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As a new inorganic antibacterial agent, TiO2 is widely used in textiles, hygiene products, construction materials and other fields in the last decade [3].
Duan: Journal of Rare Earths, 2007, 25: 268-272
Pang: Journal of Molecular Catalysis A - Chemical, 2006, 247 (1-2): 36-43
Antibacterial Materials.
The Science and Engineering of Materials. 2002, 20(7-8):298-301.

Stanislav Seitl1,a, Pavel Hutař1,b and Alfonso Fernández-Canteli2,c 1 Institute of Physics of Materials, Academy of Sciences of the Czech Republic, v.v.i., Brno, Czech Republic 2 Dept. of Construction and Manufacturing Engineering, E.P.S. de Ingeniería de Gijón, University of Oviedo, Campus de Viesques, 33203 Gijón, Spain a seitl@ipm.cz, bhutar@ipm.cz, cafc@uniovi.es Keywords: Stress intensity factor, T-stress, mixed-mode, Arcan-Richard specimen, Williams expansion Abstract.
Many materials, structures and components loaded uniaxially often contain randomly oriented defects and cracks which evolve to a mixed mode state by virtue of their orientation with respect to the loading axis.
Williams: Journal of Applied Mechanics 24 (1957) p. 109 [7] A.
Knesl: Key Engineering Materials Vols. 417-418 (2010) p. 257 [9] J.
Smith: International Journal Fracture 91 (1998) p. 283 [11] M.A.S.Khan, M.

Experimental Al-20Si was used in the experiment as the material, cut into small pieces, and melted in graphite.
Modifying agent selection for Al-7Si alloy by Miedema model, International Journal of Minerals Metallurgy and Materials,19(2012), 131-135
[4] Amir Hassani ,Khalil Ranjbar ,and Sattar Sami, Microstructural evolution and intermetallic formation in Al-8wt% Si-0.8wt% Fe alloy due to grain refiner and modifier additions, International Journal of Minerals, Metallurgy and Materials,19(2012), 739-746
Evolution of microstructure in spray formed Al–18%Si alloy, Materials Science and Engineering, A, 383(2004),14-20
Effect of electromagnetic vibration on the microstructure of continuously cast aluminum alloys, Materials Science and Engineering, A ,173(1993), 169-172.

Study on Moisture Transfer Properties of Polyester-Cotton Fabric Hong ru Liu 1,a, Feng He 2,b * 1.School of Materials Science and Engineering Beiji1ng Institute of Fashion Technology, Beijing 2.Critical Laboratory of Clothing Material Research-Development and Evaluation, Beijing a:clylhr@bift.edu.cn b:hefeng20024406@126.com * Corresponding author:He Feng,(1983.4-), hefeng20024406@126.com Keywords: polyester-cotton cotton fabric, moisture absorption, fabric density, fabric structure Abstract: In this paper, moisture transfer properties were studied on different weave structure and different weft of polyester-cotton fabric.
The Program was voted for Critical Laboratory of Clothing Material Research-Development and Evaluation—2012ZK-01and 2012 A -22 of BIFT.
Tel: 13693660986; address: School of materials science and engineering Beijing Institute Of Fashion Technology; post code: 100029; E-mail: lucylhr@163.com Reference [1] Tao Haimei, Sun Li.
Journal of Beijing Institute Of Fashion Technology, 2005, 25 ( 1) :25-30
[J]Journal of Textile & Apparel / Tekstil ve Konfeksiyon; 2010, Vol. 20 Issue 2, p93-100, 8p [8] Bao-guo Yao, Yi Li, Yi-lin Kwok .Precision of New Test Method for Characterizing Dynamic Liquid Moisture Transfer in Textile Fabrics.

Experimental Procedure Starting material was commercially pure iron powder (WPL 200) with mean particle size of 88 μm, and with an initial purity level higher than 99.4%, but highly oxidized by exposure to air under inadequate conditions of conservation.
Zavaliangos, Materials Science & Engineering, 2000, A287, 171-177
Zhao, Computational Materials Science 49, 351-362 (2010)
Cintas, Journal of Materials Science 46, 5197-5207 (2010)
Calero, International Journal of Refractory Metals and Hard Materials, Volume 66, August 2017, Pages 88-94.

