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/content/asa/journal/arlo/6/3/10.1121/1.1897810
1.
1.D.F. Gaitan, L.A. Crum, C.C. Church, and R.A. Roy, “Sonoluminescence and bubble dynamics for a single, stable, cavitation bubble,” J. Acoust. Soc. Am. 91, 31663183 (1992).
2.
2.B. Gompf, R. Günther, G. Nick, R. Pecha, and W. Eisenmenger, “Resolving sonoluminescence pulse width with time-correlated single photon counting,” Phys. Rev. Lett. 79, 14051408 (1997).
3.
3.R. Hiller, K. Weninger, S.J. Putterman, and B.P. Barber, “Effect of noble gas doping in single-bubble sonoluminescence,” Science 266, 248250 (1994).
4.
4.W.C. Moss, D.A. Young, J.A. Harte, J.L. Levatin, B.F. Rozsnyai, G.B. Zimmerman, and I.H. Zimmerman, “Computed optical emissions from a sonoluminescing bubble,” Phys. Rev. E 59, 29862992 (1999).
5.
5.S. Hilgenfeldt, S. Grossmann, and D. Lohse, “A simple explanation of light emission in sonoluminescence,” Nature (London) 398, 402405 (1999).
6.
6.C. Camara, S. Putterman, and E. Kirilov, “Sonoluminescence from a single bubble driven at 1 megahertz,” Phys. Rev. Lett. 92, 124301-1 (2004).
7.
7.D.J. Flannigan and K.S. Suslick, “Plasma formation and temperature measurement during single-bubble cavitation,” Nature (London) 434, 5255(2005).
8.
8.K. Weninger, R. Hiller, B.P. Barber, D. Lacoste, and S.J. Putterman, “Sonoluminescence from single bubbles in nonaqueous liquids: new parameter space for sonochemistry,” J. Phys. Chem. 99, 1419514197 (1995).
9.
9.Y.T. Didenko, W.B. McNamara III, and K.S. Suslick, “Molecular emission from single-bubble sonoluminescence,” Nature (London) 407, 877879 (2000).
10.
10.A. Chakravarty, T. Georghiou, T.E. Philipson, and A.J. Walton, “Stable sonoluminescence within a water hammer tube,” Phys. Rev. E 69, 066317-1 (2004).
11.
11.S.J. Putterman and K.R. Weninger, “Sonoluminescence: how bubbles turn sound into light,” Annu. Rev. Fluid Mech. 32, 445476 (2000).
12.
12.J.M. Ajello, D.L. Hansen, L.W. Beegle, C.A. Terrell, I. Kanik, G.K. James, and O.P. Makarov, “Middle ultraviolet and visible spectrum of by electron impact,” J. Geophys. Res. 107, JA000122 SIA2-1 (2002).
13.
13.R.S. Shappe, M.B. Schulman, F.A. Sharpton, and C.C. Lin, “Emission of the second-negative-band system produced by electron impact on Phys. Rev. A 38, 45374545 (1988).
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2016-12-05
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