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Used the gauss body heat source to irradiate underwater aluminum target material, in this paper, simulated the process of punching, gauss body heat source equations as follows: (1) Where U is energy on the surface of the aluminum material; a is the optical depth of material; b is the absorptions of material for laser energy; r is 95% of the heat source center to spot radius.
Governing equation of the model can be expressed as a function of temperature: (2) Where is the density of material; is the heat capacity of materials; is time; is the heat source; is changing with temperature coefficient of thermal conductivity.
Acknowledgements This project was funded by National Natural Science Foundation of China (Grant No.61366009), the Guangxi Natural Science Foundation (Grant No. 2012GXNSFAA053202), the director Fund of Guangxi Manufacturing Systems and Advanced Manufacturing Technology Laboratory (Grant No. 13-051-09-004Z), and Guangxi Experiment Center of Information Science, Guilin University of Electronic Technology (Grant No. 20130313) References [1] W.
Peng: China Journal of Lasers, Vol. 36 (2009), No.11, p.3064-3067
Yu: China Journal of Lasers, Vol. 31 (2004), No.12, p.1527-1532

Martins, End forming of thin-walled tubes, Journal of Materials Processing Technology. 177 (2006) 183-187
Martins, Cold expansion and reduction of thin-walled PVC tubes using a die, Journal of Materials Processing Technology. 209 (2009) 4229-4236
[4] Jialing Yang, Min Luo, Yunlong Hua, Guoxing Lu, Energy absorption of expansion tubes using a conical–cylindrical die: Experiments and numerical simulation, International Journal of Mechanical Sciences. 52 (2010) 716-725
[5] He Mao, Changjie Luo, Kai He, Ruxu Du, Numerical and experimental investigations on the expansion tube energy absorber, Applied Mechanics and Materials. 190-191 (2012) 115-120
[6] He Mao, Kai He, Changjie Luo, Ruxu Du, Axial compression and energy absorption characteristics of reduction tubes using a die under impact load, Advanced Materials Research. 712-715 (2013) 1519-1526

Scientific works Construction, materials science, mechanical engineering, (58), 351-352
Science and Technology of Zirconia, (3), 25
Construction, materials science, engineering.
Journal, (4)
Aviation materials and technologies, 3(52). 22-26

Starbuck, Journal of Composite Materials, vol. 36, pp. 813-850, 2002
Kuebler, "Activated pressureless melt infiltration of zirconia-based metal matrix composites," Materials Science and Engineering, vol.
Adams, Electron Backscatter Diffraction in Materials Science: Kluwer Academic / Plenum New York, 2000
Nowell, "High speed EBSD," Advanced Materials, p. 3, 2008
Hannink, "Microstructural development of sub-eutectoid aged MgO-ZrO2 alloys," Journal of Materials Science, vol. 18, pp. 457-470, 1983

In asymmetric hybrid supercapacitors, the electrodes use dissimilar materials, such as materials with different charge storing mechanisms.
The cathode and anode materials also have different potential windows to achieve maximum potential.
Advanced Materials, 25(29):4035–4042, May 2013
APL Materials, 7(10), October 2019
Science China Materials, 61(2):254–262, January 2018.

As a result, adjusted materials for different applications were developed.
The joining of dissimilar materials by welding is procedurally limited.
Roll, Development of a Mechanical Joining Process for Automotive Body-In-White Production, International Journal of Material Forming, Volume 3, 2010, pp. 1059–1062
Lee, Parametric study on mechanical clinching process for joining aluminum alloy and high-strength steel sheets, Journal of Mechanical Science and Technology 24, 2010, pp. 123–126
Kato, Joining of high strength steel and aluminium alloy sheets by mechanical clinching with dies for control of metal flow, Journal of Materials Processing Technology, 2012, pp. 884–889

A. de Castro: Materials Science Forum Vol. 727–728 (2012), p. 146
[6] M.F. de Campos: Materials Science Forum Vol. 591–593 (2008), p. 8
Materials Science Forum Vol. 727–728 (2012), p. 119
Journal of Magnetism and Magnetic Materials Vol. 328 (2013), p. 53
F. de Campos: Materials Science Forum Vol. 660-661 (2010), p. 283

But behavior of advanced composites with respect to different loading conditions is a complex issue due to their non homogeneity nature which causes failure in quite different manners than homogeneous materials [1].
The main reason is that mechanical properties of composite materials vary significantly with changing the displacement rate and strain rate due to their non homogeneity nature [2, 3].
This clearly shows that in design level GFRP and CFRP more suitable when compared to kevlar when the materials are subjected to varying loading conditions.
Ÿ At design level GFRP and CFRP more suitable when compared to kevlar when the materials are subjected to varying loading conditions.
Gurusideswar, Strain Rate Dependent Behavior of Glass/Nano Clay Filled Epoxy Resin Composite, Defence Science Journal.64 (2014)295-302

Mucken, Proceedings from Materials Solutions Conference.
Santella, Structure-properties relations in spot friction Welded (also known as friction Stir Spot Welded), Journal of Materials Science and Engineering , A441(2006) 79-96 [11] K.
Materials and Design, 33(2012) 545-550 [14] M.K.
Sanjeev, Effect of Process Parameters & Tool Geometries on Properties of Friction Stir Spot Welds, Universal Journal of Engineering Science, 3(2015) 6-11 [18] M.K.
Okamoto, Material flow during friction stir spot welding, Materials Science and Engineering A, 527(2010) 4389-4398 [20] A.M.Takhakh, S.J.

Journal of Material Science and Engineering, 2(1):1-4
Journal of Materials Processing Technology, 210:618-623
Journal of Nuclear Materials, 470:13-29
Journal of Materials Processing Technology, 142:738-743
Journal of Materials Processing Technology, 209:4795-4801