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Physical Review Applied
Volumn 3, Issue 4, 2015, Pages
Drop Shaping by Laser-Pulse Impact
Author keywords

[No Author keywords available]
Indexed keywords

DEFORMATION; DROPS; LASER PULSES; PROPULSION;
EID: 84949265234     PISSN: None     EISSN: 23317019     Source Type: Journal    
DOI: 10.1103/PhysRevApplied.3.044018     Document Type: Article
Times cited : (101)
References (35)
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    • See Supplemental Material at for additional movies and technical details
    • See Supplemental Material at http://link.aps.org/supplemental/10.1103/PhysRevApplied.3.044018 for additional movies and technical details.
  • 29
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    • The typical impulse (Equation presented) exerted on the drop by the 3% reflected light from the surface scales as (Equation presented), with (Equation presented) the energy of the reflected light and (Equation presented) the speed of light. This impulse would yield a typical drop speed (Equation presented). The impulse due to thermal radiation from the hot drop surface scales as (Equation presented) with (Equation presented) the emissivity and (Equation presented) the Stefan-Boltzmann constant. This impulse would yield (Equation presented)
    • The typical impulse (Equation presented) exerted on the drop by the 3% reflected light from the surface scales as (Equation presented), with (Equation presented) the energy of the reflected light and (Equation presented) the speed of light. This impulse would yield a typical drop speed (Equation presented). The impulse due to thermal radiation from the hot drop surface scales as (Equation presented) with (Equation presented) the emissivity and (Equation presented) the Stefan-Boltzmann constant. This impulse would yield (Equation presented).
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    • On the time scale of vapor ejection (Equation presented) heat typically diffuses over a length (Equation presented), where (Equation presented) is the thermal diffusivity of water
    • On the time scale of vapor ejection (Equation presented) heat typically diffuses over a length (Equation presented), where (Equation presented) is the thermal diffusivity of water.
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