Ozawa A. Frequency combs in the extreme ultraviolet. - Garching: Max-Planck-Institut für Quantenoptik, 2010. - vi, 152 p.: ill. - (Berichte / Max-Planck-Institut für Quantenoptik (München); MPQ 327). - Bibliogr.: p.141-152.  Место хранения:   02 | Отделение ГПНТБ СО РАН | Новосибирск

Оглавление / Contents

1 Introduction ................................................. 9 1.1 Short pulses and frequency combs ........................ 9 1.2 Short pulses in dispersive materials ................... 13 1.3 Generation of frequency combs .......................... 13 1.4 Measurement of carrier envelope offset frequency ....... 15 1.5 Applications of frequency combs ........................ 17 1.5.1 A frequency reference for high precision spectroscopy .................................... 17 1.5.2 Direct excitation with frequency comb ........... 23 1.6 High precision spectroscopy of He+ ..................... 24 1.7 Frequency conversion into the ultraviolet region ....... 29 2 XUV frequency comb generation with a femtosecond enhancement cavity .......................................... 31 2.1 Introduction ........................................... 31 2.2 High harmonic generation (HHG) ......................... 32 2.2.1 Single atom response of HHG: perturbative regime .......................................... 32 2.2.2 Single atom response of HHG: non-perturbative regime .......................................... 33 2.2.3 Single atom response of HHG: numerical simulations ..................................... 40 2.2.4 Other important remarks of high harmonic generation ...................................... 41 2.3 Femtosecond enhancement cavity ......................... 43 2.3.1 Femtosecond and continuous wave optical cavities ........................................ 43 2.3.2 A basic model of a femtosecond cavity ........... 46 2.3.3 The effect of intracavity dispersion ............ 57 2.4 Experiments and results ................................ 59 2.4.1 Positively chirped oscillator at 10 MHz repetition rate ................................. 59 2.4.2 Enhancement cavity .............................. 60 2.4.3 Locking of the cavity ........................... 61 2.4.4 Dispersion management of enhancement cavity ..... 65 2.4.5 High precision intracavity dispersion measurement ..................................... 68 2.4.6 Designing chirped mirrors for high precision dispersion compensation ......................... 73 2.4.7 Dispersion compensated broadband enhancement cavity .......................................... 78 2.4.8 Intracavity high harmonic generation ............ 80 2.5 Conclusion ............................................. 85 3 Non-collinear high harmonic generation (NCHHG) .............. 87 3.1 Introduction ........................................... 87 3.1.1 Current outcoupling methods ..................... 87 3.1.2 New outcoupling methods ......................... 89 3.1.3 Previous demonstrations of non-collinear high harmonic generation ............................. 94 3.1.4 A simple picture of non-collinear high harmonic generation ............................. 95 3.2 Experimental ........................................... 97 3.3 Discussion of results .................................. 98 3.3.1 NCHHG beam profiles ............................. 98 3.3.2 Estimation of outcoupling efficiency ........... 100 3.3.3 Systematic investigation of NCHHG .............. 101 3.4 Numerical Simulation .................................. 103 3.4.1 Discussion of results .......................... 107 3.5 Conclusions ........................................... 113 3.6 Future prospects ...................................... 114 4 High repetition rate cryogenic amplifier for femtosecond laser pulses ............................................... 117 4.1 Introduction .......................................... 117 4.1.1 Mode-locked oscillator with high average power .......................................... 117 4.1.2 High repetition rate amplifier ................. 121 4.2 Experiments and discussions ........................... 122 4.2.1 Cryogenic Amplifier: setup ..................... 122 4.2.2 Cryogenic Amplifier: Amplification results ..... 123 4.2.3 Cryogenic Amplifier: Spectrum and pulse duration ....................................... 124 4.2.4 Cryogenic Amplifier: White light generation in a bulk crystal .............................. 127 4.2.5 Cryogenic Amplifier: Phase noise of the carrier-envelope offset frequency after amplification .................................. 127 4.2.6 Cryogenic Amplifier: Amplification of 200fs pulses ......................................... 129 4.2.7 Peltier cooled amplifier ....................... 129 4.2.8 Beam profiles .................................. 131 4.3 Conclusions ........................................... 132 4.4 Future prospects ...................................... 133 4.4.1 Multi pass amplifier ........................... 133 4.4.2 High power oscillator combined with high repetition rate amplifier ...................... 134 4.4.3 Heat dissipation in the enhancement cavity ..... 135 4.4.4 Coupling to the cavity ......................... 135 5 Future Prospects ........................................... 137 5.1 Ytterbium-based systems ............................... 137 5.2 Cavity-assisted high harmonic generation at shorter fundamental wavelengths ............................... 138 5.3 Cavity-assisted high harmonic generation at extremely high repetition rates ....................... 139 5.4 Other applications of femtosecond enhancement cavities .............................................. 139