Oscillations, Waves, and Interactions - GWDG

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398 U. Kaatze and R. Behrends [6] M. A. Anisimov, Critical Phenomena in Liquids and Liquid Crystals (Gordon and Breach, Philadelphia, 1991). [7] C. Domb, The Critical Point: A Historical Introduction to the Modern Theory of Critical Phenomena (Taylor and Francis, London, 1996). [8] A. Onuki, Phase Transition Dynamics (Cambridge University Press, Cambridge, 2002). [9] L. M. Brown, Renormalization (Springer, Berlin, 1993). [10] M. E. Fisher, ‘Renormalization Group Theory: Its Basis and Formulation in Statistical Physics’, Rev. Mod. Phys. 70, 653 (1998). [11] H. E. Stanley, ‘Scaling, Universility, and Renormalization: Three Pillars of Modern Critical Phenomena’, Rev. Mod. Phys. 71, S358 (1999). [12] J. Israelachvili, Intermolecular and Surface Forces (Academic, New York, 1992). [13] W. M. Gelbart, A. Ben-Shaul, and D. Roux (Eds.), Micelles, Membranes, Microemulsions, and Monolayers (Springer, Berlin, 1994). [14] B. Jonsson, B. Lindman, K. Holmberg, and B. Kronberg, Surfactants and Polymers in Aqueous Solution (Wiley, Chichester, 1998). [15] T. Telgmann and U. Kaatze, ‘Monomer Exchange and Concentration Fluctuations in Poly(ethylene glycol)Monoalkyl Ether/Water Mixtures. Toward a Uniform Description of Acoustical Spectra’, Langmuir 18, 3068 (2002). [16] E. Hanke, T. Telgmann, and U. Kaatze, ‘Monomer Exchange Kinetics, Dynamics of Concentration Fluctuations, and Chain Isomerization of Nonionic Surfactant/Water Systems. Evidence From Broadband Ultrasonic Spectra’, Tenside Surf. Det. 41, 23 (2005). [17] J. Haller, R. Behrends, and U. Kaatze, ‘Critical Fluctuations of Micellar Triethylene Glycol Monoheptyl Ether-Water System’, J. Chem. Phys. 124, 124910 (2006). [18] G. Kurtze and K. Tamm, ‘Measurements of Sound Absorption in Water and in Aqueous Solutions of Electrolytes’, Acustica 3, 33 (1953). [19] M. Eigen and K. Tamm, ‘Schallabsorption in Elektrolytlösungen als Folge chemischer Relaxation I. Relaxationstheorie der mehrstufigen Dissoziation’, Z. Elektrochem. Ber. Bunsenges. Phys. Chem. 66, 93 (1962). [20] M. Eigen and K. Tamm, ‘Schallabsorption in Elektrolytlösungen als Folge chemischer Relaxation II. Meßergebnisse und Relaxationsmechanismen für 2-2-wertige Elektrolyte’, Z. Elektrochem. Ber. Bunsenges. Phys. Chem. 66, 107 (1962). [21] K. G. Plaß, ‘Relaxation in organischen Flüssigkeiten’, Acustica 19, 236 (1967/68). [22] F. Bader and K. G. Plaß, ‘Sound Absorption in Liquid Acetic Acid in the Frequency Range between 0.3 and 1.5 GHz’, Ber. Bunsenges. Physik. Chem. 75, 553 (1971). [23] F. Eggers, ‘Eine Resonanzmethode zur Bestimmung von Schallgeschwindigkeit und Dämpfung an geringen Flüssigkeitsmengen’, Acustica 19, 323 (1967/68). [24] A. B. Bhatia, Ultrasonic Absorption (Oxford University Press, Oxford, 1967). [25] E. Hanke and U. Kaatze, ‘Structural Aspects and Molecular Dynamics of Liquid Polymers, Including Mixtures with Water’, J.Phys. IV France 129, 29 (2005). [26] E. Hanke, Struktureigenschaften und molekulare Dynamik flüssiger Ethylenglykol- Oligomere und ihrer Mischungen mit Wasser, Dissertation, Georg-August-Universität Göttingen (2007). [27] P. E. Rouse Jr., ‘A Theory of the Linear Viscoelastic Properties of Dilute Solutions of Coiling Polymers’, J. Chem. Phys. 21, 1272 (1953). [28] B. Zimm, ‘Dynamics of Polymer Molecules in Dilute Solutions: Viscoelasticity, Flow Birefringence and Dielectric Loss’, J. Chem. Phys. 24, 269 (1956). [29] A. V. Tobolsky and J. J. Aklonis, ‘A Molecular Theory for Viscoelastic Behavior of Amorphous Polymers’, J. Chem. Phys. 68, 1970 (1964).
