Explosive boiling of water after pulsed IR laser heating

Atsushi Takamizawa; Shinji Kajimoto; Jonathan Hobley; Koji Hatanaka; Koji Ohta; Hiroshi Fukumura

doi:10.1039/b210609d

Explosive boiling of water after pulsed IR laser heating

Atsushi Takamizawa, Shinji Kajimoto, Jonathan Hobley, Koji Hatanaka, Koji Ohta, Hiroshi Fukumura

Department of Biomedical Engineering

Research output: Contribution to journal › Article › peer-review

39 Citations (Scopus)

Abstract

By focussing 1 J of 1064 nm Nd: YAG beam into 30 atmospheres of hydrogen we could Raman shift to produce a 10 ns, 300 mJ, 1.9 μm laser pulse. This pulse can directly heat water by more than 100 K (average), during the laser pulse, inducing vaporisation. Vaporisation was studied using time-resolved shadowgraphy and Raman spectroscopy to obtain macro and molecular level information. The O-H stretching Raman bands of water are sensitive to temperature allowing us to measure the average temperatures during the boiling process. After the T-jump, explosive boiling occurred within 100 ns during which time the bulk temperature decreased, indicating that the vaporising water molecules deprived heat from their surroundings. Shadowgraphs confirmed the timescale for this phenomenon visually. After 10 μs, vaporised gas molecules condensed and formed droplets, which were observed by a morphology-dependent resonance (MDR) Raman.

Original language	English
Pages (from-to)	888-895
Number of pages	8
Journal	Physical Chemistry Chemical Physics
Volume	5
Issue number	5
DOIs	https://doi.org/10.1039/b210609d
Publication status	Published - 2003 Mar 1

All Science Journal Classification (ASJC) codes

General Physics and Astronomy
Physical and Theoretical Chemistry

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10.1039/b210609d

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abstract = "By focussing 1 J of 1064 nm Nd: YAG beam into 30 atmospheres of hydrogen we could Raman shift to produce a 10 ns, 300 mJ, 1.9 μm laser pulse. This pulse can directly heat water by more than 100 K (average), during the laser pulse, inducing vaporisation. Vaporisation was studied using time-resolved shadowgraphy and Raman spectroscopy to obtain macro and molecular level information. The O-H stretching Raman bands of water are sensitive to temperature allowing us to measure the average temperatures during the boiling process. After the T-jump, explosive boiling occurred within 100 ns during which time the bulk temperature decreased, indicating that the vaporising water molecules deprived heat from their surroundings. Shadowgraphs confirmed the timescale for this phenomenon visually. After 10 μs, vaporised gas molecules condensed and formed droplets, which were observed by a morphology-dependent resonance (MDR) Raman.",

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T1 - Explosive boiling of water after pulsed IR laser heating

AU - Takamizawa, Atsushi

AU - Kajimoto, Shinji

AU - Hobley, Jonathan

AU - Hatanaka, Koji

AU - Ohta, Koji

AU - Fukumura, Hiroshi

PY - 2003/3/1

Y1 - 2003/3/1

N2 - By focussing 1 J of 1064 nm Nd: YAG beam into 30 atmospheres of hydrogen we could Raman shift to produce a 10 ns, 300 mJ, 1.9 μm laser pulse. This pulse can directly heat water by more than 100 K (average), during the laser pulse, inducing vaporisation. Vaporisation was studied using time-resolved shadowgraphy and Raman spectroscopy to obtain macro and molecular level information. The O-H stretching Raman bands of water are sensitive to temperature allowing us to measure the average temperatures during the boiling process. After the T-jump, explosive boiling occurred within 100 ns during which time the bulk temperature decreased, indicating that the vaporising water molecules deprived heat from their surroundings. Shadowgraphs confirmed the timescale for this phenomenon visually. After 10 μs, vaporised gas molecules condensed and formed droplets, which were observed by a morphology-dependent resonance (MDR) Raman.

AB - By focussing 1 J of 1064 nm Nd: YAG beam into 30 atmospheres of hydrogen we could Raman shift to produce a 10 ns, 300 mJ, 1.9 μm laser pulse. This pulse can directly heat water by more than 100 K (average), during the laser pulse, inducing vaporisation. Vaporisation was studied using time-resolved shadowgraphy and Raman spectroscopy to obtain macro and molecular level information. The O-H stretching Raman bands of water are sensitive to temperature allowing us to measure the average temperatures during the boiling process. After the T-jump, explosive boiling occurred within 100 ns during which time the bulk temperature decreased, indicating that the vaporising water molecules deprived heat from their surroundings. Shadowgraphs confirmed the timescale for this phenomenon visually. After 10 μs, vaporised gas molecules condensed and formed droplets, which were observed by a morphology-dependent resonance (MDR) Raman.

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Explosive boiling of water after pulsed IR laser heating

Abstract

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