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Lv and et al: Journal of Disaster Prevention and Mitigation Engineering Vol. 23 (2003), p. 50-55 [3] Y.
Liu: Journal of Catastrophology Vol. 26 (2011), p. 68-72 [4] B.
Wu: Journal of Engineering Geology Vol. 18 (2010), p. 827-836 [5] Y.
Chen: Journal of Disaster Prevention and Mitigation Engineering Vol. 25 (2005), p. 146-151 [6] L.Y Wen, G.
KANG and et al: Debris Flow and Its Comprehensive Control (Science Press, China 1993)

Experimental Analysis on Mechanical Properties of Perforated Casing in Complex Fracturing Lihong Han1,2,3,a, Guangxi Liu4, Shangyu Yang1,2,3* and Peng Wang1,2,3 1State key Laboratory for Performance and Structure Safety of Petroleum Tubular Goods and Equipment Materials, CNPC Tubular Goods Research Institute, Xi’an, Shaanxi 710077 China 2Shaanxi key Laboratory for Performance and Structure Safety of Petroleum Tubular Goods and Equipment Materials, Xi’an, Shaanxi 710077, China 3Key Laboratory of Petroleum Tubular Goods Engineering, CNPC, Xi’an, Shaanxi 710077 China 4CNPC Xinjiang oilfield heavy oil production company, Karamay, Xinjiang 834000, China.
Numerical investigation for different casing deformation reasons in Weiyuan-Changning shale gas field during multistage hydraulic fracturing[J].Journal of Petroleum Science and Engineering, 2018, 49:331-341
Investigation of casing deformation during hydraulic fracturing in high geo-stress shale gas play[J].Journal of Petroleum Science and Engineering, 2017, 150:22-29
[12] Yin Fei, Han Lihong, Yang Shangyu, et al.Casing deformation from fracture slip in hydraulic fracturing[J].Journal of Petroleum Science and Engineering, 2018, 166:235-241
Journal of Petroleum Science and Engineering, 2018, 168:32-38.

Mechanical properties were investigated on multiphase materials applied a generalized means to distinguish the elastic modulus of is the bulk, shear and young's modulus with strength of flow for multistage composite material [4-6].
[4] Han, Q., Chen, P and Ma, T., Influencing factor analysis of shale micro-indentation measurement, Journal of Natural Gas Science and Engineering. 27 (2015) 641-650
Beecham, The relationship between porosity and strength for porous concrete, Construction and Building Materials. 25(11) (2011) 4294-4298
[10] Baud, Wong, T.F and Zhu, W, Effects of porosity and crack density on the compressive strength of rocks, International Journal of Rock Mechanics and Mining Sciences. 67 (2014) 202-211
[16] Medani, Mohammed et al., Static and dynamic behavior of (FG-CNT) reinforced porous sandwich plate using energy principle, Steel and Composite Structures. 32(5) (2019) 595-610 [17] Liu et al, Dynamic mechanical behaviour of recycled crumb rubber concrete materials subjected to repeated impact, Journal of Materials Research Innovations. 19(8) (2015) 496-501 [18] Nikhilesh and Chawla, Microstructure-based modeling of the deformation behavior of particle reinforced metal matrix composites, Journal of Materials Science. 41(3) (2016) 913-925

The selected materials were a 0.20-mm thick, obtained by cold (secondary)-rolled and continuous annealing or cover annealing, coated with an electrolytical substrate.
Journal of Materials Processing Technology, 152(2004), p.384-388
Journal of Iron and Steel Research, 13-4 (2001), p. 38-41.
Corrosion Science, 52(2010), p.14-20
Materials Protection. 33 -3 (2000), p.1~3.

