処理によるナノ光触媒薄膜の作製と高機能化,日本金属学会誌 Vol. 79, No. 9(2015),429-433.
[15] Fabrication of thermoelectric CuAlO2 and performance enhancement by high density, Journal of Alloys and Compounds, Vol.650, No.25(2015), 558–563; doi:10.1016/j.jallcom.2015.08.013
[16] Review on the Photocatalyst Coatings of TiO2: Fabrication by Mechanical Coating Technique and Its Application, Coatings 2015, 5(3), 425-464; doi:10.3390/coatings5030425
[17] Fabrication of the photocatalyst thin films of nano-structured potassium titanate by molten salt treatment and its photocatalytic activity, Surface and Coatings Technology,Vol. 275(2015), 260–263(DOI: 10.1016/j.surfcoat.2015.05.009).
[18] Influence of oxidation process on photocatalytic activity of photocatalyst coatings by mechanical coating technique, Materials Science in Semiconductor Processing, Vol.30(2015), 128-134.
[19] Preparation and Photocatalytic Activity of TiO2–Copper Oxides Composite Coatings by Mechanical Coating Technique and Heat Oxidation,Applied Mechanics and Materials, Vols.719-720(2015), 13-16.
[20] Fabrication and Photocatalytic Activity of Photocatalyst Coatings by Mechanical Coating Technique and the Oxidation at Relatively Low Temperatures, Applied Mechanics and Materials, Vols.719-720(2015), 17-20.
[21] Simulated effect on the compressive and shear mechanical properties of biomimetic integrated honeycomb plates, Materials Science & Engineering C, Vol.50(2015), 286–293.
[22] Effect of Ce addition on thermal conductivity of Mg–2Zn–1Mn alloy, Journal of Alloys and Compounds, Vol.639,No.5(2015), 556-562.
[23] The microstructure of paper after heat-induced inkless eco-printing and its features, Journal of Wood Chemistry and Technology, Vol.34, No.3(2014), 202-210.
[24]Cu/TiO2-x複合熱電材料の特性解析−有限要素法および実験による高性能化の検討−, 材料の科学と工学,Vol.51. No.3(2014), 99-106.
[25] Titanium dioxide–nickel oxide composite coatings: Preparation by mechanical coating/thermal oxidation and photocatalytic activity,Materials Science in Semiconductor Processing, Vol.24(2014),138–145.
[26] Ti1-xCrxOzの作製およびその組織と熱電特性の解析,日本金属学会誌,Vol.78, No.3(2014),109-116.
[27] Technological Parameters and Disign of Bionic Integrated Honeycomb Plates, Journal of Bionic Engineering, Vol.11(2014), 134-143.
[28] Improvement in Thermoelectric Properties of Non-Stoichiometric Titanium Dioxide by Reduction Treatment, Materials Transactions, Vol.54 No.10 (2013) 1981-1985.
[29] Photocatalytic activity of TiO2/Ti composite coating fabricated by mechanical coating technique and subsequent heat oxidation, Materials Science in Semiconductor Processing, Vol.16, No.6(2013), 1949-1956.
[30] A study of the residual stress and its influence on tensile behaviors of fiber-reinforced SiC/Al composite, Advanced Composite Materials, Vol.22, No.4(2013), 255-263.
[31] 溶融塩処理による可視光応答型TiO2 光触媒の作製およびその機能評価,日本金属学会誌, Vol.77, No.7(2013), 287-293.
[32] Mechanism of Enhancing the Mechanical Properties of Basalt Fiber-Wood-Plastic Composites by the MAPE Addition, Materials, Vol.6, No.6(2013), 2483-2496.
[33] Fabrication and characteristics of visible light active TiO2 films by reduction treatment in carbon powder, Materials Technology, Vol.28, No.4(2013), 205-2134.
[34] Influence of metal properties on the formation and evolution of metal coatings during mechanical coating, Metallurgical and Materials Transactions A, Vol. 44, No.6(2013), 2717-2724.
[35] Effect of substrate temperature on optical properties and strain distribution of ZnTe epilayer on (100) GaAs substrates, Thin Solid Films, Vol.536(2013), 240-243.
[36] Effect of Cu powder addition on thermoelectric properties of Cu/TiO2-x composite, Ceramics International,Vol.39(2013),6689-6694.
[37] Analysis on energy transfer during mechanical coating and ball milling—supported by electric power measurement in planetary ball mill, International Journal of Mineral Processing, Vol.121 (2013), 51-58.
[38] Improvement of Thermoelectric Properties of CuAlO2 by Excess Oxygen Doping in Annealing, Materials Science Forum, Vol.750(2013), 134-137.
[39] FEM Analysis on Thermoelectric Properties of Metal/TiO2 Composites with Random Metal Powder Distribution, Materials Science Forum, Vol.750(2013),130-133.
[40] Influence of intermittent air introduction on the formation of Zn films by mechanical coating technique, Materials Science Forum, Vol.750(2013),138-141.
[41] Antibacterial activity of TiO2/Ti composite photocatalyst films treated by ultrasonic cleaning, Advanced in Materials Physics and Chemistry, Vol.2, No.4B(2012), 9-12.
