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Matsunami Department of Electronic Science and Engineering, Kyoto University, Yoshidahonmachi, Sakyo, Kyoto 606-8501, Japan Keywords: fast epitaxy, morphology, photoluminescence, deep level transient spectroscopy Abstract.
Journal Title and Volume Number (to be inserted by the publisher) 3 In general, it is difficult to realize good morphology of epilayers grown at a high growth rate.
Financial support for this work was also provided in part by Japan Society for the Promotion of Science, Research for the Future Feasibility Study Program, "Control of Interface Properties in Wide Bandgap Semiconductors and Evolution of New Function".
Journal Title and Volume Number (to be inserted by the publisher) 5 References [1]R.
Conf. on Silicon Carbide and Related Materials 2000 (Kloster Banz, 2000), p. 5 [2]O.

Construction of User Response Subsystem for Energy Efficiency of Electric Power Supply and Demand System TANG Xinfa1,a,WU Lihong2, b, WAN Youwei3, c, CHENG Yueming1, d 1 Tourism School, Jiangxi Science & Technology Normal University, Nanchang, China 2 Jiangxi Vocational and technical College of information Application, Nanchang, China 3 School of Economics and Management, North China Electric Power University, Beijing, China a xinfatang@sina.com.cn, b 775230108@qq.com, c whyuv@163.com.cn, d 729209745@qq.com.cn Keywords: System development, Energy efficiency, Assets of energy efficiency, Customer response, Growth Ceiling Abstract.
Applied Mechanics and Materials, 2013, 291-294:1297-1302 [2] Liao Hua, Wei Yiming.
Journal of Public Management, 2010, 7(1): 28-34(in Chinese) [3] Tang Xinfa, Wan Youwei, Yan Qingyou.
Journal of Huazhong University of Science and Technology: Nature Science Edition, 2006,34(6): 55-57(in Chinese) [6] Li Li, Wang Jianjun, LI Ning, Tan Zhongfu, An Jianqiang.

Mathematical Formulation and Materials Markov chain is a branch of Markov process.
Acknowledgements Supported by the 100 Talents Program of the Chinese Academy of Sciences and the Key Laboratory of Mapping from Space of State Bureau of Surveying and Mapping.
Social Science & Medicine. vol.52(2001),p.1751 [5] Kang-Tsung Chang.Programming ArcObjects with VBA.
American Journal of Public Health.vol. 90 (2000),p.1562
[7] Zhihang Peng, Changjun Bao,etc.Journal of Biomedical Research.vol.24 (2010),p.208 [8] Winston L.W..Operations Research: Applications and Algorithms.

Acknowledgments The authors thank National Natural Science Foundation of China（No.61271159）and Applied Basic Research Foundation of Yunnan Province of China (No. 2011FB088) and the Research Foundation of Chuxiong Normal University of China(No.10zd03) for their financial supply.
References [1]P.B.Koeneman, I.J.Busch-Vishniac, K.L.Wood, Feasibility of Micro power supplies for MEMS, Journal of microelectromchanical systems, 6(1997)355– 362
[6]Y.Q.Li, H.Y.Yu, B.Su, Y.H Shang, Hybrid Micropower Source for Wireless Sensor Network, IEEE Sensors Journal, 8(2008) 678 – 681
[8] Z.Zha, J.Liu, X.Sun, photovoltaic generation and application of solar energy, Science Publishing Press,2005
[9]Y.T.He, Y.Q.Li, L.H.Liu, L.Wang, A High-efficiency Energy Storage Scheme of Solar Micro-power Systems , Advanced Materials Research, 60-61(2009) 74-78 [10] Information on http://www.wsn.net.cn/cn/productsd.php?

Ahmed1,c,Sverre Steen3,d, Fatemeh Behrouzi1,e,Reza Hassanzadeh1,f,Ahmad F.Sabki1,g 1Faculty of Mechanical Engineering, Universiti Teknologi Malaysia, 81310 UTM, Johor, Malaysia 2Marine Technology Centre (MTC), Universiti Teknologi Malaysia, 81310 UTM, Johor, Malaysia 3Rolls-Royce University Technology Centre ‘‘Performance in a seaway’’, Norwegian University of Science and Technology, N-7491 Trondheim, Norway anmehdi5@live.utm.my,b*adi@fkm.utm.my (corresponding author) ,cyasser@mail.fkm.utm.my, dsverre.steen@ntnu.no, ebfatemeh5@live.utm.my, frhm1425@gmail.com , gfuaad@fkm.utm.my Keywords: Flow Structure, Stern Hull, Finite Volume Method, Propeller, LNG Carrier Abstract.
Journal of Mechanical Engineering 45 (6), 222–228 June (2009)
Numerical analysis of hydrodynamic propeller performance of LNG carrier in open water, Jurnal Teknologi (Sciences and Engineering)  66  (2)  PP. 85 – 89, doi: 10.11113/jt.v66.2490 (2014) [21] M.
Numerical analysis of three dimensional flow around marine propellers in restricted water, IOP Conference Series: Materials Science and Engineering  50  (1), doi: 10.1088/1757-899X/50/1/012046 (2013) [22] M.
Three-dimensional numerical analysis of restricted water effects on the flow pattern around hull and propeller plane of LNG ship,  International Journal of Mechanics  7  (3)  PP. 234 – 241 (2013)

