Characteristics of metal ablation product by intense pulsed ion beam irradiation

Zhang Jie; Zhong Hao-Wen; Shen Jie; Liang Guo-Ying; Cui Xiao-Jun; Zhang Xiao-Fu; Zhang Gao-Long; Yan Sha; Yu Xiao; Le Xiao-Yun

doi:10.7498/aps.66.055202

Abstract

Intense pulse ion beam (IPIB) has been extensively used in material surface modification. The ablation effect plays an important role in the interaction between IPIB and material. Therefore, the understanding of ablation mechanism is of great significance for IPIB application. Here, to investigate the ablation process and the characteristics of ablation products, pure zinc targets are bombarded by IPIB of 1.2-1.5 J/cm2 energy density at TEMP-4M accelerator. The ablation products are collected by monocrystalline silicon substrates in the IPIB irradiation process. By using the scanning electron microscopy, energy dispersive spectrometer and high precision balance, the surface morphology of the substrate and the characteristics of ablation products are obtained. The majority of observed ablation products are nearly circular particles with diameters of 0.03-2.00 m. There are a small number of zinc droplets and solid debris with large irregular shapes on the silicon substrate. Combining Monte Carlo method and infrared imaging diagnostic results, a heat conduction model is constructed by finite element method to describe the distribution and evolution of thermal field formed by IPIB on a zinc target. The results show that the zinc target can be melted and evaporated under a 1.2 J/cm2 IPIB irradiation. By comparing the experimental resuls with the simulation results, it is found that the gaseous, liquid and solid ablation products are generated collectively in the zinc ablation process. The causes of the different ablation products are also studied.

Keywords:

Authors and contacts

1.
School of Physics and Nuclear Energy Engineering, Beihang University, Beijing 100191, China;
2.
Beijing Key Laboratory of Advanced Nuclear Energy Materials and Physics, Beihang University, Beijing 100191, China;
3.
Institute of Heavy Ion Physics, Peking University, Beijing 100871, China

Corresponding author: Le Xiao-Yun, xyle@buaa.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 11175012) and the National Science and Technology Major Project of the Ministry of Science and Technology of China (Grant No. 2013GB109004).

References

[1]	Humphries J S 1980Nucl.Fusion 20 1549
[2]	Rej D J, Davis H A, Olson J C, Remnev G E, ZakoutaevA N, Ryzhkov V A, Struts V K, IsakovI F, ShulovV A, NochevnayaN A, Stinnett R W, NeauE L, YatsuiK, Jiang W 1997J.Vac.Sci.Technol.A 15 1089
[3]	Remnev G E, Isakov I F, Opekounov M S, Matvienkoa V M, Ryzhkova V A, Strutsa V K, Grushina I I, Zakoutayeva A N, Potyomkina A V, Tarbokova V A, Pushkaryova A N, Kutuzovb V L, Ovsyannikovb M Y 1999Surf.Coat.Technol. 114 206
[4]	Zhao W J, Remnev G E, Yan S, Opekounov M S, Le X Y, Matvienkoa V M, Han B X, Xue J M, Wang Y G 2000Rev.Sci.Instrum. 71 1045
[5]	Piekoszewski J, Werner Z, Szymczyk W 2001Vacuum 63 475
[6]	Yatsui K, Grigoriu C, Masugata K, Jiang W, Sonegawa T 1997Jpn.J.Appl.Phys. 36 4928
[7]	Davis H A, Johnston G P, Olson J C, Rej D, Waganaar W J, Ruiz C L, Schmidlapp F A, Thompson M O 1999J.Appl.Phys. 85 713
[8]	Mei X X, Xu J, Ma T C 2002Acta Phys.Sin. 51 1875(in Chinese)[梅显秀, 徐军, 马腾才2002物理学报51 1875]
[9]	Pushkarev A I, Isakova Y I, Vakhrushev D V 2010Phys.Plasmas 17 123112
[10]	Isakova Y I 2011IEEE Pulsed Power Conference America, Chicago, June 19-23, 2011 p334
[11]	Isakova Y I, Pushkarev A I 2013Instrum.Exp.Tech. 56 185
[12]	Yu X, Shen J, Zhong H W, Qu M, Zhang J, Zhang G L, Zhang X F, Yan S, Le X Y 2015Acta Phys.Sin. 64 175204(in Chinese)[喻晓, 沈杰, 钟昊玟, 屈苗, 张洁, 张高龙, 张小富, 颜莎, 乐小云2015物理学报64 175204]
[13]	Shen J, Yu X, Zhang Y Y, Zhong H W, Zhang J, Qu M, Yan S, Zhang G L, Zhang X F, Le X Y 2015Nucl.Instrum.Methods Phys.Res.Sect.B 365 26

Cited By

[1]	Humphries J S 1980Nucl.Fusion 20 1549
[2]	Rej D J, Davis H A, Olson J C, Remnev G E, ZakoutaevA N, Ryzhkov V A, Struts V K, IsakovI F, ShulovV A, NochevnayaN A, Stinnett R W, NeauE L, YatsuiK, Jiang W 1997J.Vac.Sci.Technol.A 15 1089
[3]	Remnev G E, Isakov I F, Opekounov M S, Matvienkoa V M, Ryzhkova V A, Strutsa V K, Grushina I I, Zakoutayeva A N, Potyomkina A V, Tarbokova V A, Pushkaryova A N, Kutuzovb V L, Ovsyannikovb M Y 1999Surf.Coat.Technol. 114 206
[4]	Zhao W J, Remnev G E, Yan S, Opekounov M S, Le X Y, Matvienkoa V M, Han B X, Xue J M, Wang Y G 2000Rev.Sci.Instrum. 71 1045
[5]	Piekoszewski J, Werner Z, Szymczyk W 2001Vacuum 63 475
[6]	Yatsui K, Grigoriu C, Masugata K, Jiang W, Sonegawa T 1997Jpn.J.Appl.Phys. 36 4928
[7]	Davis H A, Johnston G P, Olson J C, Rej D, Waganaar W J, Ruiz C L, Schmidlapp F A, Thompson M O 1999J.Appl.Phys. 85 713
[8]	Mei X X, Xu J, Ma T C 2002Acta Phys.Sin. 51 1875(in Chinese)[梅显秀, 徐军, 马腾才2002物理学报51 1875]
[9]	Pushkarev A I, Isakova Y I, Vakhrushev D V 2010Phys.Plasmas 17 123112
[10]	Isakova Y I 2011IEEE Pulsed Power Conference America, Chicago, June 19-23, 2011 p334
[11]	Isakova Y I, Pushkarev A I 2013Instrum.Exp.Tech. 56 185
[12]	Yu X, Shen J, Zhong H W, Qu M, Zhang J, Zhang G L, Zhang X F, Yan S, Le X Y 2015Acta Phys.Sin. 64 175204(in Chinese)[喻晓, 沈杰, 钟昊玟, 屈苗, 张洁, 张高龙, 张小富, 颜莎, 乐小云2015物理学报64 175204]
[13]	Shen J, Yu X, Zhang Y Y, Zhong H W, Zhang J, Qu M, Yan S, Zhang G L, Zhang X F, Le X Y 2015Nucl.Instrum.Methods Phys.Res.Sect.B 365 26

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Vol. 66, Issue 5 - 2017-03-05

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