TY - JOUR
T1 - Aerodynamic levitator furnace for measuring thermophysical properties of refractory liquids
AU - Langstaff, David Philip
AU - Gunn, Matthew David
AU - Greaves, George Neville
AU - Marsing, Andreas
AU - Kargl, Florian
N1 - Langstaff, D. P., Gunn, M. D., Greaves, G. N., Marsing, A., Kargl, F. (2013). Aerodynamic levitator furnace for measuring thermophysical properties of refractory liquids. Review of Scientific Instruments, 84 (12), [124901]
PY - 2013/12/5
Y1 - 2013/12/5
N2 - The development of novel contactless aerodynamic laser heated levitation techniques is reported that enable thermophysical properties of refractory liquids to be measured in-situ in the solid, liquid and supercooled liquid state and demonstrated here for alumina. Starting with polished crystalline ruby spheres, we show how, by accurately measuring the changing radius, the known density in the solid state can be reproduced from room temperature to the melting point at 2323 K. Once molten, by coupling the floating liquid drop to acoustic oscillations via the levitating gas, the mechanical resonance and damping of the liquid can be measured precisely with high-speed high-resolution shadow cast imaging. The resonance frequency relates to the surface tension, the decay constant to the viscosity, and the ellipsoidal size and shape of the levitating drop to the density. This unique instrumentation enables these related thermophysical properties to be recorded in-situ over the entire liquid and supercooled range of alumina, from the boiling point at 3240 K, until spontaneous crystallization occurs around 1860 K, almost 500 degree below the melting point. We believe that the utility that this unique instrumentation provides will be applicable to studying these important properties in many other high temperature liquids.
AB - The development of novel contactless aerodynamic laser heated levitation techniques is reported that enable thermophysical properties of refractory liquids to be measured in-situ in the solid, liquid and supercooled liquid state and demonstrated here for alumina. Starting with polished crystalline ruby spheres, we show how, by accurately measuring the changing radius, the known density in the solid state can be reproduced from room temperature to the melting point at 2323 K. Once molten, by coupling the floating liquid drop to acoustic oscillations via the levitating gas, the mechanical resonance and damping of the liquid can be measured precisely with high-speed high-resolution shadow cast imaging. The resonance frequency relates to the surface tension, the decay constant to the viscosity, and the ellipsoidal size and shape of the levitating drop to the density. This unique instrumentation enables these related thermophysical properties to be recorded in-situ over the entire liquid and supercooled range of alumina, from the boiling point at 3240 K, until spontaneous crystallization occurs around 1860 K, almost 500 degree below the melting point. We believe that the utility that this unique instrumentation provides will be applicable to studying these important properties in many other high temperature liquids.
KW - THERMOMETRY
KW - THERMAL DIFFUSIVITY
KW - ACOUSTIC
KW - PHOTOTHERMAL AND PHOTOACOUSTIC
UR - http://hdl.handle.net/2160/13128
U2 - 10.1063/1.4832115
DO - 10.1063/1.4832115
M3 - Article
C2 - 24387452
SN - 0034-6748
VL - 84
JO - Review of Scientific Instruments
JF - Review of Scientific Instruments
IS - 12
M1 - 124901
ER -