Characterisation of nonlinear conversion and crystal quality in Nd- and Yb-doped YAB

Peter Dekker; Judith M. Dawes

doi:10.1364/OPEX.12.005922

Optics Express
Vol. 12,
Issue 24,
pp. 5922-5930
(2004)
•https://doi.org/10.1364/OPEX.12.005922

Characterisation of nonlinear conversion and crystal quality in Nd- and Yb-doped YAB

Peter Dekker and Judith M. Dawes

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Peter Dekker and Judith M. Dawes, "Characterisation of nonlinear conversion and crystal quality in Nd- and Yb-doped YAB," Opt. Express 12, 5922-5930 (2004)

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About this Article
History
- Original Manuscript: October 27, 2004
- Revised Manuscript: November 14, 2004
- Manuscript Accepted: November 15, 2004
- Published: November 29, 2004

Abstract

Variable crystal quality affects the laser performance of many self-frequency doubling crystals, particularly those of the yttrium aluminum borate family. In this report we characterize nonlinear frequency conversion in Yb:YAB and demonstrate a simple non-destructive technique for measuring crystal quality. By imaging the nonlinear conversion using a CCD camera we observe phase matching characteristics similar to that obtained in quasi-phase-matched crystals. These effects are attributed to stacking faults in the structure of the YAB crystal during crystal growth. We believe that such defects cause the large variability in self-doubled performance reported for Nd- or Yb-doped YAB and that our technique may be used as a nondestructive measurement of crystal quality.

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Fig. 1. Schematic of arrangement used to measure angular and temperature acceptance in YAB.

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Fig. 2. Angular acceptance curves for phase matched Yb:YAB in crystals without (a) and with (b) twinning. In both cases f was orientated normal to the probe beam.

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Fig. 3. Calculated and measured second harmonic intensity as a function of detuning angle in different regions in a Yb:YAB crystal. Model normalized to singly peaked data.

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Fig. 4. Second harmonic phase matching maps in Yb:YAB, (3x3×4.1mm) as a function of phase mismatch. Red/white areas signify high intensities while blue-purple low intensity. Angle in top right hand corner indicates phase-mismatch angle from θ_pm (external angle).

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Fig. 5. Phase matching maps for Yb:YAB and Nd:YAB (lower 3) oriented for optimized phasematching.

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Fig. 6. Phase matching maps of Yb:GdCOB as a function of external angle around the optimum (middle image). Crystal dimensions 3×3×5.4 mm, cut θ=66.8°, ϕ=132.6°.

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\frac{P_{2 ω}}{P_{ω}} = {(l_{c})}^{2} K \frac{4}{π^{2}} \frac{P_{ω}}{A} \sin^{2} (\frac{π l_{x}}{2 l_{c}})

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