2016
DOI: 10.1364/optica.3.000366
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High-harmonic generation at 250  MHz with photon energies exceeding 100  eV

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Cited by 87 publications
(69 citation statements)
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“…The problems of thermal lensing, mirror damage and resonator stability were addressed in [12,16,27], identifying ways of progressively scaling the intracavity power. Thanks to these results, a state-of-the-art experiment demonstrated a enhancement-cavity-based 250 MHz HHG source reaching photon energies in excess of 100 eV and a photon flux of´-9 10 photons s 1 in a 2% bandwidth around 94 eV [13], which indicates that intracavity HHG has come to a point where it is potentially useful for ultrafast photoelectron spectroscopy and microscopy experiments. For this, 30 fs pulses at 1040 nm with a pulse energy of m 0.7 J were power-enhanced a factor of 60 and focused down to m = · ( ) w w 13.4 m x y 0, 0, 2 , reaching peak intensities around -3 10 W cm 14 2 in a 200 mm long neon gas target with an atomic density of n 5 std placed 0.5 Rayleigh ranges before the focus, where n std is the atomic density of an ideal gas at IUPAC standard temperature and pressure and w x 0, and w y 0, are the beam waists in x and y direction.…”
Section: State Of the Art Of Hhg In Femtosecond Ecsmentioning
confidence: 86%
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“…The problems of thermal lensing, mirror damage and resonator stability were addressed in [12,16,27], identifying ways of progressively scaling the intracavity power. Thanks to these results, a state-of-the-art experiment demonstrated a enhancement-cavity-based 250 MHz HHG source reaching photon energies in excess of 100 eV and a photon flux of´-9 10 photons s 1 in a 2% bandwidth around 94 eV [13], which indicates that intracavity HHG has come to a point where it is potentially useful for ultrafast photoelectron spectroscopy and microscopy experiments. For this, 30 fs pulses at 1040 nm with a pulse energy of m 0.7 J were power-enhanced a factor of 60 and focused down to m = · ( ) w w 13.4 m x y 0, 0, 2 , reaching peak intensities around -3 10 W cm 14 2 in a 200 mm long neon gas target with an atomic density of n 5 std placed 0.5 Rayleigh ranges before the focus, where n std is the atomic density of an ideal gas at IUPAC standard temperature and pressure and w x 0, and w y 0, are the beam waists in x and y direction.…”
Section: State Of the Art Of Hhg In Femtosecond Ecsmentioning
confidence: 86%
“…Coherently stacking the pulses of a high-repetition-rate modelocked laser inside of a passive optical resonator, or enhancement cavity (EC), provides a convenient way to combine peak intensities on the order of -10 W cm 14 2 necessary for HHG in a gas target with pulse repetition rates of several (tens of) MHz [10,11]. With the advent of Yb-based lasers, ECs have enabled reaching these intensities at the highest repetition rates so far, providing ultrashort pulses with the highest average powers ever demonstrated [12], and allowing for HHG with photon energies exceeding 100 eV at repetition rates as high as 250 MHz [13]. Just a few years ago, femtosecond ECs have been used for the first frequency comb spectroscopy experiments in the vacuum ultraviolet spectral region [14,15].…”
Section: Introductionmentioning
confidence: 99%
“…For instance, the zero-offset-frequency pulse train can be used to drive HHG in a suitable femtosecond enhancement cavity [16,17] for the generation of attosecond pulse trains and, ultimately, for the generation of isolated attosecond pulses at multi-MHz repetition rates [18]. This will dramatically decrease the measurement times in photoelectron emission microscopy and spectroscopy, in particular allowing for the study of plasmonic fields with a unique combination of nm-scale spatial resolution with sub-femtosecond temporal resolution [20].…”
Section: Discussionmentioning
confidence: 99%
“…This will dramatically decrease the measurement times in photoelectron emission microscopy and spectroscopy, in particular allowing for the study of plasmonic fields with a unique combination of nm-scale spatial resolution with sub-femtosecond temporal resolution [20]. Furthermore, the adjustable repetition rate allows for direct studies of cumulative effects such as those observed in HHG in gases at high repetition rates [16]. Another application which will tremendously profit from this MOPA is field-resolved detection of broadband infrared pulses [21], employing the 7-fs pulses generated by the Ti:Sa oscillator for electro-optical sampling with a lock-in detection at half the fundamental oscillator repetition rate [22].…”
Section: Discussionmentioning
confidence: 99%
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