Oscillations, Waves, and Interactions - GWDG

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330 Martin Dressel References [1] Mathematical Physics in One Dimension, edited by E. H. Lieb and D. C. Mattis (Academic Press, New York, 1966). [2] T. Giamarchi, Quantum Physics in One Dimension (Oxford University Press, Oxford, 2004); M. Dressel, ‘Spin-charge separation in quasi one-dimensional organic conductors’, Naturwissenschaften 90, 337 (2003). [3] H. Moritz, T. Stöferle, M. Köhl, and T. Esslinger, ‘Exciting collective oscillations in a trapped 1D gas’, Phys. Rev. Lett. 91, 250402 (2003). [4] J. H. Davies, The Physics of Low-Dimensional Semiconductors (Cambridge University Press, Cambridge, 1998). [5] F. J. Himpsel, A. Kirakosian, J. N. Crain, J.-L. Lin, und D. Y. Petrovykh, ‘Self-assembly of one-dimensional nanostructures at silicon surfaces’, Solid State Commun. 117, 149 (2001). [6] M. Dressel and H.-W. Helberg, ‘AC conductivity of deformed germanium single crystals at T = 4.2 K’, phys. stat. sol. (a) 96, K199 (1986); M. Brohl, M. Dressel, H.-W. Helberg, and H. Alexander, ‘Microwave conductivity investigations in plastically deformed silicon’, Phil. Mag. B 61, 97 (1990). [7] H. Alexander and H. Teichler, ‘Dislocations’, in Handbook of Semiconductor Technology, Vol. 1, edited by K. A. Jackson and W. Schröter (Wiley-VCH, New York, 2000), p. 291. [8] M. O’Connell, Carbon Nanotubes (Taylor & Francis, Boca Raton, 2006); P. J. F. Harris, Carbon Nanotubes and Related Structures (Cambridge University Press, Cambridge, 2004); S. Reich, C. Thomsen, and J. Maultzsch, Carbon Nanotubes (Wiley-VCH, Weinheim, 2004). [9] P. Brüesch, ‘Optical Properties of the One-Dimensional Pt Complex Compounds’, in One-Dimensional Conductors, edited by H. G. Schuster (Springer-Verlag, Berlin, 1975), p. 194; P. Brüesch, S. Strässler, and H. R. Zeller, ‘Fluctuations and order in a one-dimensional system. A spectroscopical study of the Peierls transition in K2Pt(CN)4Br0.3·3(H2O)’, Phys. Rev. B 12, 219 (1975). [10] P. Monceau (Ed.), Electronic Properties of Inorganic Quasi-One-Dimensional Compounds, Part I/II (Reidel, Dordrecht, 1985); C. Schlenker, J. Dumas, M. Greenblatt, and S. Van Smalen (Eds.), Physics and Chemistry of Low Dimensional Inorganic Conductors (Plenum, New York, 1996). [11] P. A. Cox, Transition Metal Oxides (Clarendon Press, Oxford, 1992); S. Maekawa, T. Tohyama, S. E. Barnes, S. Ishihara, W. Koshibae, and G. Khaliullin, The Physics of Transition Metal Oxides (Springer, Berlin, 2004). [12] D. Jérome and H. J. Schulz, ‘Organic conductors and superconductors’, Adv. Phys. 31, 299 (1982); D. Jérome, in Organic Conductors, edited by J.-P. Farges (Marcel Dekker, New York, 1994), p. 405; M. Dressel, ‘Spin-charge separation in quasi one-dimensional organic conductors’, Naturwissenschaften 90, 337 (2003); M. Dressel, ‘Ordering phenomena in quasi one-dimensional organic conductors’, Naturwissenschaften 94, DOI 10.1007/s00114-007-0227-1 (2007). [13] D. Jérome, A. Mazaud, M. Ribault, and K. Bechgaard, ‘Superconductivity in a synthetic organic conductor (TMTSF)2PF6’, J. Physique Lett. 41, L95 (1980). [14] J. Goldstone, ‘Field theories with “superconductor” solution’, Nuovo cimento 19, 154 (1961); J. Goldstone, A. Salam, and S. Weinberg, ‘Broken symmetries’, Phys. Rev. 127, 965 (1962). [15] G. Grüner, Density Waves in Solids (Addison-Wesley, Reading, MA, 1994). [16] M. Dressel and G. Grüner, Electrodynamics of Solids (Cambridge University Press, Cambridge, 2002).
