Artículos de revistas
Generation of optical frequency combs via four-wave mixing processes for low- and medium-resolution astronomy
Fecha
2015-05Registro en:
Zajnulina, M.; Chavez Boggio, J. M.; Böhm, M.; Rieznik, Andrés Anibal; Fremberg, T.; et al.; Generation of optical frequency combs via four-wave mixing processes for low- and medium-resolution astronomy; Springer; Applied Physics B: Lasers and Optics; 120; 1; 5-2015; 171-184
0946-2171
CONICET Digital
CONICET
Autor
Zajnulina, M.
Chavez Boggio, J. M.
Böhm, M.
Rieznik, Andrés Anibal
Fremberg, T.
Haynes, R.
Roth, M. M.
Resumen
We investigate the generation of optical frequency combs through a cascade of four-wave mixing processes in nonlinear fibres with optimised parameters. The initial optical field consists of two continuous-wave lasers with frequency separation larger than 40 GHz (312.7 pm at 1531 nm). It propagates through three nonlinear fibres. The first fibre serves to pulse shape the initial sinusoidal-square pulse, while a strong pulse compression down to sub-100 fs takes place in the second fibre which is an amplifying erbium-doped fibre. The last stage is a low-dispersion highly nonlinear fibre where the frequency comb bandwidth is increased and the line intensity is equalised. We model this system using the generalised nonlinear Schrödinger equation and investigate it in terms of fibre lengths, fibre dispersion, laser frequency separation and input powers with the aim to minimise the frequency comb noise. With the support of the numerical results, a frequency comb is experimentally generated, first in the near infra-red and then it is frequency-doubled into the visible spectral range. Using a MUSE-type spectrograph, we evaluate the comb performance for astronomical wavelength calibration in terms of equidistancy of the comb lines and their stability.