Plasma Self-Q Switching in Far Infrared Lasers

B. W. McCaul

doi:10.1364/AO.9.000653

Applied Optics
Vol. 9,
Issue 3,
pp. 653-663
(1970)
•https://doi.org/10.1364/AO.9.000653

Plasma Self-Q Switching in Far Infrared Lasers

B. W. McCaul

Not Accessible

Your library or personal account may give you access

Get PDF
Email
Share
Get Citation
Copy Citation Text
B. W. McCaul, "Plasma Self-Q Switching in Far Infrared Lasers," Appl. Opt. 9, 653-663 (1970)

Export Citation
- BibTex
- Endnote (RIS)
- HTML
- Plain Text
Citation alert
Save article

Abstract

The plasma electrons in pulsed far ir lasers constitute a temporary divergent refractive element. This lens element can be strong enough to prohibit stable laser modes and serves to explain the delay commonly reported between current and laser pulses. With electron recombination the cavity rapidly becomes stable, Q switching the laser pulse. The lens effect and Q-switching rate are calculated in terms of tube dimensions, laser frequency, electron density, and radial electron density distribution. Higher laser frequencies appear earlier when this effect is operative. A simple criterion is given to distinguish this delay effect from other sources of laser pulse delay. Experimental measurements are presented of cavity stability as a function of mirror curvature and electron density; wall reflections are shown to be important. The radial electron density distribution is compared with plasma theory results. Lens effects associated with the laser gain are shown to be negligible.

Full Article | PDF Article

More Like This

Plasma effects in the HCN laser

R. Turner
Appl. Opt. 16(5) 1197-1203 (1977)

Refractive Q-switching of a ruby laser by a moving plasma

M. Dembinski and P. K. John
Appl. Opt. 21(20) 3725-3727 (1982)

The Lensing Effect of CO₂ Laser Plasma

H. K. V. Lotsch and W. C. Davis
Appl. Opt. 9(12) 2725-2728 (1970)

Previous Article Next Article

Cited By

You do not have subscription access to this journal. Cited by links are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

Figures (15)

You do not have subscription access to this journal. Figure files are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

Tables (1)

You do not have subscription access to this journal. Article tables are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

Equations (38)

You do not have subscription access to this journal. Equations are available to subscribers only. You may subscribe either as an Optica member, or as an authorized user of your institution.

Contact your librarian or system administrator
or
Login to access Optica Member Subscription

A. Reference Fig. 14
Refractive index	Focal length			α
Divergent electron	$\frac{- 1}{α sinh α L}$			$α = (1 / r_{0}) {(N_{0} / N_{p})}^{\frac{1}{2}}$
Divergent molecular	“		}	$\begin{array}{l} α & = (1 / r_{0}) {({χ_{0}}^{″} / 2)}^{\frac{1}{2}} \\ = (1 / r_{0}) (λ_{η} / 2 π \\ {\times 8.686)}^{\frac{1}{2}} \end{array}$

Convergent molecular	$\frac{1}{α sin α L}$
Substitutions: r₀ = 5 cm, λ = 337 μ, L = 1.6 m
B. Reference Fig. 15
Guided beam	R _m	w _m ² π	1/α
		λ
Divergent electronic	−1/α	infinite
Convergent gain (χ″)	1/α	1/α	$\begin{array}{l} 1 / α & = r_{0} {(2 / {χ_{0}}^{″})}^{\frac{1}{2}} \\ = r_{0} [(2 π \times 8.686) / \\ {λ η]}^{\frac{1}{2}} \end{array}$
Substitutions: r₀ = 5 cm, λ = 337 μ

Abstract

Cited By

Figures (15)

Tables (1)

Equations (38)

Applied Optics