Beam cleanup with stimulated Raman scattering in the intensity-averaging regime

J. Reintjes; R. H. Lehmberg; R. S. F. Chang; M. T. Duignan; G. Calame

doi:10.1364/JOSAB.3.001408

Journal of the Optical Society of America B
Vol. 3,
Issue 10,
pp. 1408-1427
(1986)
•https://doi.org/10.1364/JOSAB.3.001408

Beam cleanup with stimulated Raman scattering in the intensity-averaging regime

J. Reintjes, R. H. Lehmberg, R. S. F. Chang, M. T. Duignan, and G. Calame

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J. Reintjes, R. H. Lehmberg, R. S. F. Chang, M. T. Duignan, and G. Calame, "Beam cleanup with stimulated Raman scattering in the intensity-averaging regime," J. Opt. Soc. Am. B 3, 1408-1427 (1986)

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Abstract

We describe experimental and theoretical investigations of beam cleanup with highly aberrated pump beams in the intensity-averaging regime. Distortion-free amplification of a diffraction-limited Stokes beam is demonstrated in a crossed-beam geometry with a pump beam aberrated to 120 times its diffraction limit, resulting in a brightness increase of 5000 times. Moderately aberrated pump beams produce off-axis Stokes components, while collinear interactions introduce distortion on the Stokes beam. Phase conjugation is combined with stimulated Raman scattering to remove both the aberrations of the pump beam and the aberrations on the Stokes beam itself.

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Regime	Geometry	Aberration	Fresnel Number of Aberration (FN_A = D_A²λL)	Stokes-Beam Characteristics
Nonintensity averaging	Collinear propagation	Phase aberration only	Large (no diffraction over interaction length)	No pump phase print through
Nonintensity averaging	Collinear propagation	Phase aberration only	Intermediate (significant diffraction over interaction length)	Phase or amplitude structure due to print through of pump amplitude structure resulting from diffraction of phase structure
Nonintensity averaging	Collinear propagation	Amplitude	Large or intermediate	Print through of amplitude structure
Intensity averaging	Collinear propagation	Random phase or amplitude	Small (rapid diffraction of pump structure in e-folding gain length)	Some degradation due to incomplete averaging or four-wave mixing
Intensity averaging	Crossed beam	Random phase or amplitude	Large to intermediate	Off-axis pump replication
Intensity averaging	Crossed beam	Random phase or amplitude	Small	Excellent Stokes-beam quality

Pump-Beam Quality (XDL)	GL	Conversion Efficiency (%)	Stokes Sideband Energy (%)
43	5.4	<1	70
43	3.0	<1	44.6
85	3.17	<1	28.5
85	3.08	67.3	38.6

Number of Pump Beams	Pump-Beam Quality (XDL)	Stokes-Beam Quality (XDL)	Conversion Efficiency (%)
2	120	<1.01	43
4	120	<1.01	36
5^a	120	1.6^b	36

Pump-Beam Quality (XDL)	H₂ Pressure (atm)	Pump Depletion (%)	Stokes Conversion (%)		Stokes-Beam Quality (XDL)
Pump-Beam Quality (XDL)	H₂ Pressure (atm)	Pump Depletion (%)	1st	2nd + 3rd	Stokes-Beam Quality (XDL)
120	9	20–30	21–28	1–4	<1.03^a
120	13	30–40	21–28	9–12	<1.03^a
20	3	40	15 (on axis)	15	1.63^b
			10 (off axis)
20	5	70	5 (on axis)	50	3.74^b
			15 (off axis)

Number of Pump Beams	Interaction	Stokes-Beam Quality Relative to Input^a	Stokes-Beam Quality Relative to Renormalized Reference^a
2	Raman–phase conjugation	1.84	1.13
4	Raman–phase conjugation	1.56	1.06
6	Raman–phase conjugation	1.46	1.05
2	Raman cleanup alone, no aberrator and no phase conjugator	1.8	1.06

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Journal of the Optical Society of America B