Oscillations, Waves, and Interactions - GWDG

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256 A. Vogel, I. Apitz, V. Venugopalan [86] L. I. Sedov, Similarity and Dimensional Methods in Mechanics (Academic Press, New York, 1959). [87] L. D. Landau and E. M. Lifschitz, Fluid Mechanics (Pergamon Press, Oxford, 1987), 2nd ed. [88] A. Sakurai, ‘On the propagation and structure of a blast wave, I’, J. Phys. Soc. Japan 8, 662 (1953). [89] A. Sakurai, ‘On the propagation and structure of a blast wave, II’, J. Phys. Soc. Japan 9, 256 (1954). [90] D. A. Freiwald and R. A. Axford, ‘Approximate spherical blast theory including source mass’, J. Appl. Phys. 46, 1171 (1975). [91] R. Kelly and B. Braren, ‘On the direct observation of the gas dynamics of laser-pulse sputtering of polymers. Part I: Analytical considerations’, Appl. Phys. B 53, 160 (1991). [92] R. Kelly and A. Miotello, ‘Pulsed-laser sputtering of atoms and molecules. Part I: Basic solutions for gas-dynamic effects’, Appl. Phys. B 57, 145 (1993). [93] P. E. Dyer and J. Sidhu, ‘Spectroscopic and fast photographic studies of excimer laser polymer ablation’, J. Appl. Phys. 64, 4657 (1988). [94] D. L. Jones, ‘Intermediate strength blast wave’, Phys. Fluids 11, 1664 (1968). [95] C. Stauter, P. Grard, J. Fontaine, and T. Engel, ‘Laser ablation acoustical monitoring’, Appl. Surf. Sci. 109/110, 174 (1997). [96] D. A. Freiwald, ‘Approximate blast wave theory and experimental data for shock trajectories in linear explosive-driven shock tubes’, J. Appl. Phys. 43, 2224 (1972). [97] C. E. Otis, B. Braren, M. O. Thompson, D. Brunco, and P. M. Goodwin, ‘Mechanisms of excimer laser ablation of strongly absorbing systems’, in Proc. SPIE vol. 1856 – Laser Radiation Photophysics, edited by B. Braren and M. N. Libenson (SPIE, Bellingham, 1993), pp. 132–142. [98] Z. Chen, A. Bogaerts, and A. Vertes, ‘Phase explosion in atmospheric pressure infrared laser ablation from water-rich targets’, Appl. Phys. Lett. 89 (2006). [99] K. Nahen and A. Vogel, ‘Shielding by the ablation plume during Er:YAG Laser ablation’, J. Biomed. Opt. 7, 165 (2002). [100] K. Nahen and A. Vogel, ‘Investigations on acoustic on-line monitoring of IR laser ablation of burned skin’, Lasers Surg. Med. 25, 69 (1999). [101] K. Nahen and A. Vogel, ‘Acoustic signal characteristics during IR laser ablation, and their consequences for acoustic tissue discrimination’, in Proc. SPIE vol. 3914 – Laser- Tissue Interaction XI: Photochemical, Photothermal, and Photomechanical, edited by D. D. Duncan, J. O. Hollinger D. D. S., and S. L. Jacques (SPIE, Bellingham, 2000), pp. 166–176. [102] A. Vogel, B. Kersten, and I. Apitz, ‘Material ejection in free-running Er:YAG laser ablation of water, liver and skin by phase explosion, confined boiling, recoil-induced expulsion and flow-induced suction’, in Proc. SPIE vol. 4961 – Laser-Tissue Interaction XIV, edited by S. L. Jacques, D. D. Duncan, S. J. Kirkpatrick, and A. Kriete (SPIE, Bellingham, 2003), pp. 40–47. [103] R. Hibst, Technik, Wirkungsweise und medizinische Anwendungen von Holmium- und Erbium-Lasern (Ecomed, Landsberg, 1996). [104] C. A. Puliafito, D. Stern, R. R. Krueger, and E. R. Mandel, ‘High-speed photography of excimer laser ablation of the cornea’, Arch. Ophthalmol. 105, 1255 (1987). [105] D. Bäuerle, Laser Processing and Chemistry (Springer, Berlin, 2000). [106] J. P. Cummings and J. T. Walsh, ‘Tissue tearing caused by pulsed laser-induced ablation pressure’, Appl. Opt. 32, 494 (1993). [107] C. R. Phipps, R. F. Harrison, T. Shimada, G. W. York, T. P. Turner, X. F. Corlis,
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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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204 W. Eisenmenger and U. Kaatze Fi
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Page 290 and 291: 280 Schreiber not moving along with
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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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368 U. Kaatze and R. Behrends with
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370 U. Kaatze and R. Behrends Figur
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386 U. Kaatze and R. Behrends of th
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398 U. Kaatze and R. Behrends [6] M
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400 U. Kaatze and R. Behrends [49]
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402 U. Kaatze and R. Behrends (2002
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404 U. Kaatze and R. Behrends Copyr
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406 U. Parlitz here chaos control m
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408 U. Parlitz Figure 2. Amplitude
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410 U. Parlitz 4 10 5 5 (a) (b) (c)
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412 U. Parlitz two-parameter studie
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414 U. Parlitz GN differential opti
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416 U. Parlitz P 1 P 2 P 3 S P 1 P
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418 U. Parlitz Figure 9. Correlatio
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420 U. Parlitz series” where for
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422 U. Parlitz current state future
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424 U. Parlitz tion [69] of two uni
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426 U. Parlitz LD1 LD2 M BS1 BS2 OD
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428 U. Parlitz with a clear tendenc
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430 U. Parlitz (a) y (c) y 40 20 È
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432 U. Parlitz [29] P. Grassberger,
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434 U. Parlitz [76] H. D. I. Abarba
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436 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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