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 |
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Acoust Soc acoustic cavitation adiabatic air bubble ambient radius antinode argon argon bubble atoms Barber BP Bjerknes forces black body bremsstrahlung Brenner Brenner et al bubble collapse bubble dynamics bubble in water bubble oscillations bubble radius bubble wall calculated Casimir effect cavitation bubbles Chem collapsing bubble compression Crum curve density dissolved driving pressure effect electrons emitted energy equilibrium experimental Figure flash Frommhold Gaitan DF gas bubble Gompf heat Hilgenfeldt Hiller inside the bubble intensity ionization Lauterborn light emission liquid Löfstedt Lohse luminescence maximum measured Mie scattering molecular molecular dynamics molecules multibubble sonoluminescence observed parameters Pecha phase photon Phys Rev Lett Plesset pressure amplitude Prosperetti pulse Putterman SJ radiation Rayleigh Rayleigh–Plesset equation resonance SBSL shock wave shows single bubble sonoluminescence solution Sonochemistry sound field spectra spectrum spherical stable Storey and Szeri temperature theory thermal conductivity Ultrasonics velocity viscosity water vapor Weninger xenon Yasui