Transverse mode formation in low-magnification positive-branch unstable resonators

R. William Jones; James F. Perkins

doi:10.1364/AO.23.001361

Applied Optics
Vol. 23,
Issue 9,
pp. 1361-1368
(1984)
•https://doi.org/10.1364/AO.23.001361

Transverse mode formation in low-magnification positive-branch unstable resonators

R. William Jones and James F. Perkins

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R. William Jones and James F. Perkins, "Transverse mode formation in low-magnification positive-branch unstable resonators," Appl. Opt. 23, 1361-1368 (1984)

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Abstract

The dynamics of transverse mode formation time in positive-branch unstable resonators with low magnification (M = 1.32) and typical Fresnel numbers (279 < N_T < 2700) used in high-energy lasers has been investigated. The objective was to observe the far-field intensity distribution from the onset of pumping to the settled steady-state diffraction-limited pattern. The research consisted of an experimental and numerical analysis. The experimental measurements of mode formation time were with a pulsed XeF laser having centered resonator optics. Mode formation was deduced from observation of the far field. The analytical effort consisted of a fast Fourier transform wave optics code which modeled the far-field pattern evolution. Results agree with temporal mode formation geometrical predictions of Ananev when laser saturation is achieved around this time.

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Parameter	CO₂ laser	XeF laser
Laser wavelength	10.6 μm	0.3532 μm
Pulse length (in experiments)	0.02–1.0 μsec	0.2–0.8 μsec
Pulse energy (in experiments)	30 J	15 J
Laser gas mix (in experiments)	1:1 CO₂:He	1:3:760 NF₃:X_e:Ar
Cavity pressure (in experiments)	456 Torr	1520–2280 Torr
Active media dimensions	10 × 10 × 100 cm	10 × 20 × 200 cm
Resonator magnification	1.32	1.32
Mirror separation	338 cm	262 cm
Output beam size	10 × 10 cm	10 × 20 cm
Geometric outcoupling	0.426	0.426
Beam shape (obscuration)	Decentered	Centered
Tube Fresnel number	279	2700
Mode formation time	489 nsec	513 nsec
e-beam voltage	180 keV	300–500 keV
Discharge voltage	0–50 keV	0
Guide field current	0	300 A

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Applied Optics