SonoluminescenceCRC Press, 2004 M08 30 - 250 pages While it is still a mystery of how a low-energy-density sound wave can concentrate enough energy in a small enough volume to cause the emission of light, research in acoustic cavitation and sonoluminescence has lead to plausible theories in which the source of light can be experimentally sustained. It has also lead to promising applications, such a |
Contents
Introduction | 1 |
Multibubble Sonoluminescence | 27 |
Single Bubble Sonoluminescence | 67 |
Theories of Sonoluminescence | 149 |
Conclusions | 207 |
Appendix | 217 |
| 219 | |
| 223 | |
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Common terms and phrases
acoustic ambient amplitude argon atoms Barber bremsstrahlung Brenner et al bubble dynamics bubble wall calculated cavitation Chem collapse compression concentration considered constant Crum curve cycle density dependence diffusion dissolved driving dynamics effect electron emission emitted energy equation equilibrium experimental experiments field Figure flash Fluid force frequency function Gaitan gases given heat Hilgenfeldt increased inside instability intensity ionization JAcoust Soc light light emission liquid Lohse luminescence maximum measured mechanism motion multibubble observed obtained occurs oscillations parameter particles phase photon Phys Rev Lett Physics pressure produced Prosperetti pulse Putterman SJ radiation radius reactions resonance SBSL scattering shape shock wave shown shows single bubble sonoluminescence solution sonoluminescing bubble sound sound field spectra spectrum spherical stable surface surface tension Suslick Szeri temperature theoretical theory thermal Ultrasonics values volume Weninger Yasui Young
References to this book
Advances in Heat Transfer, Volume 39 George A. Greene,Young I. Cho,James P. Hartnett,Avram Bar-Cohen Limited preview - 2006 |