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A novel shock tube with a laser–plasma driver

Published online by Cambridge University Press:  13 September 2017

Y. Kai*
Affiliation:
Hochschule Emden/Leer, University of Applied Sciences, Institute for Laser and Optics, Constantiaplatz 4, Emden 26723, Germany Carl von Ossietzky University of Oldenburg, Institute of Physics, Oldenburg 26111, Germany
W. Garen
Affiliation:
Hochschule Emden/Leer, University of Applied Sciences, Institute for Laser and Optics, Constantiaplatz 4, Emden 26723, Germany
T. Schlegel
Affiliation:
Hochschule Emden/Leer, University of Applied Sciences, Institute for Laser and Optics, Constantiaplatz 4, Emden 26723, Germany
U. Teubner
Affiliation:
Hochschule Emden/Leer, University of Applied Sciences, Institute for Laser and Optics, Constantiaplatz 4, Emden 26723, Germany Carl von Ossietzky University of Oldenburg, Institute of Physics, Oldenburg 26111, Germany
*
Address correspondence and reprint requests to: Y. Kai, Institute of Physics, Carl von Ossietzky University of Oldenburg, Oldenburg 26111, Germany. E-mail: [email protected]

Abstract

A novel method to generate shock waves in small tubes is demonstrated. A femtosecond laser is applied to generate an optical breakdown an aluminum film as target. Due to the sudden appearance of this non-equilibrium state of the target, a shock wave is induced. The shock wave is further driven by the expanding high-pressure plasma (up to 10 Mbar), which serves as a quasi-piston, until the plasma recombines. The shock wave then propagates further into a glass capillary (different square capillaries with hydraulic diameter D down to 50 µm are applied). Shock wave propagation is investigated by laser interferometry. Although the plasma is an unsteady driver, due to the geometrical confinement of the capillaries, rather strong micro shocks can still propagate as far as 35 times D. In addition to the experiments, the initial conditions of this novel method are investigated by hydrocode simulations using MULTI-fs.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2017 

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References

REFERENCES

Anderson, J.D. (2003). Modern Compressible Flow: With Historical Perspective, Vol. 12. New York: McGraw-Hill.Google Scholar
Austin, J. & Bodony, D. (2011). Wave propagation in gaseous small-scale channel flows. Shock Waves 21, 547.Google Scholar
Brouillette, M. (2003). Shock waves at microscales. Shock Waves 13, 312.Google Scholar
Caruso, A. & Gratton, R. (1969). Interaction of short laser pulses with solid materials. Plasma Phys. 11, 839.Google Scholar
Deshpande, A. & Puranik, B. (2017). A numerical investigation of shock propagation in three-dimensional microducts. Shock Waves 27, 565582.Google Scholar
Faik, S., Basko, M.M., Tauschwitz, A., Iosilevskiy, I. & Maruhn, J.A. (2012). Dynamics of volumetrically heated matter passing through the liquid–vapor metastable states. High Energy Density Phys. 8, 349359.Google Scholar
Garen, W., Meyerer, B., Udagawa, S. & Maeno, K. (2009). Shock waves in mini-tubes: influence of the scaling parameter S . Shock Waves, pp. 14731478.Google Scholar
Kai, Y., Garen, W. & Teubner, U. (2017). Generation and propagation of shock waves in submillimeter capillaries. In 30th International Symposium on Shock Waves 2, pp. 1201–1204. Springer.Google Scholar
Kemp, A. & Meyer-ter Vehn, J. (1998). An equation of state code for hot dense matter, based on the qeos description. Nucl. Instrum. Methods Phys. Res. A. 415, 674676.Google Scholar
Lyon, S. & Johnson, J. (1992). Los Alamos National Laboratory Report No. LA-UR-3407, Technical Report, Los Alamos National Laboratory.Google Scholar
Mirshekari, G. & Brouillette, M. (2009). One-dimensional model for microscale shock tube flow. Shock Waves 19, 2538.Google Scholar
Mirshekari, G. & Brouillette, M. (2012). Microscale shock tube. J. Microelectromech. Syst. 21, 739748.Google Scholar
Mirshekari, G., Brouillette, M., Giordano, J., Hébert, C., Parisse, J.-D. & Perrier, P. (2013). Shock waves in microchannels. J. Fluid Mech. 724, 259283.Google Scholar
Ngomo, D., Chaudhuri, A., Chinnayya, A. & Hadjadj, A. (2010). Numerical study of shock propagation and attenuation in narrow tubes including friction and heat losses. Comput. Fluids 39, 17111721.Google Scholar
online data bank (2016). Air Properties. (www.engineeringtoolbox.com).Google Scholar
Palik, E.D. (1998). Handbook of Optical Constants of Solids, Vol. 3. Orlando: Academic Press, Inc.Google Scholar
Ramis, R., Eidmann, K., Meyer-ter Vehn, J. & Hüller, S. (2012). Multi-fs–a computer code for laser–plasma interaction in the femtosecond regime. Comput. Phys. Commun. 183, 637655.Google Scholar
Reddy, K. & Sharath, N. (2013). Manually operated piston-driven shock tube. Curr. Sci. 104, 172176.Google Scholar
Sun, M., Ogawa, T. & Takayama, K. (2001). Shock propagation in narrow channels. ISSW23, Fort Worth, TX.Google Scholar
T4GROUP. (1983). SESAME Report on the Los Alamos Equation-of-State Library, Technical Report, No. LALP-83-4. Los Alamos, NM: Los Alamos National Laboratory.Google Scholar
Teubner, U., Kai, Y., Schlegel, T., Zeitoun, D. & Garen, W. (2017). Laser-plasma induced shock waves in micro shock tubes. New J. Phys., accepted.Google Scholar
Teubner, U., Wülker, C., Theobald, W. & Förster, E. (1995). X-ray spectra from high-intensity subpicosecond laser produced plasmas. Phys. Plasmas 2, 972981.Google Scholar
Udagawa, S., Garen, W., Meyerer, B. & Maeno, K. (2007). Interferometric detection of dispersed shock waves in small scale diaphragm-less shock tube of 1mm diameter. In 16th Australasian Fluid Mechanics Conference (AFMC), pp. 207–210. School of Engineering, The University of Queensland.Google Scholar
Vézina, G., Fortier-Topping, H., Bolduc-Teasdale, F., Rancourt, D., Picard, M., Plante, J.-S., Brouillette, M. & Fréchette, L. (2016). Design and experimental validation of a supersonic concentric micro gas turbine. J. Turbomach. 138, 021007.Google Scholar
Young, D.A. & Corey, E.M. (1995). A new global equation of state model for hot, dense matter. J. Appl. Phys. 78, 37483755.Google Scholar
Zeitoun, D. & Burtschell, Y. (2006). Navier–stokes computations in micro shock tubes. Shock Waves 15, 241246.Google Scholar