Mid-infrared laser-induced superheating of water and is quantification by an optical temperature probe

Tobias Brendel; Ralf Brinkmann

doi:10.1364/AO.43.001856

Mid-infrared laser-induced superheating of water and is quantification by an optical temperature probe

Tobias Brendel^*, Ralf Brinkmann

^*Corresponding author for this work

Institute of Biomedical Optics

4 Citations (Scopus)

Abstract

Free-running thulium laser pulses (Cr:Tm:YAG, λ = 2.01 μm, t_p = 300 μs) were applied to a purified, degassed water sample and the resulting temperature rise was investigated by an optical temperature probe. The probe detected water reflectance index changes with temperature and also the onset of vaporization, which was found to occur in a superheat regime, at approximately 230°C. The experimental data were compared with theoretical temperature calculations, and deviations of less than 20°C were stated. The best agreement between theory and experiment was found for temperatures below 180°C, defining by this the method's high accuracy limit. In conclusion, both the optical temperature probe and the presented calculations can help to improve dosimetry in pulsed IR laser applications by precise temperature measurement and prediction.

Original language	English
Journal	Applied Optics
Volume	43
Issue number	9
Pages (from-to)	1856-1862
Number of pages	7
ISSN	1559-128X
DOIs	https://doi.org/10.1364/AO.43.001856
Publication status	Published - 20.03.2004

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Academic Focus: Biomedical Engineering

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10.1364/AO.43.001856

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abstract = "Free-running thulium laser pulses (Cr:Tm:YAG, λ = 2.01 μm, tp = 300 μs) were applied to a purified, degassed water sample and the resulting temperature rise was investigated by an optical temperature probe. The probe detected water reflectance index changes with temperature and also the onset of vaporization, which was found to occur in a superheat regime, at approximately 230°C. The experimental data were compared with theoretical temperature calculations, and deviations of less than 20°C were stated. The best agreement between theory and experiment was found for temperatures below 180°C, defining by this the method's high accuracy limit. In conclusion, both the optical temperature probe and the presented calculations can help to improve dosimetry in pulsed IR laser applications by precise temperature measurement and prediction.",

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AU - Brendel, Tobias

AU - Brinkmann, Ralf

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N2 - Free-running thulium laser pulses (Cr:Tm:YAG, λ = 2.01 μm, tp = 300 μs) were applied to a purified, degassed water sample and the resulting temperature rise was investigated by an optical temperature probe. The probe detected water reflectance index changes with temperature and also the onset of vaporization, which was found to occur in a superheat regime, at approximately 230°C. The experimental data were compared with theoretical temperature calculations, and deviations of less than 20°C were stated. The best agreement between theory and experiment was found for temperatures below 180°C, defining by this the method's high accuracy limit. In conclusion, both the optical temperature probe and the presented calculations can help to improve dosimetry in pulsed IR laser applications by precise temperature measurement and prediction.

AB - Free-running thulium laser pulses (Cr:Tm:YAG, λ = 2.01 μm, tp = 300 μs) were applied to a purified, degassed water sample and the resulting temperature rise was investigated by an optical temperature probe. The probe detected water reflectance index changes with temperature and also the onset of vaporization, which was found to occur in a superheat regime, at approximately 230°C. The experimental data were compared with theoretical temperature calculations, and deviations of less than 20°C were stated. The best agreement between theory and experiment was found for temperatures below 180°C, defining by this the method's high accuracy limit. In conclusion, both the optical temperature probe and the presented calculations can help to improve dosimetry in pulsed IR laser applications by precise temperature measurement and prediction.

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SN - 1559-128X

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Mid-infrared laser-induced superheating of water and is quantification by an optical temperature probe

Abstract

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