Optimization of a cw mode-locked frequency-doubled Nd:LiYF<sub>4</sub> laser

Herman Vanherzeele

doi:10.1364/AO.27.003608

Applied Optics
Vol. 27,
Issue 17,
pp. 3608-3615
(1988)
•https://doi.org/10.1364/AO.27.003608

Optimization of a cw mode-locked frequency-doubled Nd:LiYF₄ laser

Herman Vanherzeele

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Herman Vanherzeele, "Optimization of a cw mode-locked frequency-doubled Nd:LiYF₄ laser," Appl. Opt. 27, 3608-3615 (1988)

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Abstract

Several drawbacks of a cw-pumped mode-locked Nd:LiYF₄ laser are outlined, and it is shown how to overcome them. For the first time, attention is paid to thermally induced astigmatism and its compensation in a Nd:LiYF₄ rod. An optimized system generates an average output power similar to that of a typical Nd:YAG laser, however, with an increased stability and with pulse durations that are significantly shorter. The higher peak power in Nd:LiYF₄ can result in a higher conversion efficiency in a frequency-doubling process, provided the doubling crystal can handle the high average power. It will be demonstrated that a well-engineered Nd:LiYF₄ system may become the preferred choice for many applications, including seeding regenerative amplifiers and pumping synchronously mode-locked dye laser oscillators and amplifiers.

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	Glass	YAG	YLF
Optical class	Isotopic	Isotopic	Uniaxial
Wavelength (nm)	1054	1064	1053 (σ)
Wavelength (nm)			1047 (π)
Linewidth (Å)	212	4.5	13.5
Stimulated emission cross section (cm²)	4.4 × 10⁻²⁰	3.4 × 10⁻¹⁹	2.6 × 10⁻¹⁹ (σ)
Stimulated emission cross section (cm²)			3.7 × 10⁻¹⁹ (π)
Gain limit due to parasitics	Moderate	Low	High
Energy storage	High	Low	Medium
Thermal conductivity(W/m°C)	0.7	10	6
Thermal birefringence	Medium	High	Low
Thermal lensing	Moderate	Strong	Low
Fluorescence lifetime (μs)	190	244	480
Optical quality	Excellent	Good	Fair

	⊥c/‖c	⊥c/‖c	⊥c/‖c	⊥c/‖c

f(m)	20/−20	10/−10	8/−8	6.5/−6.5
w _HR	0.138/0.145	0.144/0.144	0.146/0.142	0.148/0.140
w _rod	1.07/0.99	1.02/1.00	1.01/1.01	1.00/1.02
w _OC	0.54/0.42	0.49/0.45	0.47/0.47	0.45/0.49
w ₀	0.44/0.38	0.42/0.40	0.41/0.41	0.40/0.42
z ₀	42/39	32/25	28/28	25/32
δ	0.76/0.87	0.79/0.83	0.81/0.81	0.83/0.79

	Glass	YAG	YLF
Optical class	Isotopic	Isotopic	Uniaxial
Wavelength (nm)	1054	1064	1053 (σ)
Wavelength (nm)			1047 (π)
Linewidth (Å)	212	4.5	13.5
Stimulated emission cross section (cm²)	4.4 × 10⁻²⁰	3.4 × 10⁻¹⁹	2.6 × 10⁻¹⁹ (σ)
Stimulated emission cross section (cm²)			3.7 × 10⁻¹⁹ (π)
Gain limit due to parasitics	Moderate	Low	High
Energy storage	High	Low	Medium
Thermal conductivity(W/m°C)	0.7	10	6
Thermal birefringence	Medium	High	Low
Thermal lensing	Moderate	Strong	Low
Fluorescence lifetime (μs)	190	244	480
Optical quality	Excellent	Good	Fair

	⊥c/‖c	⊥c/‖c	⊥c/‖c	⊥c/‖c

f(m)	20/−20	10/−10	8/−8	6.5/−6.5
w _HR	0.138/0.145	0.144/0.144	0.146/0.142	0.148/0.140
w _rod	1.07/0.99	1.02/1.00	1.01/1.01	1.00/1.02
w _OC	0.54/0.42	0.49/0.45	0.47/0.47	0.45/0.49
w ₀	0.44/0.38	0.42/0.40	0.41/0.41	0.40/0.42
z ₀	42/39	32/25	28/28	25/32
δ	0.76/0.87	0.79/0.83	0.81/0.81	0.83/0.79

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