Abstract
Resonant dispersive-wave (RDW) emission from solitons in gas-filled hollow-core fibres is an established tech-nique for generating tunable ultraviolet (UV) pulses [1,2]. During soliton self-compression of the pump pulse along the fibre, its spectrum broadens until it overlaps with phase-matched wavelengths in the normal dispersion region, allowing an efficient transfer of energy to a linearly propagating RDW. In the case of hollow-core fibres, the RDW phase-matching wavelengths can be tuned simply by changing the pressure of the filling gas. UV RDW emission has been shown to be a useful tool for multiple applications, such as spectroscopy and pump-probe ex-periments [3,4]. UV RDW emission is most commonly achieved using gas-filled hollow-core fibres with a core diameter ranging from ~25 µm up to ~450 µm [1, 5]. Even the lower end of this range usually requires the pump energy to be at the µJ level, requiring amplified laser systems. Recently, the use of a much smaller core size enabled the use of less than 150 nJ pump energy from a Ti:Sapphire laser to achieve UV RDW emission [6].
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