Numerical simulations for performance optimization of a few-cycle terawatt NOPCPA system

Witte, Stefan; Zinkstok, R.T.; Hogervorst, W.; Eikema, K.S.E.

doi:10.1007/s00340-007-2640-8

Cited by 44 publications

(20 citation statements)

References 25 publications

(50 reference statements)

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“…Because parametric amplification influences the phase of the amplified light [61,62], a method is needed to detect a differential phase shift between the pulses. This shift is recorded for each laser shot by using spectral interferometry with the original comb pulses as a reference in a Mach-Zehnder configuration (Fig.…”

Section: Phase-shift Measurements In the Infraredmentioning

confidence: 99%

XUV frequency-comb metrology on the ground state of helium

et al. 2011

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The operation of a frequency comb at extreme ultraviolet (xuv) wavelengths based on pairwise amplification and nonlinear upconversion to the 15th harmonic of pulses from a frequency-comb laser in the near-infrared range is reported. It is experimentally demonstrated that the resulting spectrum at 51 nm is fully phase coherent and can be applied to precision metrology. The pulses are used in a scheme of direct-frequency-comb excitation of helium atoms from the ground state to the 1s4p and 1s5p 1 P 1 states. Laser ionization by auxiliary 1064 nm pulses is used to detect the excited-state population, resulting in a cosine-like signal as a function of the repetition rate of the frequency comb with a modulation contrast of up to 55%. Analysis of the visibility of this comb structure, thereby using the helium atom as a precision phase ruler, yields an estimated timing jitter between the two upconverted-comb laser pulses of 50 attoseconds, which is equivalent to a phase jitter of 0.38 (6) cycles in the xuv at 51 nm. This sets a quantitative figure of merit for the operation of the xuv comb and indicates that extension to even shorter wavelengths should be feasible. The helium metrology investigation results in transition frequencies of 5 740 806 993 (10) and 5 814 248 672 (6) MHz for excitation of the 1s4p and 1s5p 1 P 1 states, respectively. This constitutes an important frequency measurement in the xuv, attaining high accuracy in this windowless part of the electromagnetic spectrum. From the measured transition frequencies an eight-fold-improved 4 He ionization energy of 5 945 204 212 (6) MHz is derived. Also, a new value for the 4 He ground-state Lamb shift is found of 41 247 (6) MHz. This experimental value is in agreement with recent theoretical calculations up to order mα 6 and m 2 /Mα 5 , but with a six-times-higher precision, therewith providing a stringent test of quantum electrodynamics in bound two-electron systems.

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Section: Phase-shift Measurements In the Infraredmentioning

confidence: 99%

XUV frequency-comb metrology on the ground state of helium

et al. 2011

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“…2. Amplification in a BBO-based non-collinear optical parametric amplifier (NOPA) yields gain bandwidth as wide as 300 nm ranging from 700 to 1000 nm, enabling the amplification of few-cycle pulses [13]. Nevertheless, stretching and compressing pulses spanning over 300 nm of bandwidth requires compensating dispersion up to the fourth order.…”

Section: System Architecture and Challengesmentioning

confidence: 99%

Multi-kHz, multi-mJ, phase stabilized, OPCPA amplifier system

Hemmer

Vaupel

Webb

et al. 2010

Solid State Lasers XIX: Technology and Devices

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The pump beam generation line of an optical parametric chirped pulse amplifier (OPCPA) system providing few-cycle pulses with energy in the millijoule range at repetition rates up to 10 kHz is presented. The overall design of the system is briefly discussed including stretching-compressing and parametric amplification. The main emphasis is on the requirements on the pump beam for successful pumping of a parametric amplifier. Aspects of the design of the multistage hybrid amplifier line are detailed and performances of each stage are presented.

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“…Existing analytical solutions of the non-collinear optical parametric amplifier (NOPA) processes provide an accurate estimate of the gain bandwidth, but generally neglect dispersion and walk-off effects [18][19][20]. Numerical methods provide good estimates for the pulse energetics and closely reflect experimentally chosen parameters, such as, pulse energy, pulse duration, spectrum and phase [18,21]. Here, a 2D-model was developed with the z-axis along the signal propagation axis and one transverse direction (x-axis) formed in the plane between the signal and pump axes.…”

Section: Numerical Modeling and Materials Parametersmentioning

confidence: 99%

Design considerations for a high power, ultrabroadband optical parametric chirped-pulse amplifier

et al. 2014

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A conceptual design of a high power, ultrabroadband optical parametric chirped-pulse amplifier (OPCPA) was carried out comparing nonlinear crystals (LBO and BBO) for 810 nm centered, sub-7.0 fs pulses with energies above 1 mJ. These amplifiers are only possible with a parallel development of kilowatt-level OPCPA-pump amplifiers. It is therefore important to know good strategies to use the available OPCPA-pump energy efficiently. Numerical simulations, including self- and cross-phase modulation, were used to investigate the critical parameters to achieve sufficient spectral and spatial quality. At high output powers, thermal absorption in the nonlinear crystals starts to degrade the output beam quality. Strategies to minimize thermal effects and limits to the maximum average power are discussed.

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Numerical simulations for performance optimization of a few-cycle terawatt NOPCPA system

Cited by 44 publications

References 25 publications

XUV frequency-comb metrology on the ground state of helium

XUV frequency-comb metrology on the ground state of helium

Multi-kHz, multi-mJ, phase stabilized, OPCPA amplifier system

Design considerations for a high power, ultrabroadband optical parametric chirped-pulse amplifier

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