Oscillations, Waves, and Interactions - GWDG

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402 U. Kaatze and R. Behrends (2002). [91] V. P. Romanov and V. A. Solov’ev, ‘Sound Absorption in Solutions’, Sov. Phys. Acoust. 11, 68 (1965). [92] V. P. Romanov and S. V. Ul’yanov, ‘Bulk Viscosity in Relaxing Media’, Phys. A 201, 527 (1993). [93] V. P. Romanov and V. A. Solov’ev, ‘Relaxation of the Ion Atmospheres and Sound Absorption in Electrolytes’, Sov. Phys. Acoust. 19, 550 (1974). [94] C. J. Montrose and T. A. Litovitz, ‘Structural-Relaxation Dynamics in Liquids’, J. Acoust. Soc. Am. 47, 1250 (1970). [95] H. Endo, ‘Sound Absorption Mechanism of an Aqueous Solution in Nonelectrolyte’, J. Chem. Phys. 92, 1986 (1990). [96] K. Kawasaki, ‘Kinetic Equations and Time Correlation Functions of Critical Fluctuations’, Ann. Phys. (N. Y.) 61, 1 (1970). [97] J. K. Bhattacharjee and R. A. Ferrell, ‘Dynamic Scaling Theory for the Critical Ultrasonic Attenuation in a Binary Liquid’, Phys. Rev. A 24, 1643 (1981). [98] R. A. Ferrell and J. K. Bhattacharjee, ‘General Dynamic Scaling Theory of Critical Ultrasonic Attenuation and Dispersion’, Phys. Lett. A 86, 109 (1981). [99] R. A. Ferrell and J. K. Bhattacharjee, ‘Dynamic Scaling Theory of the Critical Attenuation and Dispersion of Sound in a Classical Fluid: The Binary Liquid’, Phys. Rev. A 31, 1788 (1985). [100] J. K. Bhattacharjee and R. A. Ferrell, ‘Universality in the Critical Dynamics of Fluids: Ultrasonic Attenuation’, Physica A 250, 83 (1998). [101] R. Folk and G. Moser, ‘Frequency-Dependent Shear Viscosity, Sound Velocity, and Sound Attenuation Near the Critical Point in Liquids. I. Theoretical Results’, Phys. Rev. E 57, 683 (1998). [102] R. Folk and G. Moser, ‘Critical Dynamics in Mixtures’, Phys. Rev. E 58, 6246 (1998). [103] R. Folk and G. Moser, ‘Nonasymptotic Transport Properties in Fluids and Mixtures Near a Critical Point’, Intern. J. Thermophys. 19, 1003 (1998). [104] R. Folk and G. Moser, ‘Critical Sound in Fluids and Mixtures’, Condens. Matter. Phys. 2, 243 (1999). [105] A. Onuki, ‘Dynamic Equations and Bulk Viscosity Near the Gas-Liquid Critical Point’, Phys. Rev. E 55, 403 (1997). [106] A. Onuki, ‘Bulk Viscosity Near the Critical Point’, J. Phys. Soc. Jpn. 66, 511 (1997). [107] R. Behrends and U. Kaatze, ‘Scaling Frequency in the Critical Sound Attenuation of Binary Liquids’, Europhys. Lett. 65, 221 (2004). [108] R. Behrends, U. Kaatze, and M. Schach, ‘Scaling Function of the Critical Binary Mixture Methanol-Cyclohexane’, J. Chem. Phys. 119, 7957 (2003). [109] I. Iwanowski, R. Behrends, and U. Kaatze, ‘Critical Fluctuations Near the Consolute Point of n-Pentanol-Nitroethane. An Ultrasonic Spectrometry, Dynamic Light Scattering, and Shear Viscosity Study’, J. Chem. Phys. 120, 9192 (2004). [110] R. Behrends, I. Iwanowski, M. Kosmowska, A. Szala, and U. Kaatze, ‘Sound Attenuation, Shear Viscosity, and Mutual Diffusivity Behavior in the Nitroethane- Cyclohexane Critical Mixture’, J. Chem. Phys. 121, 5929 (2004). [111] I. Iwanowski, K. Leluk, M. Rudowski, and U. Kaatze, ‘Critical Dynamics of the Binary System Nitroethane/3-Methylpentane: Relaxation Rate and Scaling Function’, J. Phys. Chem. A 110 4313 (2006). [112] I. Iwanowski, A. Sattarow, R. Behrends, S. Z. Mirzaev, and U. Kaatze, ‘Dynamic Scaling of the Critical Mixture Methanol-Hexane’, J. Chem. Phys. 124, 144505 (2006). [113] S. Z. Mirzaev, I. Iwanowski, and U. Kaatze, ‘Dymanic Scaling and Background Relaxation in the Ultrasonic Spectra of the Ethanol-Dodecane Critical Mixture’, Chem.