[42] Fabrication of Sn coatings on alumina balls by mechanical coating technique and relevant process analysis, Advanced in Materials Physics and Chemistry,Vol.2, No.4B(2012), 126-129.
[43] 有限要素法を用いた複合熱電材料の特性解析, 日本金属学会誌, Vol.76,No.8(2012),508-514.
[44] Improvement and Function Characteristics of SiCCVD/Al Composite Electric Heating Actuators, Advanced Materials Research Vol. 567(2012), 224-227.
[45] Fabrication of Ni coatings by mechanical coating technique, Journal of Engineering and Technology, Vol.1, No.1(2012), 131-134.
[46] Fabrication of zinc coatings on alumina balls from zinc powder by mechanical coating technique and the process analysis, Powder Technology, 228(2012) , 377-384.
[47]Fabrication of Non-stoichiometric Titanium Dioxide by Spark Plasma Sintering and Its Thermoelectric Properties, Materials Transactions, Vol.53, No.7(2012), 1208-1211.
[48] The influence of the processing parameters on the formation of iron thin films on alumina balls by mechanical coating technique,Journal of Materials Processing Technology, 212(2012), 1169-1176.
[49] Reaction behaviour of Ni1−x M x O’s (M = Li, Na)formation and its thermoelectric properties, Journal of Materials Science: Materials in Electronics, Vol. 23,No. 1 (2012), 315-319.
[50] Fabrication and Thermoelectric Properties of Magneli Phases by Adding Ti into TiO2, Advanced Materials Research, Vols.415-417(2012), 1291-1296.
[51] Photocatalyst thin film by 2-step Mechanical Coating Technique and its photocatalytic activity, Advanced Materials Research, Vols.415-417(2012), 1942-1948.
[52] Study of Strength and Its Reliability of SiC Fiber Bundle By Experimental and Monte-Carlo Simulation Approach, Materials Science and Engineering A, 528(2011), 4080-4085.
[53] Formation of TiO2/Ti composite photocatalyst film by 2-step mechanical coating technique, Materials Science Forum, Vol.675-677(2011), 1229-1232.
[54] Performance improvement of TiO2/Ti composite photocatalyst film by heat oxidation treatment, Materials Science Forum, Vol.675-677(2011), 1233-1236.
[55] Behavior of electrical resistance of SiCCVD fiber and development of micro-heater with SiCCVD fiber, Journal of Materials Science, Vol.46, No.7 (2011), 2085-2090.
[56] Development of basalt fiber reinforced wood-plastic composite materials, Journal of Advanced Materials Research, Vols. 189-193(2011), 4043-4048.
[57] CuAlO2熱電材料の作製における固相反応挙動とその高性能化,材料の科学と工学,Vol.48(2011), No.6, 302-307.
[58] Effect of Temperature Difference on the Power Output of CaMnO3 and Ca3Co4O9 Thermoelectric Generators,Journal Of Xihua University -Natural Science Edition, Vol.30, NO.2 (2011), 78-81.
[59] 純銅板のARB法による高強度化,銅と銅合金技術研究会誌,Vol.50(2011), No.1(2011), 259-263.
[60] Influence of stacking fault energy on formation of long period stacking ordered structures in Mg-Zn-Y-Zr alloys, Progress in Natural Science: Materials International , Vol.21, No. 6(2011), 485-490.

出願特許:
[1] 光触媒の製造方法及びこれにより製造される光触媒,特願2015-039720
[2] 熱電変換材料及びその製造方法,特願2014-038954号
[3] 熱電変換材料及びその製造方法,特願2011-064076号
[4] 光触媒及びその製造方法, 特願2011-032676号
[5] 複合光触媒の製造方法及びそれにより製造される複合光触媒,特許第5354569号
[6] 金属酸化物半導体の製造方法, 特許第4106434号
[7] アクチュエータ, 特許第3824836号
[8] Ni-Al系金属間化合物の製造方法, 特許第3839632号
[1]先進複合材料,機械工業出版社,2003(主著)
[2]新材料概論,冶金工業出版社,2004(分担執筆)
[3]Chapter 13 Mechanical Coating Technique for Composite Films and Composite Photocatalyst Films 
by Yun Lu, Liang Hao and Hiroyuki Yoshida(分担執筆)
in Composites and Their Applications, Edited by Ning Hu, ISBN 978-953-51-0706-4,InTech, Published,2012
[4]金属学III(合金熱力学と相変態基礎),重慶大学出版社,1986
[5]金属学Ⅰ(材料科学基礎),重慶大学出版社,1986
学部:
「鉄鋼材料」(前期、3セメ、機械工学科)
「工業技術概論」(前期、工学部(留学生)共通)
「機械工学セミナー」(1セメ、機械工学科、分担)
「デザイン工学」(6セメ、機械工学科、分担)
大学院:
「新エネルギー材料」(前期、機械系コース)
「環境・新エネルギー材料」(博士課程)(後期、機械系コース)
H20LY-3.pdf(pdf)