High-resolution Interferometric Diagnostics for Ultrashort Pulses

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References[1] Rakov, V. & Uman, M. Lightning: physics and effects. Cambridge Univ Pr (2003). 6[2] Shah, J. Ultrafast spectroscopy of semiconductors and semiconductor nanostructures.Springer Verlag (1999). 7[3] Jimenez, R., Fleming, G. R., Kumar, P. V., & Maroncelli, M. Nature 369, 471 (1994). 7[4] Zewail, A. H. J. Phys. Chem. A 104, 5660 (2000). 7[5] Mukamel, S. Principles of nonlinear optical spectroscopy. Ox<strong>for</strong>d University Press, New York(1995). 7[6] Dantus, M. Annu. Rev. Phys. Chem. 52, 639 (2001). 7[7] Warren, W., Rabitz, H., & Dahleh, M. Science 259, 1581 (1993). 7, 11, 64[8] Bonadeo, N., Erland, J., Gammon, D., Park, D., Katzer, D., & Steel, D. Science 282, 1473 (1998).7, 11[9] Zipfel, W., Williams, R., & Webb, W. Nat. Biotechnol. 21, 1369 (2003). 7[10] Xu, C., Zipfel, W., Shear, J. B., Williams, R. M., & Webb, W. W. Proc. Natl. Acad. Sci. U. S. A. 93,10763 (1996). 7[11] Gattass, R. R. & Mazur, E. Nat. Photon. 2, 219 (2008). 7[12] Ye, J. & Cundiff, S. Femtosecond optical frequency comb technology: Principle, operation andapplication. Springer Verlag (2005). 8[13] Udem, T., Holzwarth, R., & Haensch, T. Nature 416, 233 (2002). 8[14] Holzwarth, R., Udem, T., Hansch, T. W., Knight, J. C., Wadsworth, W. J., & Russell, P. St. J..Phys. Rev. Lett. 85, 2264 (2000). 8[15] Bradley, D. & New, G. Proc. IEEE 62, 313 (1974). 8[16] Korobkin, V. V., Malyutin, A. A., & Shchelev, M. Y. Sov. Phys. JETP 11, 103 (1970). 8[17] Bradley, D. J., Liddy, B., & Sleat, W. E. Opt. Commun. 2, 391 (1971). 8[18] Bradley, D., Liddy, B., Roddie, A., Sibbett, W., & Sleat, W. In Photo-Electronic Image Devices,Proceedings of the Fifth Symposium Held at Imperial College, vol. 33, Part 2 of Advances inElectronics and Electron Physics, pages 1145 – 1156. Academic Press (1972). 9[19] Ruddock, I. S. & Bradley, D. J. Appl. Phys. Lett. 29, 296 (1976). 9[20] Armstrong, J. A. Appl. Phys. Lett. 10, 16 (1967). 9, 32[21] Weber, H. P. J. Appl. Phys. 39, 6041 (1968). 9[22] Haus, H. IEEE J. Quantum. Elect. 11, 736 (1975). 9[23] Wise, F., Walmsley, I., & Tang, C. Opt. Lett. 13, 129 (1988). 9[24] Treacy, E. B. Phys. Lett. A 28, 34 (1968). 9[25] Treacy, E. B. Appl. Phys. Lett. 14, 112 (1969). 9, 34[26] Cubeddu, R. & Svelto, O. IEEE J. Quantum. Elect. 5, 495 (1969). 9[27] Svelto, O. Appl. Phys. Lett. 17, 83 (1970). 9[28] Ippen, E. P. & Shank, C. V. Appl. Phys. Lett. 27, 488 (1975). 9[29] Fork, R. L., Greene, B. I., & Shank, C. V. Appl. Phys. Lett. 38, 671 (1981). 9[30] Fork, R., Shank, C., Yen, R., & Hirlimann, C. IEEE J. Quantum. Elect. 19, 500 (1983). 9[31] Dietel, W., Döpel, E., Kühlke, D., & Wilhelmi, B. Opt. Commun. 43, 433 (1982). 10[32] Mourou, G. & II, T. S. Opt. Commun. 41, 47 (1982). 10[33] Dietel, W., Fontaine, J. J., & Diels, J.-C. Opt. Lett. 8, 4 (1983). 10229
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High-resolution InterferometricDiag
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AcknowledgementsMy supervisor Ian W
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6 High-harmonic generation 1256.1 D
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List of acronymsADK Ammosov, Delone
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Definitions and symbolsAll Fourier
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1. INTRODUCTIONprofile in space as
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2 BackgroundThis dissertation prese
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2.1 Metrology, ultrashort pulses, a
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2.1 Metrology, ultrashort pulses, a
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2.2 Formal introduction to ultrasho
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2.3 Introduction to ultrashort puls
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2.4 Extending ultrashort metrology
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3 Phase reconstruction algorithm fo
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3.1 Motivationration of information
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3.2 Quantitative noise analysis for
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3.3 Nature of the input datato give
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3.4 Sampling and uniqueness of solu
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3.5 Main algorithmfrom all the shea
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3.5 Main algorithmsituation, Γ k ,
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3.5 Main algorithmfor j = 1,2,...,k
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3.6 Implications for the relative p
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3.7 Signal-to-noise ratio cost of a
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3.8 Signal-to-noise ratio benefit o
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3.9 Numerical comparison of single-
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3.10 Summary, critical evaluation,
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4 Experimental implementations of m
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4.1 Sequential acquisition of shear
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4.1 Sequential acquisition of shear
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4.2 Simultaneous acquisition of she
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5 Compact Space-time SPIDERIn this
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5.2 Role of the measurement planetr
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5.3 Analysis of ST-SPIDERof design
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5.4 A common-path re-imaging ST-SPI
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5.5 Experimental exampleRomero [295
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5.6 Effect of miscalibrationy (pix)
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5.7 Summary and outlooknow perform
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6. HIGH-HARMONIC GENERATIONcurrent
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6. HIGH-HARMONIC GENERATIONcomponen
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6. HIGH-HARMONIC GENERATION00−I p
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6. HIGH-HARMONIC GENERATION (t ) (E
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6. HIGH-HARMONIC GENERATIONstationa
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6. HIGH-HARMONIC GENERATION10080log
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6. HIGH-HARMONIC GENERATIONwhere re
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6. HIGH-HARMONIC GENERATION• Sadd
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6. HIGH-HARMONIC GENERATIONgiven in
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6. HIGH-HARMONIC GENERATIONderivati
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6. HIGH-HARMONIC GENERATIONPhase ma
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6. HIGH-HARMONIC GENERATION30(S31)2
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6. HIGH-HARMONIC GENERATIONwhere W
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6. HIGH-HARMONIC GENERATIONtheir re
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6. HIGH-HARMONIC GENERATIONsmall pi
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7. LATERAL SHEARING INTERFEROMETRY
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Page 248 and 249: REFERENCESFrancis (1990). 51[220] B
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High-resolution Interferometric Diagnostics for Ultrashort Pulses

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