43 research outputs found
Coherent beam superposition of ten diode lasers with a Dammann grating
We demonstrate the use of a binary diffractive optical element in a very simple setup to convert the multilobed beam from a low fill factor array of coherent laser diodes into a quasi-Gaussian beam. The phase profile of the grating is determined with a phase retrieval algorithm. Experimentally, the conversion efficiency reaches more than 44%. We also establish that this setup can be used to make an effective measurement of the coherency of the laser array
Frequency comb offset dynamics of SESAM modelocked thin disk lasers
We present a detailed study of the carrier-envelope offset (CEO) frequency dynamics of SESAM modelocked thin disk lasers (TDLs) pumped by kW-class highly transverse multimode pump diodes with a typical M2 value of 200-300, and give guidelines for future frequency stabilization of multi-100-W oscillators. We demonstrate CEO frequency detection with > 30 dB signal-to-noise ratio with a resolution bandwidth of 100 kHz from a SESAM modelocked Yb:YAG TDL delivering 140 W average output power with 748-fs pulses at 7-MHz pulse repetition rate. We compare with a low-power CEO frequency stabilized Yb:CALGO TDL delivering 2.1 W with 77-fs pulses at 65 MHz. For both lasers, we perform a complete noise characterization, measure the relevant transfer functions (TFs) and compare them to theoretical models. The measured TFs are used to determine the propagation of the pump noise step-by-step through the system components. From the noise propagation analysis, we identify the relative intensity noise (RIN) of the pump diode as the main contribution to the CEO frequency noise. The resulting noise levels are not excessive and do not prevent CEO frequency stabilization. More importantly, the laser cavity dynamics are shown to play an essential role in the CEO frequency dynamics. The cavity TFs of the two lasers are very different which explains why at this point a tight CEO frequency lock can be obtained with the Yb:CALGO TDL but not with the Yb:YAG TDL. For CEO stabilization laser cavities should exhibit high damping of the relaxation oscillations by nonlinear intra-cavity elements, for example by operating a SESAM in the roll-over regime. Therefore the optimum SESAM operation point is a tradeoff between enough damping and avoiding multiple pulsing instabilities. Additional cavity components could be considered for supplementary damping independent of the SESAM operation point
Transport Coefficients from Large Deviation Functions
We describe a method for computing transport coefficients from the direct
evaluation of large deviation function. This method is general, relying on only
equilibrium fluctuations, and is statistically efficient, employing trajectory
based importance sampling. Equilibrium fluctuations of molecular currents are
characterized by their large deviation functions, which is a scaled cumulant
generating function analogous to the free energy. A diffusion Monte Carlo
algorithm is used to evaluate the large deviation functions, from which
arbitrary transport coefficients are derivable. We find significant statistical
improvement over traditional Green-Kubo based calculations. The systematic and
statistical errors of this method are analyzed in the context of specific
transport coefficient calculations, including the shear viscosity, interfacial
friction coefficient, and thermal conductivity.Comment: 11 pages, 5 figure
Efficient Spectral Broadening in the 100-W Average Power Regime Using Gas Filled Kagome HC-PCF and Pulse Compression
We present nonlinear pulse compression of a high-power SESAM-modelocked
thin-disk laser (TDL) using an Ar-filled hypocycloid-core Kagome Hollow-Core
Photonic Crystal Fiber (HC-PCF). The output of the modelocked Yb:YAG TDL with
127 W average power, a pulse repetition rate of 7 MHz, and a pulse duration of
740 fs was spectrally broadened 16-fold while propagating in a Kagome HC-PCF
containing 13 bar of static Argon gas. Subsequent compression tests performed
using 8.4% of the full available power resulted in a pulse duration as short as
88 fs using the spectrally broadened output from the fiber. Compressing the
full transmitted power through the fiber (118 W) could lead to a compressed
output of >100 W of average power and >100 MW of peak power with an average
power compression efficiency of 88%. This simple laser system with only one
ultrafast laser oscillator and a simple single-pass fiber pulse compressor,
generating both high peak power >100 MW and sub-100-fs pulses at megahertz
repetition rate, is very interesting for many applications such as high
harmonic generation and attosecond science with improved signal-to-noise
performance