C. Lovato scite author profile

C. Lovato

2Publications

22Citation Statements Received

117Citation Statements Given

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Folkwang University of the Arts, University of Siegen

Publications

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Gelation Dynamics upon Pressure-Induced Liquid–Liquid Phase Separation in a Water–Lysozyme Solution

Moron

Lovato

et al. 2022

J. Phys. Chem. B

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Employing X-ray photon correlation spectroscopy, we measure the kinetics and dynamics of a pressure-induced liquid−liquid phase separation (LLPS) in a water−lysozyme solution. Scattering invariants and kinetic information provide evidence that the system reaches the phase boundary upon pressure-induced LLPS with no sign of arrest. The coarsening slows down with increasing quench depths. The g 2 functions display a two-step decay with a gradually increasing nonergodicity parameter typical for gelation. We observe fast superdiffusive (γ ≥ 3/2) and slow subdiffusive (γ < 0.6) motion associated with fast viscoelastic fluctuations of the network and a slow viscous coarsening process, respectively. The dynamics age linearly with time τ ∝ t w , and we observe the onset of viscoelastic relaxation for deeper quenches. Our results suggest that the protein solution gels upon reaching the phase boundary.

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Gelation dynamics upon pressure-induced liquid-liquid phase separation in a water-lysozyme solution

Moron¹,

A.²,

Lovato³

et al. 2021

Preprint

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Employing X-ray photon correlation spectroscopy we measure the kinetics and dynamics of a pressure-induced liquid-liquid phase separation (LLPS) in a water-lysozyme solution. Scattering invariants and kinetic information provide evidence that the system reaches the phase boundary upon pressure-induced LLPS with no sign of arrest.The coarsening slows down with increasing quench depths. The g 2 -functions display a two-step decay with a gradually increasing non-ergodicity parameter typical for gelation. We observe fast superdiffusive (γ ≥ 3/2) and slow subdiffusive (γ < 0.6) motion associated with fast viscoelastic fluctuations of the network and a slow viscous coarsening process, respectively. The dynamics age linear with time τ ∝ t w and we observe the onset of viscoelastic relaxation for deeper quenches. Our results suggest that the protein solution gels upon reaching the phase boundary.

show abstract

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C. Lovato

Gelation Dynamics upon Pressure-Induced Liquid–Liquid Phase Separation in a Water–Lysozyme Solution

Gelation dynamics upon pressure-induced liquid-liquid phase separation in a water-lysozyme solution

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