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In this paper, the effects of dielectric materials with finite dimension on resonant frequency and impedance characteristics of embedded small NMHA were investigated.
It provides an effective guidance for designers to tune the antenna to desirable complex impedance when surroundded dielectric materials are employed.
The frequency and impedance characteristics of NMHA in a dielectric are complex functions of its physical parameters including those electrical properties of surrounding materials.
The materials under consideration are linear, homogeneous and isotropic.
Hubing: ACES Journal Vol. 25 (2010), p. 32

Univ. 30, 28911 Leganés, Spain 2Dpt. of Materials Science and Eng.
Iron based powder metallurgy (PM), were developed in the previous years to the II World War, being the absence of raw materials the pushing effect, and it was the origin of a new materials family (PM Steels) that today can be considered a high performance materials.
, [] Kaysser, WA; Zivkovic, M; Petzow, G, Journal of Materials Science 20 (1985) 578-584
PM2TEC’99, Advances in Powder Metallurgy and Particulate Materials.
In this way, the most recent studies are focused in new effective methods to introduce the Mn in the alloying system [[] Sicre-Artalejo, J., Campos, M., Marcu, T., Torralba, J.M., Materials Science Forum, 534-536, (2007) 697-700. ].

The TBC and bond coat were modeled as elastic-viscoplastic materials.
Takeuchi: Materials Science and Engineering A 189 (1994), p. 301
Taylor: Materials Science and Engineering A299 (2001), p. 296
Kokini: Mechanics of Time-Dependent Materials Vol. 6 (2002), p. 171
Taylor: Materials Science and Engineering A Vol. 323 (2002), p. 70

[3] WANG X.R, ZHANG X. and CAO L.W: submitted to Journal of Jiamusi University (Natural Science Edition) (2007)
[4] ZHANG G.L, LIU Y. and WANG Y.C: submitted to Journal of Materials Science & Technology. (2017)
[8] Savchenko D.V., Serdan A.A. and Morozov V.A.: submitted to Xinxing Tan Cailiao/New Carbon Materials(2012)
[11] JIANG Q J, JIANG C and SHANG J: submitted to Science and Technology Innovation Herald. (2015) [12] LIU C, CHEN Z and CHEN H.: submitted to Journal Wuhan University of Technology, Materials Science Edition( 2011)
[13] WANG Y, YANG Q and CHEN J T: submitted to Materials Research.(2016).

Tamayol, Experimental study of convective heat transfer of a nanofluid through a pipe filled with metal foam, International Journal of Thermal Sciences 88 (2015) 33-39
Kang, Review on combined heat and mass transfer characteristics in nanofluids, International Journal of Thermal Sciences 87 (2015) 49-67
Torsæter, A coreflood investigation of nanofluid enhanced oil recovery, Journal of Petroleum Science and Engineering 111 (2013) 128-138
Miguel, Fluid flow through macro-porous materials: friction coefficient and wind tunnel similitude criteria, International Journal of Fluid Mechanics Research 39 (2012) 136-148
Aydin, Aerosol particle deposition and distribution in a bifurcating ventilation duct, Journal of Hazardous Materials 116 (2004) 249-255

Research on Metallic Silicon Used As Lithium Ion Battery Anode Material Rui Zhang1,a, An Li2,b , Lei Zhang3,c and Xunyong Jiang4,d 1,2,3,4 Department of Materials Science and Engineering, Tianjin University of Technology, Tianjin, China,300384 azr062312548@163.com, b814902189@qq.com, czhanglei0315@yeah.net, d jiangxunyong@tjut.edu.cn, to whom correspondence should be addressed Keywords: metallic silicon, electrochemical lithium storage, anode material of lithium ion battery Abstract.
It is indispensable to dope and modify pure silicon when it is used as electrode materials.
The coating materials can prevent cracking, isolation of particles and suddenly increasing internal resistance. (3) Doping of silicon material [9-10].
[4] Hanping Zhang，Lijun Fu，Yu-Ping Wu， et al，research progress of Lithium ion battery cathode materials [J]。
Journal of Power Sources, 2007,163: 1003- 1039