Liquids: Formation of complexes and complex dynamics 403 Phys. Lett. 435, 263 (2007). [114] S. Z. Mirzaev, I. Iwanowski, and U. Kaatze, ‘Dynamic Scaling of the Critical Mixture Perfluoromethylcyclohexane Carbon Tetrachloride’, J. Phys. D: Appl. Phys. 40, 3248 (2007). [115] H. C. Burstyn, J. V. Sengers, J. K. Bhattacharjee, and R. A. Ferrell, ‘Dynamic Scaling Function for Critical Fluctuations in Classical FLuids’, Phys. Rev. A 28, 1567 (1983). [116] J. K. Bhattacharjee, R. A. Ferrell, R. S. Basu, and J. V. Sengers, ‘Crossover Function for the Critical Viscosity of a Classical Fluid’, Phys. Rev. A 24, 1469 (1981). [117] J. C. Nienwouldt and J. V. Sengers, ‘A Reevaluation of the Viscosity Exponent for Binary Mixtures Near the Consolute Point’, J. Chem. Phys. 90, 457 (1989). [118] J. Luettmer-Strathmann, J. V. Sengers, and G. A. Olchowy, ‘Non-Asymptotic Critical Behavior of the Transport Properties of Fluids’, J. Chem. Phys. 103, 7482 (1995). [119] K. Kawasaki, ‘Sound Attenuation and Dispersion Near the Gas-Liquid Point’, Phys. Rev. A. 1, 1750 (1970). [120] A. Stein, J. C. Allegra, and G. F. Allen, ‘Shear Viscosity of 3-Methylpentane- Nitroethane Near the Critical Point’, J. Chem. Phys. 55, 4265 (1971). [121] C. W. Garland and G. Sanchez, ‘Ultrasonic Study of Critical Behavior in the Binary Liquid 3-Methylpentane+Nitroethane’, J. Chem. Phys. 79, 3090 (1983). [122] U. Kaatze and S. Z. Mirzaev, ‘Slowing Down in Chemical Reactions. The Isobutyric Acid/Water System in the Critical Region’, J. Phys. Chem. A 104, 5430 (2000). [123] S. Z. Mirzaev and U. Kaatze, ‘Dynamic Scaling in the Ultrasonic Attenuation Spectra of Critical Binary Mixtures’, Chem. Phys. Lett. 328, 277 (2000). [124] R. Behrends, T. Telgmann, and U. Kaatze, ‘The Binary System Triethylamine-Water Near its Critical Consolute Point: An Ultrasonic Spectrometry, Dynamic Light Scattering, and Shear Viscosity Study’, J. Chem. Phys. 117, 9828 (2002). [125] S. Z. Mirzaev, R. Behrends, T. Heimburg, J. Haller, and U. Kaatze, ‘Critical Behavior of 2,6-Dimethylpyridine-Water: Measurements of Specific Heat, Dynamic Light Scattering, and Shear Viscosity’, J. Chem. Phys. 124, 144517 (2006). [126] S. Z. Mirzaev, I. Iwanowski, M. Zaitdinov, and U. Kaatze, ‘Critical Dynamics and Kinetics of Elementary Reactions of 2,6-Dimethylpyridine-Water’, Chem. Phys. Lett. 431, 308 (2006). [127] I. Iwanowski and U. Kaatze, ‘Dynamic Scaling and Slowing Down in Chemical Reactions of the Critical Triethylamine-Water System’, J. Phys. Chem. B 111, 1438 (2007). [128] T. Telgmann and U. Kaatze, ‘Monomer Exchange and Concentration Fluctuations in Poly(ethylene glycol) Monoalkyl Ether/Water Mixtures. Dependence upon Nonionic Surfactant Composition’, J. Phys. Chem. A 104, 4846 (2000). [129] K. Menzel, S. Z. Mirzaev, and U. Kaatze, ‘Crossover Behavior in Micellar Solutions with Critical Demixing Point: Broadband Ultrasonic Spectrometry of the Isobutoxyethanol-Water System’, Phys. Rev. E 68, 011501 (2003). [130] U. Kaatze, ‘Elementary Kinetics and Microdynamics of Aqueous Surfactants Systems’, Uzbek. J. Phys. 5, 75 (2003). [131] I. Iwanowski, S. Z. Mirzaev, and U. Kaatze, ‘Relaxation Rate in the Critical Dynamics of the Micellar Isobutoxyethanol-Water Sytem with Lower Consolute Point’, Phys. Rev. E 73, 061508 (2006). [132] I. Procaccia and M. Gittermann, ‘Slowing Down Chemical Reactions Near Thermodynamic Critical Points’, Phys. Rev. Lett. 46, 1163 (1981). [133] H. G. E. Hentschel and I. Procaccia, ‘Sound Attenuation in Critically Slowed-Down Chemically Reactive Mixtures’, J. Chem. Phys. 76, 666 (1982).
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Thomas Kurz, Ulrich Parlitz, and Ud
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erschienen im Universitätsverlag G
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Bibliographische Information der De
