[2] Shabanov S V, Gornushkin I B. Emission plasma tomography with large acceptance angle apertures relevant to laser induced plasma spectroscopy [J]. Spectrochim Acta Part B, 2011, 6(6): 413-420.
[3] Dário S J, Lidiane C N, Gabriel G A, et al. Laser-induced breakdown spectroscopy for analysis of plant materials: A review [J]. Spectrochim Acta Part B, 2012, 71-72: 3-13.
[4] Xiao Qingmei, Yao Zhi, Liu Jiahong, et al. Synthesis and characterization of Ag-Ni bimetallic nanoparticles by laser-induced plasma [J]. Thin Solid Films, 2011, 519(4): 7116-7119.
[5] Mayo R, Ortiz M, Plaza M. Measured Stark widths of several Ni II lines [J]. J. Phys. B: At Mol. Opt. Phys., 2008, (41): 095702-095709.
[6] Fantoni R, Caneve L, Colao F, et al. Metodologies for laboratory laser induced breakdown spectroscopy semi-quantitative and quantitative analysis-A review [J]. Spectrochim Acta Part B, 2008, 63(10): 1097-1108.
[7] Alonso M A. Experimental determination of the Stark widths of PbI spectral lines in a laser-induced plasma [J]. Spectrochim Acta Part B, 2008, 63(5): 598-602.
[8] Elhassan A, Giakoumaki A, Anglos D, et al. Nanosecond and femtosecond laser induced breakdown spectroscopic analysis of bronze alloys[J]. Spectrochim Acta Part B, 2008, 63(4): 50411.
[10] Liu W, Xu H L, Méjean G, et al. Efficient non-gated remote filament-induced breakdown spectroscopy of metallic sample [J]. Spectrochim Acta Part B, 2007, 62(1): 76-81.
[11] Cristoforetti G, Lorenzetti G, Legnaioli S, et al. Investigation on the role of air in the dynamical evolution and thermodynamic state of a laser-induced aluminium plasma by spatial- and time-resolved spectroscopy [J]. Spectrochim Acta Part B, 2010, 65(9-10): 787-796.
[15] Ma Q L, Motto-Ros V, Lei W Q, et al. Temporal and spatial dynamics of laser-induced aluminum plasma in argon background at atmospheric pressure: Interplay with the ambient gas [J]. Spectrochim Acta Part B, 2010, 65(11): 896-907.
[16] Zorba V, Mao Xianglei, Richard E. Ultrast laser induced breakdown spectroscopy for high spatial resolution chemical analysis [J]. Spectrochim Acta Part B, 2011, 6(2): 189-192.
[17] Perez-Tijerina E, Bohigas J, Machorro R. Density and temperature maps of an aluminium plasma produced by laser ablation [J]. Rev. Mex. Fis., 2005, 51: 153-156.
[19] Kodama K, Wagatsuma K. Excitation mechanism for nickel and argon lines emitted by radio-frequency glow discharge plasma associated with bias current introduction [J]. Spectrochim Acta Part B, 2004, 59(4): 429-434.
[20] Manrique J, Aguilera J A, Aragon C. Determination of transition probabilities by laser-induced breakdown spectroscopy with curve-of-growth measurements [J]. J. Quant. Spectro. Rad. Trans., 2011, 112: 85-91.
[21] Dittrich K, Wennrich R. Laser vaporization in atomic spectroscopy-review [J]. Prog. Analyt. Atom. Spectrosc., 1984, 7: 139-145.
[22] Andreic Z. Dynamics of aluminum plasma produced by a nitrogen laser [J]. Physica Scripta, 1993, 48: 331-336.
[24] Griem H R. Plasma Spectroscopy [M]. New York: McGraw Hill, 1964: 139-140.
[25] Lochte-Holtgreven W. Evalution of Plasma Parameter in Plasma Diagnostics [M]. North Holland Amsterdam, 1968: 156-157.
