Shock Compression of the New 47Zr45Ti5Al3V Alloys up to 200 GPa
ZHANG Pin-Liang1, GONG Zi-Zheng1,2**, JI Guang-Fu3, WANG Qing-Song3, SONG Zhen-Fei3, CAO Yan2, WANG Xiang3
1Key Laboratory of Advanced Technologies of Materials of Ministry of Education, School of Material Science and Engineering, Southwest Jiaotong University, Chengdu 610031 2National Key Laboratory of Science and Technology on Reliability and Environment Engineering, Beijing Institute of Spacecraft Environment Engineering, Beijing 100094 3Laboratory for Shock Wave & Detonation Physics Research, Institute of Fluid Physics, China Academy of Engineering Physics (CAEP), Mianyang 621900
Abstract:Shock compression experiments on a new kind of 47Zr45Ti5Al3V alloys at pressures between 28 and 200 GPa are performed using a two-stage light gas gun. The Hugoniot data are obtained by combining the impedance-match method and the electrical probe technique. The relationship between the shock wave velocity Us and particle velocity up can be described linearly by Us=4.324(±0.035) +1.177(±0.012) up. No obvious evidence of phase transition is found in the shock compression pressure range. The calculated Us?up relationship obtained from the additive principle is different from the experimental data, indicating that the α→β phase transition occurs below 28 GPa. The Grüneisen parameter γ obtained from the experimental data can be expressed by γ=1.277(ρ0/ρ). The zero-pressure bulk modulus B0s=97.96 GPa and its pressure derivative B'0s=3.68. The P–V–T equation of state for 47Zr45Ti5Al3V is given using the Vinet equation of state to describe the cold curve and the Debye model for the thermal contributions.
. [J]. 中国物理快报, 2013, 30(6): 66401-066401.
ZHANG Pin-Liang, GONG Zi-Zheng, JI Guang-Fu, WANG Qing-Song, SONG Zhen-Fei, CAO Yan, WANG Xiang. Shock Compression of the New 47Zr45Ti5Al3V Alloys up to 200 GPa. Chin. Phys. Lett., 2013, 30(6): 66401-066401.
[1] Liang S X, Ma M Z, Jing R, Zhang X Y and Liu R P 2012 Mater. Sci. Eng. A 532 1 [2] Liang S X, Ma M Z, Jing R, Tan C L and Liu R P 2012 Mater. Sci. Eng. A 541 67 [3] Honnell K G, Velisavljevic N, Adams C D, Rigg P A, Chesnut G N, Aikin R M and Boetter J C 2007 Shock Compression Condens. Matter-2007 (Hawaii 24–29 June 2007) p 55 [4] Kerley G I 2003 SAND 2003-3785 (USA: Sandia National Laboratories) [5] Zhang P L, Gong Z Z, Ji G F and Liu S 2013 Acta Phys. Sin.62 046202 (in Chinese) [6] Young D A 1991 Phase Diagrams of the Elements (Berkeley: University of California Press) [7] Wang J, Zhang H W, Wang A M, Li H, Fu H M and Zhu Z W 2012 Acta Metall. Sin.48 636 [8] Kishawy H A, Becze C E and Mcintosh D G 2004 J. Mater. Process. Tech.152 266 [9] Jing F Q 1999 Introduction to Experimental Equation of State 2nd edn (Beijing: Science) (in Chinese) [10] Mitchell A C and Nellis W J 1981 J. Appl. Phys.52 3363 [11] Marsh S P 1980 LASL Shock Hugoniot Data (Los Angeles: University of California) [12] Winfree N A, Chhabildas L C, Reinhart W D, Carroll D E and Kerley G I 2002 Shock Compression Condens. Matter-2001 (Georgia 24–29 June 2001) p 75 [13] McQueen R G 1991 `E. Fermi' 1989 Summer School (Amsterdam, North-Holland 1989) p 101 [14] Tang W H and Zhang R Q 1999 Equation of State Theory and Calculation Conspectus (Changsha: National University of Defense Technology) (in Chinese) [15] Xu X S and Zhang W X 1986 Introduction to Practical Equation of State Theory (Beijing: Science) (in Chinese) [16] Murray J L 1981 Bull. Alloy Phase Diagrams2 197 [17] Hu J B and Jing F Q 1990 Chin. J. High Press. Phys.3 175 (in Chinese) [18] Wu Q 2004 PhD Dissertation (Mianyang: China Academy of Engineering Physics) (in Chinese) [19] Vinet P, Rose J H, Ferrante J and Smith J R 1989 J. Phys.: Condens. Matter1 1941 [20] Wen C, Liu X X, Zhou G and Sun D 2000 J. Xi'an Jiaotong University34 108 (in Chinese)
2013, Vol. 30 