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iv Contents Laser speckle metrology
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Oscillations, Waves and Interaction
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Applied physics at the “Dritte”
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noise component [GNE] 5 4 3 2 1 can
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3.4 Transfer to running speech Spee
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3.4.2 Analysis of running speech Sp
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Speech research 33 Area [Pixels] 60
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Speech research 35 [13] D. Michaeli
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Specific signal types in hearing re
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74 D. Ronneberger et al. Mechel fou
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76 D. Ronneberger et al. (flow velo
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78 D. Ronneberger et al. |t + acous
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80 D. Ronneberger et al. Figure 6.
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82 D. Ronneberger et al. Figure 8.
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84 D. Ronneberger et al. (flow velo
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86 D. Ronneberger et al. R / L ⋅
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88 D. Ronneberger et al. e. g. temp
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90 D. Ronneberger et al. 3.2 Qualit
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92 D. Ronneberger et al. As usual t
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94 D. Ronneberger et al. (wavenumbe
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96 D. Ronneberger et al. powers of
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98 D. Ronneberger et al. an increas
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100 D. Ronneberger et al. The term
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102 D. Ronneberger et al. Neverthel
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104 D. Ronneberger et al. [4] J. Br
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106 D. Ronneberger et al. strömung
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108 D. Guicking synchronised tuning
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110 D. Guicking primary noise micro
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112 D. Guicking primary sensor desi
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114 D. Guicking by an antiphase sou
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116 D. Guicking R L C C + + 1 1−C
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118 D. Guicking More involved than
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120 D. Guicking In the 1980s, longi
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122 D. Guicking with electrodynamic
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124 D. Guicking 3.6 Noise reduction
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126 D. Guicking the turbulence of a
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128 D. Guicking References [1] Lord
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130 D. Guicking [44] Falcke, H.,
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132 D. Guicking [84] J. Melcher,
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134 D. Guicking [125] D. Heyland et
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136 D. Guicking [166] S. Zommer et
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138 D. Guicking [212] M. L. Post an
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140 W. Lauterborn et al. liquid κ
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142 W. Lauterborn et al. Figure 2.