Yang: Mechanical Science and Technology for Aerospace Engineering, Vol. 27(2008), No. 8, pp.1056~1062.
Qu: Chinese Journal of Mechanical Engineering, Vol. 37(2001), No. 5, pp.26~29.
Mao: Journal of Mechanical Transmission, 28(2004), No. 6, pp.3~5.
Radestock: Electronic Notes in Theoretical Computer Science, (2005), No. 141, pp.49~67
Han: Key Engineering Materials, Vol. 579~580 (2014), pp.300~304.

Microstructure and electrochemical properties of La0.35Ce0.65Ni3.8-xCo0.8MnxAl0.4 hydrogen storage alloys Baozhong Liu1,a, Mengjuan Hu1,b, Yanping Fan1,c, Anming Li1,d School of Materials Science & Engineering, Henan Polytechnic University, Jiaozuo 454000, China abzliu@hpu.edu.cn, bhumengjuan05@126.com, c ypfan@hpu.edu.cn, d anmingli2001@sina.com Keywords: Hydrogen storage alloy; High-rate dischargeability; Phase structure; Electrochemical property; Ni/MH batteries Abstract.
Introduction AB5-type (Original LaNi5) hydrogen storage alloys are widely used as the negative electrode materials in commercial nickel/metal hydride (Ni-MH) batteries [1].
Especially when the alloys are used as negative electrode materials of high-power batteries, the high-rate dischargeability (HRD) is a critical criterion of evaluating properties of hydrogen storage alloys.
Thus, Mn has been considered as promising metal for negative electrode materials because it lowers the equilibrium pressure, and enhances the surface characteristic and the HRD of the alloys.
Wu: Journal of Rare earths Vol. 27 (2009), p. 853

It also abated that the bonding force among the active material.
What is more, the active materials are loss.
Suzuki, et al: Progress in batteries & battery materials, Vol. 16(1997), pp. 350-359
Zou, et al: Wuhan University Journal of Nautral Sciences, Vol. 5(2000), pp. 474-478
Science press, China(1987).

Properties of waste-based geopolymer building blocks Fenghui Huang a, Zonghui Zhou b, and Xin Cheng c Shandong Provincial Key Laboratory of Preparation and Measurement of Building Materials, Engineering Center of Advanced Building Materials of Ministry of Education, School of Materials Science and Engineering, University of Jinan, Jinan 250022, China ahuangfh1989@126.com, bmse_Zhouzh@ujn.edu.cn, cmse_ChengXin@ujn.edu.cn Keywords: industrial waste, geopolymer, building blocks, durability Abstract:The geopolymer building blocks were prepared with fly ash, steel slag, pulverized blast furnace slag, sand and activator by the pressure molding process.
Experimental Materials.
The chemical compositions of the major materials were shown in Table1.
Table 1 Chemical compositions of raw materials/wt/% Materials CaO MgO Fe2O3 Al2O3 SiO2 Loss Others Steel slag 38.91 7.61 23.11 1.57 13.32 1.20 14.28 Fly ash 5.21 1.63 6.45 24.81 57.40 4.27 0.23 PBFS 36.99 9.7 0.46 15.22 31.87 1.31 4.45 Sample preparation, testing and characterization.
Zhang: Construction and Building Materials.

In addition, material at the near-load end enters the nonlinear stage.
The eccentric load that the specimens sustain is basically the same with increasing load as the members go into the material and geometric nonlinearity stage.
[6] Linhai Han:Concrete filled steel tube structure(Science Press, China 2006) (in Chinese)
[8] Baochun Chen and Zhijin Ou: Journal of Building Structure. vol.27(2006),P.73(in Chinese) [9] KIL PATRICK A E and VIJA YA R B: ACI Structural Journal . vol .96 (1999),p.268 [10] Baochun Chen and Zhijin Ou.: China Journal of Civil Engineering. vol .40(2008), p.55 (in Chinese) [11] Lizhong Jiang, and Wangbao Zhou: Chinese Journal of Computational Mechanics. vol .27(2010),p.677(in Chinese) [12] Kawano A and Sakino K: Engineering Structures. vol .25(2003),p.607 [13] Galambos TV: Guide to stability design criteria for metal structures(John Wiley &Sons , Inc, New York 1998)
[15] Lin F J, Clauser E C and Johnston B G: Journal of the Structural Division, ASCE. vol .96( 1970) ,p.1377 [16] Baochun Chen and Zhijing Ou: China Journal Of Civil Engineering. vol .40(2007), p.32 [17] Yongqing Tu and Cong Li: Journal of Beijing University of Aeronautics and Astronautics. vol .31(2005),p.1092(in Chinese)