The material was steam, the density of which is set to be ideal compressible gas.
Jiang: Journal of Power Engineering.
Chen: Atomic Energy Science and Technology.
Inada: Journal of Fluids and Structures.
Zhang: Journal of Zhejiang University SCIENCE A.

The material mechanical properties of steel are shown in Table 2.
Material mechanical properties of steel Models Mondulus of elasticity Ey [GPa] Yield strength fy [MPa] Ultimate Strength fu[MPa] As15.2 196.4 1845 1942 As12.7 195.6 1839 1936 B14 201.5 408 572 B18 204.5 411 587 I14 206.1 245 406 Finite Element Analysis Model of ANSYS Finite element analysis of steel reinforced concrete structure and the other solid materials are same in the principles and methods.
Because of steel reinforced concrete structure is composed of three different materials of steel reinforced, rebar and concrete, and the material constitutive relation is very particularity and complexity, the separate model was adopted in this text.
Fig.3 Cross-sectional unit Fig.4 Constraint handling Fig.5 Reinforced unit Compared to ordinary concrete materials, mechanical properties of the ultra-high strength concrete is very special, and brittle failure is extremely obvious.
Acknowledgements The authors would like to acknowledge the financially supported from project of National Natural Science Foundation of China "Research on Seismic Performance and Ductility-based Seismic Design of Steel Reinforced Ultra-high Strength Concrete Frames" (Grant No. 51078059).

Introduction Geosynthetic clay liners (GCLs) are a new generation of waterproof building materials, which are manufactured clay liners that consist of a thin layer of bentonite glued to a geomembrane or are encased by geotextiles [1,2].
However, how to improve the salt resistance capacity of GCLs in saline water using China bentonites as the raw materials has rarely been reported.
Materials and methods Materials used.
Because diatomite, opals, sepiolite, attapulgite are all porous materials, the specific area of which are large.
Quirk, Changes in basal spacing of montmorillonite in electrolyte solutions, Journal of Colloid and Interface Science. 19 (1964) 798-812

Materials and Methods In predicting the energy absorption value of static axial load on thin-walled square tube by analytical calculations, it has started from the basic folding mechanism method presented by Abramowicz and Wierbicki [10].
In material behaviour a piecewise linear plasticity model is used.
Ramakrishna, "Microstructural design of composite materials for crashworthy structural applications," Materials & Design, vol. 18, no. 3, pp. 167-173, 1997, doi: https://doi.org/10.1016/S0261-3069(97)00098-8
Li, "Parameterization of criss-cross configurations for multiobjective crashworthiness optimization," International Journal of Mechanical Sciences, vol. 124-125, pp. 145-157, 2017, doi: https://doi.org/10.1016/j.ijmecsci.2017.02.027
Supriadi, "Experimental and Numerical Study - Effects of Crush Initiators under Quasi-Static Axial Load of Thin Wall Square Tube," Applied Mechanics and Materials, vol. 660, pp. 628-632, 2014, doi: https://doi.org/10.4028/www.scientific.net/AMM.660.628 [21] Y.

Materials Park, OH: ASM International, 2002
Bozkurt, "Additive manufacturing method and different welding applications," Journal of Materials Research and Technology, vol. 9, no. 5, pp. 11 424-11 438, sep 2020.[5] J.
Kang, "Microstructures and mechanical properties of inconel 718 welds by CO2 laser welding," Journal of Materials Processing Technology, vol. 201, no. 1-3, pp. 515-520, may 2008
Suwas, "Effect of heat treatment on the modification of microstructure of selective laser melted (SLM) IN718 and its consequences on mechanical behavior," Journal of Materials Research, vol. 35, no. 15, pp. 1949-1962, jun 2020
Liu, "Effect of standard heat treatment on the microstructure and mechanical properties of selective laser melting manufactured inconel 718 superalloy," Materials Science and Engineering: A, vol. 644, pp. 32 - 40, 2015.