Heat wave dynamics in frozen water droplets with eosin molecules under the femtosecond excitation of a supercontinuum

Heat wave dynamics in frozen water droplets with eosin molecules under the femtosecond excitation of a supercontinuum

In this study, we considered thermal processes in liquid and frozen water droplets with added dye molecules and metal nanoparticles at the moment of supercontinuum generation. We studied optical non-linear processes in a water droplet with a diameter of 1.92 mm, cooled (+2 °C) and frozen to -17 °C,...

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Main Authors: Natalia A. Myslitskaya, Anna V. Tcibulnikova, Ilia G. Samusev, Vasiliy A. Slezhkin, Valeriy V. Bryukhanov
Format: Article
Language:English
Published: Voronezh State University 2021-06-01
Series:Конденсированные среды и межфазные границы
Subjects:
supercontinuum
femtosecond excitation
water
piece of ice
eosin fluorescence
ablative silver nanoparticles
surface plasmons
two-photon excitation
thermal optical non-linearity
temperature gradient
heat wave
wave propagation velocity
Online Access:https://journals.vsu.ru/kcmf/article/view/3437
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language English
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author Natalia A. Myslitskaya
Anna V. Tcibulnikova
Ilia G. Samusev
Vasiliy A. Slezhkin
Valeriy V. Bryukhanov
spellingShingle Natalia A. Myslitskaya
Anna V. Tcibulnikova
Ilia G. Samusev
Vasiliy A. Slezhkin
Valeriy V. Bryukhanov
Heat wave dynamics in frozen water droplets with eosin molecules under the femtosecond excitation of a supercontinuum
Конденсированные среды и межфазные границы
supercontinuum
femtosecond excitation
water
piece of ice
eosin fluorescence
ablative silver nanoparticles
surface plasmons
two-photon excitation
thermal optical non-linearity
temperature gradient
heat wave
wave propagation velocity
author_facet Natalia A. Myslitskaya
Anna V. Tcibulnikova
Ilia G. Samusev
Vasiliy A. Slezhkin
Valeriy V. Bryukhanov
author_sort Natalia A. Myslitskaya
title Heat wave dynamics in frozen water droplets with eosin molecules under the femtosecond excitation of a supercontinuum
title_short Heat wave dynamics in frozen water droplets with eosin molecules under the femtosecond excitation of a supercontinuum
title_full Heat wave dynamics in frozen water droplets with eosin molecules under the femtosecond excitation of a supercontinuum
title_fullStr Heat wave dynamics in frozen water droplets with eosin molecules under the femtosecond excitation of a supercontinuum
title_full_unstemmed Heat wave dynamics in frozen water droplets with eosin molecules under the femtosecond excitation of a supercontinuum
title_sort heat wave dynamics in frozen water droplets with eosin molecules under the femtosecond excitation of a supercontinuum
publisher Voronezh State University
series Конденсированные среды и межфазные границы
issn 1606-867X
publishDate 2021-06-01
description In this study, we considered thermal processes in liquid and frozen water droplets with added dye molecules and metal nanoparticles at the moment of supercontinuum generation. We studied optical non-linear processes in a water droplet with a diameter of 1.92 mm, cooled (+2 °C) and frozen to -17 °C, with eosin molecules and ablative silver nanoparticles upon femtosecond laser treatment. When we exposed a cooled water droplet and a piece of ice containing eosin molecules and ablative silver nanoparticles to a femtosecond laser beam (l = 1030 nm), we recorded two-photon fluorescence, enhanced by plasmon processes. Also, supercontinuum generation took place, with a period of decay t = 0.02 s. The geometry of non-linear large -scale self-focusing (LLSS ~ 0.45–0.55 mm) was studied. The value of microscale self-focusing (LSSS ~ 0.1 mm) of SC radiation in the laser channel was determined experimentally. The study shows that the energy dissipation in the SC channel increases when the thermal non-linearity exceeds the electronic non-linearity. We modelled the thermal processes and determined the temperature gradient of the heating of the frozen droplet exposed to a femtosecond pulse. Based on the experimental data, the heat wave propagation velocity was calculated to be n = 0.11 m/s.
topic supercontinuum
femtosecond excitation
water
piece of ice
eosin fluorescence
ablative silver nanoparticles
surface plasmons
two-photon excitation
thermal optical non-linearity
temperature gradient
heat wave
wave propagation velocity
url https://journals.vsu.ru/kcmf/article/view/3437
work_keys_str_mv AT nataliaamyslitskaya heatwavedynamicsinfrozenwaterdropletswitheosinmoleculesunderthefemtosecondexcitationofasupercontinuum
AT annavtcibulnikova heatwavedynamicsinfrozenwaterdropletswitheosinmoleculesunderthefemtosecondexcitationofasupercontinuum
AT iliagsamusev heatwavedynamicsinfrozenwaterdropletswitheosinmoleculesunderthefemtosecondexcitationofasupercontinuum