Liquids: Formation of complexes and complex dynamics 399 [30] A. V. Tobolsky and D. B. DuPré, ‘Macromolecular Relaxation in the Damped Torsional Oscillator and Statistical Segment Models’, Adv. Polym. Sci. 6, 103 (1969). [31] R. Behrends and U. Kaatze, ‘Structural Isomerizaion and Molecular Motions of Liquid n-Alkanes. Ultrasonic and High-Frequency Shear Viscosity Relaxation’, J. Phys. Chem. A 104, 3269 (2000). [32] R. Behrends and U. Kaatze, ‘Hydrogen Bonding and Chain Conformational Isomerization of Alcohols Probed by Ultrasonic Absorption and Shear Impedance Spectrometry’, J. Phys. Chem. A 105, 5829 (2001). [33] R. Behrends and U. Kaatze, ‘A High Frequency Shear Wave Impedance Spectrometer for Low Viscosity Liquids’, Meas. Sci. Technol. 12, 519 (2001). [34] P. Debye, Polar Molecules (Chemical Catalog Co., New York, 1929). [35] R. Polacek and U. Kaatze, ‘A Small Volume Spherical Resonator Method for the Acoustical Spctrometry of Liquids Down to Audio Frequencies’, Meas. Sci. Technol. 12, 1 (2001). [36] U. Kaatze, B. Wehrmann, and R. Pottel, ‘Acoustical Absorption Spectroscopy of Liquids Between 0.15 and 3000 MHz: I. High Resolution Ultrasonic Resonator Method’, J. Phys. E: Sci. Instrum. 20, 1025 (1987). [37] F. Eggers, U. Kaatze, K. H. Richmann, and T. Telgmann, ‘New Plano-Concave Ultrasonic Resonator Cells for Absorption and Velocity Measurements in Liquids Below 1 MHz’, Meas. Sci. Technol. 5, 1131 (1994). [38] R. Behrends, F. Eggers, U. Kaatze, and T. Telgmann, T., ‘Ultrasonic Spectrometry of Liquids Below 1 MHz. Biconcave Resonator Cell with Adjustable Radius of Curvature’, Ultrasonics 34, 59 (1996). [39] R. Polacek and U. Kaatze, ‘A High-Q-Easy-to-Handle Biconcave Resonator for Acoustic Spectrometry of Liquids’, Meas. Sci. Techn. 14, 1068 (2003). [40] U. Kaatze, K. Lautscham, and M. Brai, ‘Acoustical Absorption Spectroscopy of Liquids Between 0.15 and 3000 MHz: II. Ultrasonic Pulse Transmission Methods’, J. Phys. E: Sci. Instrum. 21, 98 (1988). [41] U. Kaatze, V. Kühnel, K. Menzel, and S. Schwerdtfeger, ‘Ultrasonic Spectroscopy of Liquids. Extending the Frequency Range of the Variable Sample Length Pulse Technique’, Meas. Sci. Techn. 4, 1257 (1993). [42] U. Kaatze, V. Kühnel, and G. Weiss, ‘Variable Pathlength Cells for Precise Hypersonic Spectrometry of Liquids up to 5 GHz’, Ultrasonics 34, 51 (1994). [43] F. Eggers and U. Kaatze, ‘Broad-Band Ultrasonic Measurement Techniques for Liquids’, Meas. Sci. Technol. 7, 1 (1996). [44] R. Polacek, J. Stenger, and U. Kaatze, ‘Chair-Chair Conformational Flexibility, Pseudorotation, and Exocyclic Group Isomerization of Monosaccharides in Water’, J. Chem. Phys. 116, 2973 (2002). [45] U. Kaatze and B. Wehrmann, ‘Broadband Ultrsonic Spectroscopy of Aqueous Solutions of Zinc(II)Chloride :I. Kinetics of Complexation’, Z. Phys. Chem (Munich) 177, 9 (1992). [46] E. Baucke, R. Behrends, K. Fuchs, R. Hagen, and U. Kaatze, ‘Kinetics of Ca 2+ Complexation with Some Carbohydrates in Aqueous Solutions’, J. Chem. Phys. 120, 8118 (2004). [47] M. Cowman, F. Eggers, E. M. Eyring, D. Horoszewski, U. Kaatze, R. Kreitner, S. Petrucci, M. Klöppel-Riech, and J. Stenger, ‘Microsecond to Subnanosecond Molecular Relaxation Dynamics of the Interaction of Ca 2+ with Some Carbohydrates in Aqueous Solutions’, J. Phys. Chem. B 103, 239 (1999). [48] R. Behrends and U. Kaatze, ‘Molecular Dynamics and Conformational Kinetics of Mono- and Disaccharides in Aqueous Solution’, ChemPhysChem 6, 1133 (2005).
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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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448 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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