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Steel corrosion rate in soils by a.c and d.c electrochemical methods[J].Materials Chemistry and Physics,1990,26(3):323-330
Introduction to atmospheric corrosion research in China[J].Science and Technology of Advanced Materials,2007,8(7):559-565
Evaluation of technology for wastes and soils contaminated with dioxins,furans,and related substances[J].Journal of Hazardous Materials,1987,14(1):119-133
Assessment of damages and repair of antenna tower concrete foundations[J].Construction and Building Materials,2002,16(8):527-534
Review on research methods of soil corrosion for buried pipeline steels[J].Journal of Nanjing University of Technology,2008,30(4):105-110

Society for Optical Engineering, v. 7642, 2010, [25] He et al, Journal of Functional Materials, v. 42, SUPPL.
Kwang, Material Science Forum, Volume 426(432), 2003, pp. 2249-2254
Kwang, Smart Materials and Structures, v. 9(4), p. 543-551
[42] Bian et al, Chinese Journal of Materials Research, v. 24(5), p.520-524, October 2010
[48] Jin et al, Gongneng Cailiao/Journal of Functional Materials, v 39, n 11, p 1933-1936, 2008

Al-Kaisy3,c 1,2,3Department of Materials Engineering / University of Technology, Bagdad, Iraq.
Huang: submitted to Journal of materials engineering and performance (2012)
Wang: submitted to Journal of Materials Chemistry (2013). https://doi.org/10.13023/ETD.2017.296 [7] A.
Miola: submitted to Materials (2019)
Dhara: submitted to Materials Science and Engineering (2019)

Journal of Refractory Metals and Hard Materials, 13 (1995) 305-12
Journal of Refractory Metals and Hard Materials, 26 (2008) 48–54
Ruan, Preparation and sintering of WC–Co composite powders for coarse grained WC–8Co hard metals, International Journal of Refractory Metals and Hard Materials, 45 (2014) 80-85
Sherif El-Eskandarany, Mechanical Alloying for Nanotechnology, Materials Science and Powder Metallurgy, Elsevier Inc, Philadelphia, PA 19103-2899, the U.S.A, (2014)
Suryanarayana, and Nasser Al-Aqeeli, Mechanically alloyed nanocomposites, Progress in Materials Science, 58 (2013) 383–502

Visualisation of the Melt Flow under Rotating Magnetic Field Arnold Rónaföldi 1,a, Jenő Kovács 2,b , András Roósz 3,c 1 University of Miskolc, Department of Electrical and Electronic Engineering H-3515 Miskolc-Egyetemváros, Hungary 2 Hungarian Academy of Sciences - University of Miskolc, Materials Science Research Group H-3515 Miskolc-Egyetemváros, Hungary 3 University of Miskolc, Department of Physical Metallurgy and Metalforming H-3515 Miskolc-Egyetemváros, Hungary a elkronar@uni-miskolc.hu, b femkjeno@uni-miskolc.hu, c femroosz@uni-miskolc.hu Keywords: Liquid Gallium, Melt Flow, Magnetic Stirring, Rotating Magnetic Field, Magnetic Taylor Number, Revolution Number, Elevation of Gallium Level, "Turbine-Like" Facility Abstract.
Kim: Journal of Materials Processing Technology, 111, (2001), p. 69 [2] E.
Es-Sadiqi: Journal of Materials Processing Technology, 120 (2002), p. 365 [3] J.
Szőke: Material Science Forum Vol. 508, (2006), p.263 [4] P.
Mueller: Journal of Crystal Growth, 266 (2004) p. 224 [5] Dr.

