Post on 26-Dec-2015
Single Bubble Single Bubble SonoluminescenceSonoluminescence
Senior Thesis to partially fulfill the requirements for the Honors Degree in Physics
at the University of Alaska Fairbanks
Denis Seletskiy
SonoluminescenceSonoluminescence
- Introduction- Brief History- Parameters- Existing Theories- My Experiment- Calculations- Conclusion
IntroductionIntroduction
• What is Sonoluminescence (SL)?
• Single bubble SL (SBSL) and multiple bubble SL (MBSL)
Brief HistoryBrief History• Pre-discovery period - Lord Rayleigh (cavitation 1917)
• Discovery of MBSL (1934) - Frenzel and Schultes (photo plates)
• Discovery of SBSL (1988) - Gaitan ( Flynn’s formulation)
• Subsequent developments - Flash duration, flash spectrum, timing,
temperature, bubble radius, bubble stability (Putterman et al.; Weninger et al.)
ParametersParameters
• Radius of the Bubble in Time• Flash Duration• Spectrum and Temperature• Intensity and Temperature• Effect of Bubble Gas on Emissions• Dipole Emissions
Radius of the BubbleRadius of the Bubble
From : S. Putterman, Sonoluminescence: Sound into Light, Scientific American, 272 (1995)
Flash DurationFlash Duration
From: M.Moran et al., Observations of Single-Pulse Sonoluminescence
(from LLNL e-preprint server www-phys.llnl.gov)
• Streak camera images
• SBSL < 6ps
• Limited by fast streak camera resolution of 2ps
Spectrum and Spectrum and TemperatureTemperature
From: R.Hiller et al., Spectrum of Synchronous Picosecond Sonoluminescence, Phys. Rev. Letters, 69 (1992)
• Solid – blackbody spectrum (T=25000K)
Dotted – SL
• No spectral lines on 1nm resolution scale, (compare to MBSL)
• Note: UV absorption
Intensity and TemperatureIntensity and Temperature
Reducing T results in: a) Intensity increase
b) UV shift in spectrumFrom: R.Hiller et al, Spectrum of Synchronous Picosecond Sonoluminescence,
Phys. Rev. Letters, 69 (1992)
Effect of Gas on EmissionsEffect of Gas on Emissions
From: R. Hiller et al, Effect of Noble Gas Doping in Single Bubble
Sonoluminescence, Science 266, (1994)
• Noble Gas Doping
• Intensity normalized to emissions of air
• Most efficient at 1% doping
Ar) 1% ,N %70( 2
Dipole Emission PatternDipole Emission Pattern
• Bubble eccentricity ~ .01
• Less stable than spherical emissions
Figure shows intensity due to refraction of light from a point source through an elliptical interface (non-spherical bubble)
From: K. Weninger et al, Angular correlations in sonoluminescence: Diagnostic
for the sphericity of a collapsing bubble, Phys. Rev. E 54, (1996)
Existing TheoriesExisting Theories
• Shock Wave Theory (UCLA) Putterman et al. - as discussed before on the Radius slide - shortcomings: dI/dT >0; noble gas doping; stability - atomic emission timescale ~ ns = 1000x flash timescale
• High Pressure Gas Scintillator (Duke) Tornow - agreement with gas doping and UV spectrum peak
- shortcomings: fails to explain the picosecond flash duration
• Jet Formation Theory (John Hopkins) Prosperetti
- jet fracturing of the wall of the bubble – produces light
- manages to explain almost all of the properties
My ExperimentMy Experiment
•
CellCell• 100 ml Kimax flask with radius 3.05 cm
• Resonant frequency (27.0±0.3) kHz
• Two driving and one sensor
piezoelectric transducers
TransducersTransducers
• Piezo-electric with intrinsic polarization:
P = 3.3 V/nm C = 750 pF
• Curie point 300 °C
• Displacement 195 nm p-p at maximum drive
Electrical CircuitElectrical Circuit
• RLC circuit with variable inductance; tune to match the mechanical resonance frequency
Inductance MatchInductance Match
• In resonant condition voltage swing across the transducers was about 650 V p-p
OUT OF PHASE IN PHASE
Sonoluminescent Flash Sonoluminescent Flash
•
• Digitally photographed using a f=20 cm lens
photons 6106)(5
Digitally EnhancedDigitally Enhanced
• 16X magnification of previous image
• Note: the edge is brighter, suggesting hollow sphere
• Note: dipole-like emission?
ComparisonComparison
• Good agreement with my picture
• Note: radius of glowing bubble is about 10 µm
From: M.Moran et al, Observations of Single-Pulse Sonoluminescence,
www-phys.llnl.gov
CalculationsCalculations
ConclusionConclusion
Black
Thank you