Thermal diffusion measurements using spatially periodic temperature distributions induced by laser light

1 December 1973

journal article
research article
Published by AIP Publishing in Journal of Applied Physics

Vol. 44 (12) , 5383-5388
https://doi.org/10.1063/1.1662160

Abstract

Two light waves with different directions of propagation derived from a pulsed Nd:YAG laser are superimposed in an absorbing sample and generate an interference field. Due to absorption, a spatially periodic temperature distribution occurs, producing a spatial modulation of the refractive index which can be considered a thermal phase grating. The light of an argon laser simultaneously incident on the sample is diffracted by the thermal grating. When excitation is over, the decay time of the diffracted light is measured. From this decay time the thermal diffusivity of the sample is determined. Measurements on colored methanol and glycerin as well as on ruby compare favorably with the results of other authors. The possibility of exciting and detecting temperature waves (second sound) in solids by the method of light‐induced gratings is discussed.

This publication has 22 references indexed in Scilit:

Thermo- and Elasto-optic Parameters of NaF and Their Implications for Light Scattering from Second Sound
Physical Review B, 1973
Stimulated thermal scattering of light
Physica Status Solidi (b), 1971
Heat Pulses in NaF: Onset of Second Sound
Physical Review Letters, 1970
Specific Heat of α Al2O3 from 2 to 25 K
Journal of Applied Physics, 1969
Stimulated Thermal Scattering in the Second-Sound Regime
Physical Review B, 1969
Dispersion Relation for Second Sound in Solids
Physical Review B, 1964
Temperature Dependence of the Refractive Index of Optical Maser Crystals
Journal of the Optical Society of America, 1963
New Data on the Thermal Conductivity of Optical Crystals*
Journal of the Optical Society of America, 1951
Low Temperature Heat Capacities of Inorganic Solids.¹ III. Heat Capacity of Aluminum Oxide (Synthetic Sapphire) from 19 to 300°K.
Journal of the American Chemical Society, 1950
Theory of the Superfluidity of Helium II
Physical Review B, 1941