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144 W. Lauterborn et al. nator, and
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146 W. Lauterborn et al. by types a
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148 W. Lauterborn et al. bubble rad
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154 W. Lauterborn et al. P koll [kb
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156 W. Lauterborn et al. Pulse widt
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158 W. Lauterborn et al. laser puls
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168 W. Lauterborn et al. R [µ m] 1
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170 W. Lauterborn et al. [17] M. P.
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172 R. Mettin (a) (b) Figure 1. Bub
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174 R. Mettin 0 ms 2 mm 1 ms 2 ms 3
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176 R. Mettin important quantity ch
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178 R. Mettin 100 kPa 200 kPa | | F
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180 R. Mettin Figure 7. Trapped sin
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182 R. Mettin concentration of spec
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184 R. Mettin which is called the p
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186 R. Mettin R 02 [µm] R 02 [µm]
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188 R. Mettin constant to M a = 2π
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190 R. Mettin (a) p a [Pa] 140 120
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192 R. Mettin z [mm] 5 4 3 2 1 0 -1
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194 R. Mettin Figure 17. Left: Expe
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196 R. Mettin - a hot microlaborato
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198 R. Mettin [52] R. Mettin, C.-D.
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200 W. Eisenmenger and U. Kaatze Th
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202 W. Eisenmenger and U. Kaatze Fi
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214 W. Eisenmenger and U. Kaatze 6
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216 W. Eisenmenger and U. Kaatze Pr
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218 A. Vogel, I. Apitz, V. Venugopa
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260 K. D. Hinsch Generally, any of
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262 K. D. Hinsch Figure 1. Monitori
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264 K. D. Hinsch Figure 3. ESPI stu
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266 K. D. Hinsch Figure 4. Deterior
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268 K. D. Hinsch Often, in-plane mo
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270 K. D. Hinsch Figure 7. Optical
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272 K. D. Hinsch Figure 9. Humidity
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274 K. D. Hinsch locations that tak
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276 K. D. Hinsch Figure 13. Map of
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278 K. D. Hinsch References [1] D.
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280 Schreiber not moving along with
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282 Schreiber These properties made
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284 Schreiber Figure 3. The G ring
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286 Schreiber Rotation Rate [rad/s]
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288 Schreiber and it is currently b
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290 Schreiber n1 D A B n Figure 8.
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292 Schreiber Beamwalk [µm] 80.0 7
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294 Schreiber ∆ Perimeter [*10e12
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296 Schreiber and the last term acc
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298 Schreiber Δf [µHz] 100 50 0 -
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300 Schreiber formation of a new wo
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302 Schreiber PSD [*10 16 (rad/s) 2
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304 Schreiber 7.2 The ring laser co
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306 Schreiber Demodulator Signal [V
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308 Schreiber Est. Phase Vel. (m/s)
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310 Schreiber [18] V. Frede and V.
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312 Martin Dressel tice is reduced
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314 Martin Dressel Metallic whisker
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316 Martin Dressel (a) (b) (c) CH 3
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318 Martin Dressel 3.1 Charge densi
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320 Martin Dressel Absorptivity σ
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322 Martin Dressel brought a confir
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324 Martin Dressel a charge disprop
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326 Martin Dressel Conductivity 70
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328 Martin Dressel Reflectivity Con
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330 Martin Dressel References [1] M
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332 Martin Dressel and L. Montgomer
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334 R. Pottel, J. Haller and U. Kaa
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452 S. Lakämper and C. F. Schmidt
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462 Index basin of attraction, 144
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464 Index cone bubble structure, 19
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466 Index turbulent, 111, 126 fluct
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468 Index LPC, 29 luminescence of b
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470 Index peak factor, 38, 43 Peier
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472 Index laser-induced bubble, 152
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474 Index ultraharmonic resonance,
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