AT vasiliyaslezhkin heatwavedynamicsinfrozenwaterdropletswitheosinmoleculesunderthefemtosecondexcitationofasupercontinuum
AT valeriyvbryukhanov heatwavedynamicsinfrozenwaterdropletswitheosinmoleculesunderthefemtosecondexcitationofasupercontinuum
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spelling doaj-1c833d359dbf469b81916ebe0a0eef8a2021-06-29T13:29:34ZengVoronezh State UniversityКонденсированные среды и межфазные границы1606-867X2021-06-0123210.17308/kcmf.2021.23/3437Heat wave dynamics in frozen water droplets with eosin molecules under the femtosecond excitation of a supercontinuumNatalia A. Myslitskaya0https://orcid.org/0000-0001-6701-5328Anna V. Tcibulnikova1https://orcid.org/0000-0001-8578-0701Ilia G. Samusev2https://orcid.org/0000-0001-5026-7510Vasiliy A. Slezhkin3https://orcid.org/0000-0002-2801-7029Valeriy V. Bryukhanov4https://orcid.org/0000-0003-4689-7207Immanuel Kant Baltic Federal University, 14 А. Nevskogo ul., Kaliningrad 237041, Russian Federation; Kaliningrad State Technical University, 1 Sovetsky prospekt, Kaliningrad 237022, Russian Federation PhD in Physics and Mathematics, senior research fellow at the Research & Education Centre “Fundamental and Applied Photonics. Nanophotonics”, Institute of Physical and Mathematical Sciences and Information Technologies, Immanuel Kant Baltic Federal University, Kaliningrad, Russian Federation; Associate Professor at the Department of Physics, Kaliningrad State Technical University, Kaliningrad, Russian FederationImmanuel Kant Baltic Federal University, 14 А. Nevskogo ul., Kaliningrad 237041, Russian Federation PhD in Physics and Mathematics, senior research fellow at the Research & Education Centre “Fundamental and Applied Photonics. Nanophotonics”, Institute of Physical and Mathematical Sciences and Information Technologies, Immanuel Kant Baltic Federal University, Kaliningrad, Russian Federation Immanuel Kant Baltic Federal University, 14 А. Nevskogo ul., Kaliningrad 237041, Russian Federation PhD in Physics and Mathematics, head of the Research & Education Centre “Fundamental and Applied Photonics. Nanophotonics”, Institute of Physical and Mathematical Sciences and Information Technologies, Immanuel Kant Baltic Federal University, Kaliningrad, Russian FederationImmanuel Kant Baltic Federal University, 14 А. Nevskogo ul., Kaliningrad 237041, Russian Federation; Kaliningrad State Technical University, 1 Sovetsky prospekt, Kaliningrad 237022, Russian Federation PhD in Chemistry, senior research fellow at the Research & Education Centre “Fundamental and Applied Photonics. Nanophotonics”, Institute of Physical and Mathematical Sciences and Information Technologies, Immanuel Kant Baltic Federal University, Kaliningrad, Russian Federation; Associate Professor at the Department of Chemistry, Kaliningrad State Technical University, Kaliningrad, Russian FederationImmanuel Kant Baltic Federal University, 14 А. Nevskogo ul., Kaliningrad 237041, Russian Federation DSc in Physics and Mathematics, leading research fellow at the Research & Education Centre “Fundamental and Applied Photonics. Nanophotonics”, Institute of Physical and Mathematical Sciences and Information Technologies, Immanuel Kant Baltic Federal University, Kaliningrad, Russian FederationIn this study, we considered thermal processes in liquid and frozen water droplets with added dye molecules and metal nanoparticles at the moment of supercontinuum generation. We studied optical non-linear processes in a water droplet with a diameter of 1.92 mm, cooled (+2 °C) and frozen to -17 °C, with eosin molecules and ablative silver nanoparticles upon femtosecond laser treatment. When we exposed a cooled water droplet and a piece of ice containing eosin molecules and ablative silver nanoparticles to a femtosecond laser beam (l = 1030 nm), we recorded two-photon fluorescence, enhanced by plasmon processes. Also, supercontinuum generation took place, with a period of decay t = 0.02 s. The geometry of non-linear large -scale self-focusing (LLSS ~ 0.45–0.55 mm) was studied. The value of microscale self-focusing (LSSS ~ 0.1 mm) of SC radiation in the laser channel was determined experimentally. The study shows that the energy dissipation in the SC channel increases when the thermal non-linearity exceeds the electronic non-linearity. We modelled the thermal processes and determined the temperature gradient of the heating of the frozen droplet exposed to a femtosecond pulse. Based on the experimental data, the heat wave propagation velocity was calculated to be n = 0.11 m/s.https://journals.vsu.ru/kcmf/article/view/3437supercontinuumfemtosecond excitationwaterpiece of iceeosin fluorescenceablative silver nanoparticlessurface plasmonstwo-photon excitationthermal optical non-linearitytemperature gradientheat wavewave propagation velocity

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