Currently, there are many hydrogen storage materials, the highly effective adsorption and unique properties of high specific surface materials make it have good application prospects in hydrogen storage.
High specific surface materials will get a great development in hydrogen energy market.
[14] Shuixie Chen, Yun Lu: Journal of Materials Research, Vol. 12 (1998), p. 40, in Chinese
[18] Rongyu Fan: Journal of Nanping Teachers College, Vol. 23 (2004), p. 64 , in Chinese
[20] Bin Cai, Xxlin Yu: Development and Application of Materials, Vol. 26 (2011), p.79, in Chinese

As a type of the novel semiconductor materials, tungsten oxide (WO3) is applied extensively in recent years for its electrochromic property.
It has been widely used in many different applications, such as electrochromic windows, optical devices, fuel cells, gas sensors, and photocatalyst materials, etc.
Experiments In the experiments of fabricating hydrogen sensitive films for the optic-fiber sensor, tungsten trioxide was used as the basic materials, and the platinum-doped WO3 films were prepared with sol-gel method and magnetron sputtering method, as shown in Figure 1.
Acknowledgment This work is finically supported by the Project of National Science Foundation of China, NSFC (Number: 11076030).
Grassi, and D.Shenoy:Journal of Materials Chemistry Vol. 17(2007) [6] J.Beusink, A.Lokate and G.Besselink:Biosensors and Bioelectronics Vo1.23(2008),p.839 [7] Y.Jin, and Y.Cho: Transactions of the Korean Institute of Electrical Engineers Vo1.58(2009),p.147 [8] Y.Tang, Y.Xu, and J.Xu: Journal of Chongqing University of Science and Technology Vol.7 (2005) [9] X.Fan, Y.TANG, and C.Hou: Journal of Functional Materials and DevicesVol.14(2008)

Mahoney, “Friction Stir Processing: A New Grain Refinement Technique to Achieve High Strain Rate Superplasticity in Commercial Alloys,” Materials Science Forum, vol. 357-359, pp. 507-514, 2001
Omar, “Friction stir processing of commercial AZ31 magnesium alloy,” Journal of Materials Processing Technology, vol. 191, no. 1-3, pp. 77-81, Aug. 2007
Zhan, “Coupled thermo-mechanical FE simulation of the hot splitting spinning process of magnesium alloy AZ31,” Computational Materials Science, vol. 47, no. 3, pp. 857-866, Jan. 2010
Fatemi-Varzaneh, “An analysis to plastic deformation behavior of AZ31 alloys during accumulative roll bonding process,” Journal of Materials Science, vol. 45, no. 16, pp. 4494-4500, Apr. 2010
Beladi, “Dynamic recrystallization in AZ31 magnesium alloy,” Materials Science and Engineering: A, vol. 456, no. 1-2, pp. 52-57, May 2007.

The paper presents new, possible applications of artificial neural networks in the field of materials science and material engineering in relation to other artificial intelligence methods known and applied in this area.
Numerous researches over the last decade, pursued at the Institute of Engineering Materials and Biomaterials of the Silesian University of Technology, have been relating to the application of neural networks for modeling and simulating different concepts in the field of materials science and engineering [1–3].
Trzaska, Application of neural network for the prediction of continuous cooling transformation diagrams, Computational Materials Science 30(3–4) (2014) 251–259
Trzaska, Modeling of the optimum heat treatment conditions of Mg-Al-Zn magnesium cast alloys, International Journal Computational Materials Science and Surface Engineering 1(5) (2007) 540–554
Labisz, Neural networks aided future events scenarios presented on the example of laser surface treatment, Archives of Materials Science and Engineering 51(2) (2011) 69–96.