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Keshavamurthy, A study on microstructure and mechanical properties of Al 6061–TiB2 in-situ composites, Materials Science and Engineering, A 528, 12 (2011) 4125-4132
Anandakrishnan, Mechanical, electrical, and corrosion behavior of AA6063/TiC composites synthesized via stir casting route, Journal of Materials Research 32, 3 (2017) 606-614
Materials Science and Engineering: A 528, 29-30 (2011) 8765-8771
Madhusudan, M.M.M Sarcar and N.B.R Mohan Rao, Mechanical properties of Aluminum-Copper(p) composite metallic materials, Journal of applied research and technology 14, no. 5 (2016) 293-299
Materials Science and Engineering: A 710 (2018) 172-180

The development of fibers used for noise reduction materials is described as well.
Noise reduction materials meet born and hence the blade.
The demands for greater driving comfort and alternative materials are expanding the market for automotive acoustical materials.
Clem: submitted to Journal of Materials Research (2003) [16] L.M.
Journal of Materials Science, Vol.40.

Total Pressure Gradient Incidence on Hygrothermal Transfer in Highly Porous Building Materials K.
Tested materials Three different types of hygroscopic materials are studied.
Physical properties of these materials are listed in Table 1.
This leads to extract conclusion about the hygric behavior of materials according to the total pressure changes.
International Journal of Thermal Sciences, Vol. 57 (2012), p. 135-141

Materials.
Materials Sciences Forum. 423-425 (2003), p. 1-10 [4] F.Delale, F.
Fracture mechanics of functionally graded materials.
Cracks in functionally graded materials.
International Journal of Fracture. 123 (2003), p. 1-14

Experimental method study of climatic evaporation of porous material in wind tunnel Yu Zhang1, a, Qinglin Meng2, b 1 Architectural Design Research Institute of SCUT , State Key Laboratory of Subtropical Building Science, South China University of Technology, Guangzhou 510640, Guangdong, China 2 School of Architecture, State Key Laboratory of Subtropical Building Science, South China University of Technology, Guangzhou 510640, Guangdong, China a arzy@ scut.edu.cn, b arqlmeng@scut.edu.cn Keywords: Climatic evaporation, Porous materials, Hot-humid climatic wind tunnel, Experimental study.
Considered to different texture of materials, different beginning times and different climatic parameters, porous material evaporation experiments were carried out and an experimental model was established.
Guangzhou PM 0.998 0.996 0.296 720 188944.998 0.000 PM-M 0.996 0.993 0.411 720 97684.450 0.000 Porous Building Materials Evaporation Experimental Model Porous building materials evaporation experimental study, based on atmospheric evaporation force was a comprehensive environmental impact of climatic elements, and restricted by porous material characteristics.
Journal of Hydrology 44, 169–190 [6] Coleman, G., DeCoursey, D.G., 1976.
Journal of Hydrology 243, 192-204 [8] I.P.Craig.

Now a day, composites materials are surround us everywhere.
In composite the fiber materials are the main load bearing materials that reinforces the matrix (Epoxy LY556) [7].
Effect of aspect ratio on buckling of composite plates Journal of Composites Science and Technology 59 (1999) 439-445
Numerical tests on the buckling of the plates made of composite materials, Romanian technical sciences academy, vol.3(2006)
[11] Wen-pei, Cheng, Ming-hsiang and Cheer-germ, Analysis modeling for plate buckling load of vibration test, Journal of Zhejiang University science 2005 6A(2):132-140

The behavior of rubber materials is a nonlinear, incompressible characteristic.
There are 3 type models of hyperelastic materials and their corresponding material constants as exhibited in Table 1.
Acknowledgments The authors would like to thank the Administrative Bureau of Central Taiwan Science Park, the National Science Council of the Republic of China, Taiwan, for financially supporting this research under Contract No. 301201401.
Rivlin: Large elastic deformations of isotropic materials I.
Sohrabpour: Constitutive equations for micropolar hyper-elastic materials, International Journal of Solids and Structures, Vol.46, pp. 2765-2773, (2009)

Finite Element Simulation of Abrasive Wear and Study of Wear Resistance of Material Fan Yujin1, a, Li Zhekun1, Han Teng1, Wang Weida1 1Faculty of mechanical and electrical engineering, kunming university of science and technology, kunming,650050,china afanyujinkmust@163.com Keywords: abrasive wear; wear resistance; surface deformation; finite element analysis; numerical simulation Abstract.
Though the development of material science, surface physics and chemistry, surface analyzing and testing technology greatly contributed to further research of friction and wear, however, abrasive wear was complex process and difficult to describe simply[5-6].
There were three metallic materials mentioned in the paper, 35 quenched and tempered steel, 45 normalized steel and 35SiMn quenched and tempered steel, material elasticity modulus E=206GPa, Poisson ν =0.3, the friction coeffient of particle and material surface μ=0.15, Figure 1 was the stress-strain curve of metal material, the mechanical parameters of materials were as follow. 35 quenched and tempered steel: yield stress σs=295MPa, tangent modulus Ctm=825MPa, tensile strength σb=550MPa, reduction of area ψ=0.38, actual tensile strength σbt=1052MPa. 45 normalized steel: yield stress σs=295MPa, tangent modulus Ctm=1070MPa, tensile strength σb=590MPa, reduction of area ψ=0.38, actual tensile strength σbt=952MPa. 35SiMn quenched and tempered steel: yield stress σs=510MPa, tangent modulus Ctm=1120MPa, tensile strength σb=785MPa, reduction of area ψ=0.45, actual tensile strength σbt=1427MPa.
Acknowledgement This work is supported by the National Natural Science Foundation of China, No.51168020..
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This work focuses on the steam gasification with in-situ CO2 capture using CaO as absorbent materials for hydrogen production from palm oil empty fruit bunch (EFB).
Furthermore, CaO materials enhanced the concentration of concentration of the CO, H2 and CH4 in the gas product.
Furthermore, CaO materials enhanced the concentration of concentration of the CO, H2 and CH4 in the gas product.
Amran, Gasification of empty fruit bunch for hydrogen rich fuel gas production, Journal of Applied Sciences.
Tangsathitkulchai, Effects of gasifying conditions and bed materials on fluidized bed steam gasification of wood biomass, Bioresource Technology. 100 (2009) 1419-1427

The results showed that all three firestop materials meet with the ASTM E84 Class A.
This study tests firestop materials for fire compartments through-penetration according to the test methods specified in the American Society for Testing and Materials (ASTM) E84 [5].
Hazardous Materials, Vol.140 (2007), p.327
Moss: Fire Safety Journal, Vol.42 (2007), p.310
Tsai: Experimental Thermal and Fluid Science Vol.32 (2007), p. 29