Measurement of the stimulated thermal Rayleigh scattering instability

T. J. Karr; M. C. Rushford; J. R. Murray; J. R. Morris

doi:10.1364/JOSAB.8.000993

Journal of the Optical Society of America B
Vol. 8,
Issue 5,
pp. 993-999
(1991)
•https://doi.org/10.1364/JOSAB.8.000993

Measurement of the stimulated thermal Rayleigh scattering instability

T. J. Karr, M. C. Rushford, J. R. Murray, and J. R. Morris

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T. J. Karr, M. C. Rushford, J. R. Murray, and J. R. Morris, "Measurement of the stimulated thermal Rayleigh scattering instability," J. Opt. Soc. Am. B 8, 993-999 (1991)

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Abstract

The first clear experimental demonstration, to our knowledge, is reported of large amplification of small-scale spatial perturbations by stimulated thermal Rayleigh scattering of a cw laser beam propagating through an absorbing medium in a context normally associated with thermal blooming. A single-mode argon-ion laser beam with λ = 488 nm was propagated vertically downward through a 1.2-m cell filled with CCl₄ that was doped with an absorber to have optical depths in the range 0.5–2.3. A shear-plate interferometer near the cell input generated the perturbation. Fringe growth was rapid and visually obvious, as was competing growth from dust specks, etc. The measured growth rate is in good agreement with the asymptotic rate from analytic stimulated thermal Rayleigh scattering theory.

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	Experiment ID

	121888.72c	12989j.488
Blooming rate (waves/s)	87	64
Time for one wave (ms)	12	16
Whole-beam Fresnel number	64	57
Perturbation Fresnel number	0.45	1.0
Diffusion time ( $D$ κ²)	48	246
Diffusion Fresnel number at ten waves	2.7 × 10⁻²	1.6 × 10⁻²
Absorption optical depths	2.3	0.51
Initial perturbation amplitude	3% (simulation 2%)
Sample rate (Hz)	60
CCD integration time (ms)	33

				Growth Rates(Np/s^1/2)

Experiment ID	kΓz/2π (waves/s)	N_p	N_A	Experiment Fit	Asymptotic Prediction (for $\frac{1}{2} I_{max}$ )
121888.72c	87	0.45	2.3	22	23
121888.62c	83	0.45	2.3	25	23
121888.52c	75	0.45	2.3	22	22
121888.42c	55	0.45	2.3	32	19
12989k.488	62	1.9	0.40	22	20
12989j.488	64	1.0	0.51	19	20
12989i.488	57	0.70	0.40	17	19
12989g.488	64	0.46	0.51	17	20
12989f.488	61	0.23	0.51	19	20
12989e.488	63	0.16	0.51	20	20

	Experiment ID

	121888.72c	12989j.488
Blooming rate (waves/s)	87	64
Time for one wave (ms)	12	16
Whole-beam Fresnel number	64	57
Perturbation Fresnel number	0.45	1.0
Diffusion time ( $D$ κ²)	48	246
Diffusion Fresnel number at ten waves	2.7 × 10⁻²	1.6 × 10⁻²
Absorption optical depths	2.3	0.51
Initial perturbation amplitude	3% (simulation 2%)
Sample rate (Hz)	60
CCD integration time (ms)	33

				Growth Rates(Np/s^1/2)

Experiment ID	kΓz/2π (waves/s)	N_p	N_A	Experiment Fit	Asymptotic Prediction (for $\frac{1}{2} I_{max}$ )
121888.72c	87	0.45	2.3	22	23
121888.62c	83	0.45	2.3	25	23
121888.52c	75	0.45	2.3	22	22
121888.42c	55	0.45	2.3	32	19
12989k.488	62	1.9	0.40	22	20
12989j.488	64	1.0	0.51	19	20
12989i.488	57	0.70	0.40	17	19
12989g.488	64	0.46	0.51	17	20
12989f.488	61	0.23	0.51	19	20
12989e.488	63	0.16	0.51	20	20

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Equations (17)

Journal of the Optical Society of America B