Plastic packaging materials have a very short lifetime due to their function.
Materials & Methods Materials.
Bocz, Recycled PET packaging materials of improved toughness— Importance of devitrification of the rigid amorphous fraction, Macromolecular Materials and Engineering. (2024) 2400219
Mohanty, Biodegradable compatibilized polymer blends for packaging applications: A literature review, Journal of Applied Polymer Science. 135 (2018) 45726
Gan: Influence of blend composition and compatibilizer on mechanical and morphological properties of recycled HDPE/PET blends, Materials Sciences and Applications. 5 (2014) 943-952

Introduction Ni-based superalloys are widely used as turbine blade materials for advanced engines which may suffer from corrosion problems induced by chlorides when they are in service or out of service in marine environments.
[4] Huiping Bai, Fuhui Wang: Journal of Materials Science and Technology, Vol 23, No.4 (2007), P.541
[5] Huiping Bai, Fuhui Wang: Chinese Journal of Materials Research, Vol 22, No.2 (2007), P.147
[6] Huiping Bai, Fuhui Wang: Chinese Journal of Corrosion Science and protection technology, Vol 20, No.6 (2008), P.400
[7] Hanyi Lou, Shenlong Zhu and Fuhui Wang: Chinese Journal of Corrosion Science and protection technology, Vol 5, No.3 (1993), P.203

With the continuous development of science and technology, the function of the electrochemical biosensor is becoming more and more diversified.
This article summarizes the characteristics of all kinds of conventional materials of enzyme-free glucose sensor, the domestic and foreign general preparation methods of enzyme-free glucose sensors, the specific characterization of the electrode, its application fields, and prospects for future development.
At present there have been great achievements in the field of enzyme-free glucose biosensors, and various electrode materials, inducing the oxide materials and alloy materials based on platinum, gold, and nickel have synthesized, along with copper and its oxides.
With the broadening scope of applications of glucose sensors, preparation methods and preparation of materials, it will be continuously improved.
BMJ: British Medical Journal, 1998, 703-713

Saito, Phase-stability dependence of plastic deformation behavior in Ti-Nb-Ta-Zr-O alloys, Journal of Materials Engineering and Performance 14 (2005) 747-754
Matviychuk, Deformation behavior of beta-titanium alloys, Materials Science and Engineering: A 354 (2003) 121-132
Schwarzer, Evolution of cold rolling texture in the binary alloys: Ti–0.4 Mn and Ti–1.8 Mn, Materials Science and Engineering: A 307 (2001) 151-157
Semiatin, Thermomechanical processing of beta titanium alloys—an overview, Materials Science and Engineering: A 243 (1998) 46-65
Yashiro, Design and mechanical properties of new β type titanium alloys for implant materials, Materials Science and Engineering: A 243 (1998) 244-249.

Bottom ash is a waste byproduct generated from the combustion or incineration of materials such as coal and household waste.
Bottom ashes generated from the incineration of municipal solid waste (MSW) are a mix of inert materials, such as sand, stone, glass, porcelain, metals and ashes from the burnt materials.
The high Al2O3 content on many bottom ashes can result in low cost materials that are corrosion and abrasion resistant.
We would also like to thank the Department of Materials Science, Faculty of Science, Srinakharinwirot University, and Department of Physics and Materials Science, Faculty of Science, Chiang Mai University for providing access to their research facilities.
-H., 2008, “Recycling MSWI bottom and fly ash as raw materials for Portland cement”, Waste Management, vol. 28, pp. 1113–1118

Palomar Pardave: International Journal of Minerals, Metallurgy and Materials.
Vol. 17(2010), p. 403 [2] Yu-TuoZhang, Dian-Zhong Li, Yi-Yi Li: Journal of Materials Processing Technology.
Vol. 171(2006), p. 175 [3] Heung Nam Han, Jae Kon Lee, Hong Joon Kim, Young-Sool Jin: Journal of Materials Processing Technology.
Fattahi: Journal of Materials Processing Technology.
Vol. 47(2010), p. 1159 [8] Heung Nam Han, Jae Kon Lee, Hong Joon Kim, Young-Sool Jin: Journal of Materials Processing Technology.