2016
DOI: 10.1364/oe.24.005253
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Non-planar femtosecond enhancement cavity for VUV frequency comb applications

Abstract: External passive femtosecond enhancement cavities (fsECs) are widely used to increase the efficiency of non-linear conversion processes like high harmonic generation (HHG) at high repetition rates. Their performance is often limited by beam ellipticity, caused by oblique incidence on spherical focusing mirrors. We introduce a novel three-dimensionally folded variant of the typical planar bow-tie resonator geometry that guarantees circular beam profiles, maintains linear polarization, and allows for a significa… Show more

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Cited by 12 publications
(6 citation statements)
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“…In solids, harmonics can be generated at much lower laser intensities than in gases, promising the extension of HHG into very compact laser sources and with very high repetition rates, reaching even GHz frequencies. Such high repetition rates would be very beneficial for time-resolved spectroscopic applications, and VUV or EUV frequency combs [5][6][7] could also be realized in solids for high precision metrology. Consequently, HHG in solids is being extensively explored both experimentally and theoretically.…”
Section: Introductionmentioning
confidence: 99%
“…In solids, harmonics can be generated at much lower laser intensities than in gases, promising the extension of HHG into very compact laser sources and with very high repetition rates, reaching even GHz frequencies. Such high repetition rates would be very beneficial for time-resolved spectroscopic applications, and VUV or EUV frequency combs [5][6][7] could also be realized in solids for high precision metrology. Consequently, HHG in solids is being extensively explored both experimentally and theoretically.…”
Section: Introductionmentioning
confidence: 99%
“…The achievable precision would be determined by the bandwidth of the laser light used for excitation, which is ≈ 10 GHz (40 µeV). An alternative approach is based on a VUV frequency comb generated from the 5th harmonic of a Ti:Sapphire laser and is under development at TU Vienna [324,408]. A system that operates with the 7th harmonic of an Yb:doped fiber laser is located at JILA, Boulder, CO [406,418].…”
Section: Population Via Direct Excitationmentioning
confidence: 99%
“…We performed calculation series for sapphire alone (band gap E g = 8.7 eV, reduced effective mass of electron-hole pairs m* = 0.3, and lattice constant a = 0.476 nm) and for AlN (E g = 6.3 eV, m* = 0.4, and a = 0.310 nm). For AlN, the transition dipole moment at the band gap was estimated from the known absorption coefficient α = 3×10 5 cm -1 , and the effective density of states at the CB edge N c = 6.2×10 18 Cm. No estimation of the dipole moment could be performed for sapphire.…”
Section: Bandgap Tuning: Using Aln Film As Mhg Sourcementioning
confidence: 99%
“…To reach short wavelengths at high repetition rates, non-perturbative highharmonic generation is currently the only candidate. Such high-harmonic sources were successfully realized by adding an enhancement cavity to fiber laser systems or Ti:sapphire oscillators [13][14][15][16][17][18]. In these realizations, different noble gases were used for non-perturbative frequency conversion, which relies on the ionization of the gases and hence requires suitably high (> 10 13 W/cm 2 ) laser peak intensity.…”
Section: Introductionmentioning
confidence: 99%