Research on the Tendency of Inner Crack during 3-Roll Skew Rolling Process of Round Billets Shengzhi Li 1, a , Wenhua Meng 1, b , Lanwei Hu1, c and Bo Ding1, d 1 School of Materials Science and Engineering, Anhui University of Technology, Maanshan 243002, China a lisz55@163.com, bmm163000@163.com, chlwcyy0612@126.com, dwww024151@163.com Keywords: 3-roll skew rolling; damage; annular inner crack; coupled thermo-mechanical simulation Abstract.
The material of the billet is X12CrNi18-8.
The flow stress and thermal physical properties of the material are read from the material database of the MSC.SuperForm.
References [1] Li Shengzhi, Li Lianshi and Sun Zhongjian: Journal of University of Science and Technology Beijing, Vol. 22 (1999), p. 52 (In Chinese)
[2] Yang Cuiping, Zhang Kangsheng, Liu Jinping and Hu Zhenghuan: Journal of University of Science and Technology Beijing, Vol. 28 (2006), p. 464 (In Chinese)

Dayananda, Recovery stress generation in shape memory Ti50Ni45Cu5 thin wires, Materials Science and Engineering, 2000, A386, 298-311
Stalmans, Recovery Stress of TiNi shape memory wires, Smart Structure and Materials, 1998, 3667, 825-835
Cao, Effects of prestrain on recovery strain and stress in Ni-50.4Ti alloy, Chinese Journal of Material Research, 2000, 14, 573
Cui, Effects of pre-deformation on the reverse martensitic transformation of TiNi shape memory alloy, Material Science Technology, 2000, 16(6) 611
[17] Huibin Xu, Chengbao Jiang, Shengkai Gong, Gen Feng, Martensitic transformation of the Ti50Ni48Fe2 alloy deformed at different temperatures, Materials Science and Engineering, 2000, A281, 235

International Journal of Geographic Information Sciences. 14,153(2000)
International Journal of Geographic Information Systems. 8, 271(1994)
International Journal of Remote Sensing. 13, 263(2002)
Journal of the Indian Society of Remote Sensing.31, 283(2003)
Science in China (Series D).47, 201(2004)

If the cutting plane is in the horn's step part, ultrasonic wave vibration energy loss can be reduced substantially and it can also be used as stress stiffener in the cutting plane by ultrasonic vibration. [4-5] ∑=Fxm �� 22 dtudx =�� ),( tx x u EAAF ∂ ∂ ⋅==σ xu ∂∂=εεσ E= ),( 1 ),( 2 2 2 2 2 tx tu c tx x u ∂ ∂ = ∂ ∂ ρ E c = �,3,2,1=n k2 1 =� 0 2 2 2 =+ Uk dx Ud λ ω 1 == c k ρ ω En �2 = Fig. 3 Amplitude and Ultrasonic horn Design of horn Horn is half-wavelength object, its materials are generally used aluminum alloy, titanium alloy.
Therefore, material of horn to be designed is titanium alloy and the material properties is showed in Table 1.
Epilogue This content is the research result of In-Chun university academic-industrial university fostering business which was conducted by the contribution of education science technology department/knowledge economy department.
References [1] Bong-Gu Lee, Kwang-Lae Kim, Kang Eun Kim: Journal of KSMTE, Vol. 17, No. 6 (2008), P. 63 [2] B.Y.Park: Vibrations, an Introduction, CMG Book (2006) [3] S.G.Amin, M.H.M.Ahmed, H.A.Youssef: Journal of Materials Processing Technology, Vol. 55 (1995), p. 254 [4] G.B.Lee, H.S.Kim: Journal of the Korean Society of Precision Engineering, Vol. 13, No.11 (1996), p. 38 [5] Gon-Gu Lee, Kwang-Lae Kim, Kang Eun Kim: Transactions of the Korean society of Machine Tool Engineers, Vol. 17, No. 6 (2008) [6] J.P.Kang: Journal of the Korean Society of Precision Engineering, Vol. 8, No.3 (1991), p. 55 [7] Sun-Rak Kim, Jae Hak Lee, Choong D.
Yoo: Journal of KWJS, Vol.27, No. 4 (2009), p.404

Compressive strength is a pivotal factor in evaluating the structural integrity of earthen materials.
Density, another critical property influencing the performance of earthen materials, can also be evaluated using the UPV method.
Varum, Towards a methodology for use of sonic and ultrasonic tests in earthen materials, https://doi.org/10.23967/sahc.2021.307
Ighalo, Predicting the compressive strength of concrete by ultrasonic pulse velocity, IOP Conference Series Materials Science and Engineering 1036 (2021) 012053
Karatasios, Quantitative evaluation of self-healing capacity in cementitious materials, Material Design & Processing Communications 3 (2020)