Multi-octave supercontinuum generation in As2Se3 chalcogenide photonic crystal fiber
Authors: Lanh Chu Van, Thuy Nguyen Thi, Bao Tran Le Tran, Duc Hoang Trong, Ngoc Vo Thi Minh, Hieu Van Le, Van Thuy Hoang
Photonics and Nanostructures - Fundamentals and Applications
: 48 : 100986
Publishing year: 1/2022
We numerically calculated multi-octave spanning supercontinuum generation (SCG) in two proposed As2Se3
photonic crystal fibers (PCFs) with low input peak powers and highly coherent characteristics with the effects of
vacuum noise and pulse-to-pulse relative intensity noise. The first PCF with a lattice constant (Λ) of 1.5 μm and
core diameter (dcore) of 5.48 μm has the flat all-normal dispersion in the wavelength range of 2–10 μm. For the
input peak power of 5 kW, this fiber generates the all-normal dispersion SCG with a spectral bandwidth of
1.85–5.7 μm with pump wavelength at 3.5 μm, and two octave-spanning of 1.9–7.6 μm with pump wavelength at
5.5 μm. The second PCF with Λ of 1.52 μm and dcore of 7.3 μm has flat dispersion and two zero-dispersion
wavelengths at 4.3 μm and 7.8 μm. By launching the input peak power of 7.5 kW, and pump wavelength at
3.5 μm, the second PCF generates the broad SCG with a spectral bandwidth of 2–10 μm. The SCG in two proposed
PCFs has high coherence due to the effects of vacuum noise. However, the results of our works point out that
pulse-to-pulse relative intensity noise significantly decreases the coherence. The amount of coherence reduction
depends on the pulse duration and the physical mechanism for spectral broadening in which a part of the
supercontinuum spectrum induced by optical wave breaking and dispersive wave experiences a remarkable
reduction of coherence due to the effects of pulse-to-pulse relative intensity noise.
Photonic crystal fiber Supercontinuum generation Dispersion Nonlinear optics Coherence