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Materials and Experimental Procedure Two kinds of A356-0.1%Ti alloy samples were produced, refined by Al-5Ti master alloys, named M-A356 alloys; refined by electrolytic low-titanium alloys, named E-A356 alloys, respectively.
Journal of Light Metals Vol.2 (2002), p.38 [2] W.S.
Bottema, et al, Materials Science and Engineering Vol.A280 (2000), p.37-49
Chakraborty, Internation Material Reviews, Vol.47 (2002), p. 3 [4] P.
Vol.12 (2002), p.1121 [6] Xie Jingpei, Li Jiwen, Liu Zhongxia, et al., Material Science Forum Vol.475-479(2004),p.317 [7] Liu Zhongxia, Wang Mingxing, Song Tianfu, Material Science Forum Vol.475-479(2004),p.321 [8] Augis J.

Introduction The tailings dam is a large volume of mineral resources exploitation accumulation of waste material from the production of the dam, tailings main component is silt, sand, damming material has low cohesion and other characteristics, and under earthquake sandy soil prone to shear deformation and liquefaction phenomenon, resulting in dam accident.
Damming materials under earthquake deformation can be regarded as non-linear.
In this paper, by equivalent linear method, depending on the damming material as equivalent viscoelastic, analysis on dynamic response and stability of different slope ratio of tailing dam when the peak ground acceleration 0.15g.
Using fast Fourier Transform (FFT) method to analysis on dam material spectral component seismic waves.
Acknowledgements This work was financially supported by Foundation of Yunnan Educational Committee (No. 2014J019 ) References [1] Qi Shengwen slope dynamic response analysis and applied research[D]Beijing, Institute of geology and geophysics, Chinese academy of sciences,2002 [2] Dong Longjun, Tailings dam seismic stability analysis of interval model and its application[J] Journal of central south university (natural science edition) 2011,164-169 [3] Zhou Yanyan,Fei Weishui,Liu Wenlian,Zhang Guohai,Gao Nan, Seismic action nobody ram the tailing dam stability analysis[J] Science, technology and engineering2010，2595-2600 [4] Li Ming,Xin Hongbo,Sun Limin, Newmark sliding block analysis method to evaluate the research progress of soil slope seismic stability[J] Industrial building, 2014，722-726

(d) Different material properties are considered as isotropic.
The buried copper pipe cast copper staves adopt fine copper as body filling compound and the material of copper tube.
Material parameters The material parameters related to the creep calculation mainly including: Elastic modulus, Poisson’s ratio, coefficient of linear expansion, detailed information was presented in table 2.
Acknowledgement This paper is supported by the National Natural Science Foundation Project (51064019), Inner Mongolia on Scientific Research Project (NJ10104) and Innovation fund of Inner Mongolia University of science & technology(2011NCL019).
Thermal stress and thermal distortion of cast iron cooling stave with surface-alloyed cooling water pipes[J], Journal of University of Science and Technology Beijing,2007, 29(9):942~947 [2] Shi lin, Chen susen, Ruan xinwei, Xu liangyou.

Materials and Methods Rice Husk Fiber Concrete Material.
Concrete boats are built of steel and fiber reinforced concrete instead of more traditional materials, such as steel, wood, aluminum, thermoplastic materials and FRP.
Finally, it has the best fire-resisting properties of all boat building materials, it is leak-proof and lightweight concrete; maintenance is greatly reduced; and boats made of fiber concrete can be easily repaired.
[5] Maxim Morency and Francois Paradis: Lightweight Shotcrete Canoe: Use of Viscosity Modifying Admixture and Acetone as Artificial Paste, Journal of Materials in Civil Engineering Vol. 18-3 (2006), p. 361-366
[8] Future With A Promise For Concrete Boat Building, Information on https://www.concreteconstruction.net/how-to/materials/future-with-a-promise-for-concrete-boat-building_o [9] Mbunwe Muncho Josephine: Design and Construction of a remote control switching device for household appliances application, Advances in Science, Technology and Engineering Systems Journal Vol. 2-4 (2017), p. 154-164.

