Abstract
Liquids are less compressible than gases. The compressibility is the measure of volume change when compressed by pressure.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Abe, A. (1989). Study of diffraction of shock wave released from the open end of a shock tube (Ph.D. thesis). Graduate School of Engineering, Faculty of Engineering Tohoku University.
Abe, A., Ohtani, K., Takayama, K., Nishio, S., Mimura, H., & Takeda, M. (2010). Pressure generation from micro-bubble collapse at shock wave loading. Journal of Fluid Science and Technology, 5, 235–246.
Chaussey, Ch., Schmiedt, E., Jocham, D., Walter,V., Brendel, W., Forsmann, B., & Hepp, W. (1982). Extracorporeal shock wave lithotripsy. New aspects in the treatment of kidney stone disease. Kerger.
Coleburn, N. L., & Roslund, L. A. (1970). Interaction of spherical shock waves in water. In Proceedings of 15th International Symposium on Detonation, Pasadena (pp. 581–588).
Esashi, H. (1983). Shock wave propagation in liquids (Master thesis). Graduate School of Engineering, Faculty of Engineering, Tohoku University.
Glass, I. I., & Heuckroth, L. E. (1968). Low-energy spherical underwater explosions. Physics of Fluids, 11, 2095–2107.
Hayakawa, S. (1987). Study of shock/bubble interaction in highly viscous liquids (Master thesis). Graduate School of Engineering, Faculty of Engineering Tohoku University.
Hirano, T. (2001) Development of revascularization of cerebral thrombosis using laser induced liquid jets (M.D. thesis). Graduate School of Medicine, Tohoku University.
Ikeda, K., Matsuda, M., Tomita, K., & Takayama, K. (1999). Application of extracorporeal shock wave on bone. Basic and clinical study. In G. J. Ball, R. Hillier, & G. T. Robertz (Eds.), Proceedings of 22nd ISSW, Shock Waves, London (Vol. 1, pp. 623–626).
International Maritime Organization. Science of ship and the sea. Retrieved from http://www.imo/org/home.asp.
Kikuchi, T. (2011). A shock dynamic study of high-speed impact onto condensed matter (Ph.D. thesis). Graduate School of Engineering, Faculty of Engineering Tohoku University.
Kuwahara, M., Kambe, K., Kurosu, S., Orikasa, S., & Takayama, K. (1986). Extracorporeal stone disintegration using chemical explosive pellets as an energy source of underwater shock waves. Journal of Urology., 135, 814–817.
Nagayasu, N. (2002). Study of shock waves generated by micro explosion and their applications (Ph.D. thesis). Graduate School of Engineering, Faculty of Engineering, Tohoku University.
Ohtani, K., & Takayama, K. (2010) Shock wave interaction phenomena with a single helium gas bubble in liquid. In 7th International Conference on Flow Dynamics, Sendai (pp. 120–121).
Okazaki, K. (1989). Fundamental study in extracorporeal shock wave lithotripsy using piezoceramics. Japanese Journal of Applied Physics, 28, 143–145.
Sachs, R. G. (1944). The dependence of blast on ambient pressure and temperature (BRL Report, No. 466).
Saeki, T. (1993). Super-cavitation flows of a high speed projectile launched by two-stage light gas gun (Master thesis). Graduate School of Engineering, Faculty of Engineering, Tohoku University.
Sanada, N., Ikeuchi, J., Takayama, K., & Onodera, O. (1983). Generation and propagation of cavitation induced shock waves in an ultrasonic vibration testing. In: D. Archer & B. E. Milton (Eds.), Proceedings of 14th International Symposium on Shock Tubes and Waves, Sydney (pp. 404–412).
Shima, A. (1997). Studies on bubble dynamics. Shock Waves, 7, 33–42.
Shitamori, K. (1990). Study of propagation and focusing of underwater shock focusing (Master thesis). Graduate School of Tohoku University Faculty of Engineering, Tohoku University.
Tait, P. G. (1888). Report on physical properties of flesh and of sea water. Physics and Chemistry Challenger Expedition, IV, 1–78.
Takayama, K. (1983). Application of holographic interferometry to shock wave research. In International Symposium of Industrial Application of Holographic Interferometry, Proceedings of SPIE (Vol. 298, pp. 174–181).
Takayama, K. (1987). Holographic interferometric study of shock wave propagation in two phase media, In H. Groenig (Ed.), Proceedings of 16th International Symposium on Shock Tubes and Waves, Aachen (pp. 51–62).
Takayama, K. (1990). High pressure generation by shock wave focusing in a confined ellipsoidal cavity. In K. Takayama (Ed.), Proceedings of International Workshop on Shock Wave Focusing (pp. 217–226). Institute of High Speed Mechanics, Sendai.
Takayama, K., Yamamoto, H., & Abe, A. (2015). Underwater-shock/bubble interaction and its application to biology and medicine. In R. Bonazza, D. Ranjan (Eds.), Proceedings of 29th ISSW, Shock Waves, Madison (Vol. 2, 861–868).
Yamada, K. (1992). Study of shock wave interaction with gas bubbles in various liquids (Doctoral thesis). Graduate School of Tohoku University Faculty of Engineering, Tohoku University.
Yutkin, L. A. (1950). Apparat YRAT-1 Medeport USSR Moscow.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
Copyright information
© 2019 Springer Nature Switzerland AG
About this chapter
Cite this chapter
Takayama, K. (2019). Underwater Shock Waves. In: Visualization of Shock Wave Phenomena. Springer, Cham. https://doi.org/10.1007/978-3-030-19451-2_9
Download citation
DOI: https://doi.org/10.1007/978-3-030-19451-2_9
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-030-19450-5
Online ISBN: 978-3-030-19451-2
eBook Packages: EngineeringEngineering (R0)