Charge order in one-dimensional solids 331 [17] O. Klein, S. Donovan, M. Dressel, and G. Grüner, ‘Microwave cavity perturbation technique. Part I: Principles’, Int. J. Infrared and Millimeter Waves 14, 2423 (1993); S. Donovan, O. Klein, M. Dressel, K. Holczer, and G. Grüner, ‘Microwave cavity perturbation technique. Part II: Experimental scheme’, Int. J. Infrared and Millimeter Waves 14, 2459 (1993); M. Dressel, S. Donovan, O. Klein, and G. Grüner, ‘Microwave cavity perturbation technique. Part III: Applications’, Int. J. Infrared and Millimeter Waves 14, 2489 (1993); A. Schwartz, M. Dressel, A. Blank, T. Csiba, G. Grüner, A. A Volkov, B. P. Gorshunov, and G. V. Kozlov, ‘Resonant techniques for studying the complex electrodynamic response of conducting solids in the millimeter and submillimeter wave spectral range’, Rev. Sci. Instrum. 66, 2943 (1995); M. Dressel, O. Klein, S. Donovan, and G. Grüner, ‘High frequency resonant techniques for the study of the complex electrodynamic response in solids’, Ferroelectrics 176, 285 (1996). [18] H.-W. Helberg and B. Wartenberg, ‘Zur Messung der Stoffkonstanten ɛ und µ im GHz- Bereich mit Resonatoren’, Z. Angew. Phys. 20, 505 (1966). The tradition goes back to the Institut für Angewandte Elektrizität (Institute of Applied Electricity) founded in the beginning of the 20th century and headed by Max Reich for a long time. Students like Arthur von Hippel spread this knowledge all around the world and made highfrequency investigations of solids to a powerful tool. The foundation of the Laboratory of Insulation Research and the Radiation Laboratory at MIT during World War II certainly had the largest impact. [19] L. I. Buranov and I. F. Shchegolev, ‘Method of measuring conductivity of small crystals at a frequency of 10 10 Hz’, Prib. Tekh. Eksp. (engl.) 14, 528 (1971); I. F. Shchegolev, ‘Electric and magnetic properties of linear conducting chains’, phys. stat. sol. (a) 12, 9 (1972); H.-W. Helberg and M. Dressel, ‘Investigations of organic conductors by the Schegolev method’, J. Phys. I. (France) 6, 1683 (1996). [20] B. P. Gorshunov, A. A Volkov, G. V. Kozlov, L. Degiorgi, A. Blank, T. Csiba, M. Dressel, Y. Kim, A. Schwartz, and G. Grüner, ‘Charge density wave paraconductivity in K0.3MoO3’, Phys. Rev. Lett. 73, 308 (1994); A. Schwartz, M. Dressel, B. Alavi, A. Blank, S. Dubois, G. Grüner, B. P. Gorshunov, A. A. Volkov, G. V. Kozlov, S. Thieme, L. Degiorgi, and F. Lévy, ‘Fluctuation effects on the electrodynamics of quasi onedimensional conductors above the charge-density-wave transition’, Phys. Rev. B 52, 5643 (1995). [21] A. V. Pronin, M. Dressel, A. Loidl, H. S. J. van der Zant, O. C. Mantel, and C. Dekker, ‘Optical investiations of the collective transport in CDW-films’, Physica B 244, 103 (1998). [22] G. Kozlov and A. Volkov, ‘Coherent Source Submillimeter Wave Spectroscopy’, in Millimeter and Submillimeter Wave Spectroscopy of Solids, edited by G. Grüner (Springer, Berlin, 1998), p. 51; B. Gorshunov, A. Volkov, I. Spektor, A. Prokhorov, A. Mukhin, M. Dressel, S. Uchida, and A. Loidl, ‘Terahertz BWO-spectrosopy’, Int. J. of Infrared and Millimeter Waves, 26, 1217 (2005). [23] K. Bender, K. Dietz, H. Endres, H.-W. Helberg, I. Hennig, H. J. Keller, H. W. Schäfer, and D. Schweitzer, ‘(BEDT-TTF) 2+ J − 3 - A two-dimensional organic metal’, Mol. Cryst. Liq. Cryst. 107, 45 (1984); M. Dressel, G. Grüner, J. P. Pouget, A. Breining, and D. Schweitzer, ‘Field- and frequency dependent transport in the two-dimensional organic conductor α-(BEDT-TTF)2I3’ J. de Phys. I (France) 4, 579 (1994). [24] M. Dressel and N. Drichko, ‘Optical properties of two-dimensional organic conductors: signatures of charge ordering and correlation effects’, Chem. Rev. 104, 5689 (2004); M. Dressel, ‘Ordering phenomena in quasi one-dimensional organic conductors’, Naturwissenschaften 94, DOI 10.1007/s00114-007-0227-1 (2007). [25] M. Dressel, S. Kirchner, P. Hesse, G. Untereiner, M. Dumm, J. Hemberger, A. Loidl,
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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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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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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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148 W. Lauterborn et al. bubble rad
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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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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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272 K. D. Hinsch Figure 9. Humidity
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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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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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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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