A novel fluorescent sensor for Ag+ and Fe3+ based on aggregation-induced emission Jia-Hai Ye1,a, Zhenghua Wang1,b, Jian Liu1,c 1School of Chemical Engineering, Nanjing University of Science and Technology, Nanjing 210094, China ayejiahai@njust.edu.cn, bwzhnren@163.com, c2697228@qq.com Keywords: fluorescence probe, silver, iron, tetraphenylethylene, aggregation-induced emission Abstract: A novel fluorescence probe was obtained by click reaction based on the materials of etraphenylethylene (TPE) and 8-hydroxyquinoline, which were used as fluorescent group and accepter group respectively.
Thus, we selected tetraphenylethylene (TPE) and 8-hydroxyquinoline as materials to synthesize desired molecule through click reaction.
Materials and instruments Reagents were purchased as analytic grade.
Quinn, et al: Journal of medicinal chemistry Vol 47-25, (2004), p. 6349

Journal of Semiconductors, 2011, 32: 056002-4
Journal of Semiconductors, 2009, 30: 063002-5
Materials Science and Engineering. 2002, B95: 287-289
Journal of Semiconductors. 2009, 30: 052003-5
Journal of Semiconductors. 2011, 32: 043003-4.

Material Parameters.
The soil and pile material properties are shown in Table 3.
Acknowledgements The financial aid from National Science Foundation in Taiwan in contract No.
Journal of Geotechnical Engineering, Vol. 117 (1991), p. 448-466
Potyondy: Skin friction between various soils and construction materials, Geotechnique, Vol. 11 (1961), p. 339-353

Materials and experimental methods The chemical compositions of the investigated steels are listed in table 1.
Nesic: Corrosion Science, Vol. 49 (2007), p. 4308 [2] Guoxian Zhao, Xianghong Lu, Jianmin Xiang and Han Yong: Journal of Iron and Steel Research International, Vol.16 (4) (2009), p.8 [3] Jianbo Sun, Wei Liu, Wei Chang, Zhonghua Zhang, Zhongtao Li, Tian Yu, Minxu Lu: Acta Metallurgica Sinica, Vol.45(1)( 2009),p.84(in Chinese) [4] Z.
Wuhan: Wuhan University of Science and Technology, College of Material and Metallurgy, 2003
[6] J.Qiu, X.Ju, Y.Xin, S.Liu, Y.L.Wang, H.B.Wu, D.Tang: Journal of Nuclear Materials, 2010, Vol.407 (2010), p.189 [7] S.Morito, H.Yoshida, T.Maki and X.
Huang: Materials Science and Engineering A, Vol.428-440(2006), p.237 [8] Hiromoto Kitahara, Rintaro Ueji, Nobuhiro Tsuji and Yoritoshi Minamino: Acta Materialia, Vol.54 (2006), p. 1279 [9] Chunfang Wang, Maoqiu Wang, Jie Shi, Weijun Hui, Han Dong: Iron and Steel, Vol.42(11)(2007), p. 57(in Chinese) [10] Jianchun Cao, Qilong Yong, Qingyou Liu, Xinjun Sun: Transactions of Materials and Heat Treatment, Vol. 27(5) (2006), p. 51 (in Chinese)

Table 2 shows the performance comparisons among conventional aluminum alloys, aluminum-lithium alloys and composite materials.
These materials have special properties and usage.
(3) Select proper crucible materials.
[8] Guangjie Huang, Lingyun Wang: Development Application and Prospect of Aluminum-Lithium Alloys, Materials Review, 1997, 11, 21-24
[12] Grushko O.E: Lithium aluminium alloy ingot metallurgy, Journal Of Aeronautical Materials, 1994, 14, 45-53

Introduction Optimal blank can not only improve formability and product quality but also reduces material cost, number of trials in the try-out stage and product development time [1, 2].
Acknowledgments This research project is supported by the Scientific Research Foundation for Outstanding Young Scientists of Shandong Province (No.BS2009ZZ011), Science and Technology Program Foundation for Shandong Higher Education Institute (No.J09LD09) and partly supported by National Natural Science Foundation of China (No.60873080), Shandong Province Natural Science Foundation (No.
J. of Mechanical Sciences, Vol. 49 (2007), p. 1018-1028 [2] Z.Y.
Li: Journal of Jilin University (Engineering and Technology Edition), Vol. 34 (2004), p. 52-55 (in Chinese) [7] C.H.
Huh: Journal of Materials Processing Techonlogy, Vol. 82 (1998), p. 145-155