Chemnitz, M.M.ChemnitzScheibinger, R.R.ScheibingerGaida, C.C.GaidaGebhardt, M.M.GebhardtStutzki, F.F.StutzkiPumpe, S.S.PumpeKobelke, J.J.KobelkeTünnermann, A.A.TünnermannLimpert, J.J.LimpertSchmidt, M.A.M.A.Schmidt2022-03-052022-03-052018https://publica.fraunhofer.de/handle/publica/25683410.1364/OPTICA.5.000695Liquid-core fibers offer local external control over pulse dispersion due to their strong thermodynamic response, offering a new degree of freedom in accurate soliton steering for reconfigurable nonlinear light generation. Here, we show how to accurately control soliton dynamics and supercontinuum generation in carbon disulfide/silica fibers by temperature and pressure tuning, monitored via the spectral location and the onset energy of non-solitonic radiation. Simulations and phase-matching calculations based on an extended thermodynamic dispersion model of carbon disulfide confirm the experimental results, which allows us to demonstrate the potential of temperature detuning of liquid-core fibers for octave spanning recompressible supercontinuum generation in the near-infrared.en620journal article