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References

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  1. J. Goldsmith, E. H. Byerly, A. A. Vuysteke, in Proc. 8th Convention on Military Electronics, (1964), p. 64.
  2. J. P. Lesieur, M. C. Sexton, D. Veron, J. Phys. D 5, 1212 (1972).
    [CrossRef]
  3. B. S. Patel, Ph.D. thesis, University of Essex, 1971.
  4. R. C. Crafer, A. F. Gibson, M. F. Kimmitt, J. Phys. D 2, 1135 (1969).
    [CrossRef]
  5. P. W. Kruse, L. D. McGlauchlin, R. B. McQuistan, Infrared Technology, (Wiley, New York, (1962), pp. 44 and 45.
  6. Sources of data: Ref. 5, Chap. 4; J. E. Kiefer, A. Yariv, App. Phys. Lett. 15, 26 (1969); and some personal measurements.
    [CrossRef]

1972 (1)

J. P. Lesieur, M. C. Sexton, D. Veron, J. Phys. D 5, 1212 (1972).
[CrossRef]

1969 (1)

R. C. Crafer, A. F. Gibson, M. F. Kimmitt, J. Phys. D 2, 1135 (1969).
[CrossRef]

Byerly, E. H.

J. Goldsmith, E. H. Byerly, A. A. Vuysteke, in Proc. 8th Convention on Military Electronics, (1964), p. 64.

Crafer, R. C.

R. C. Crafer, A. F. Gibson, M. F. Kimmitt, J. Phys. D 2, 1135 (1969).
[CrossRef]

Gibson, A. F.

R. C. Crafer, A. F. Gibson, M. F. Kimmitt, J. Phys. D 2, 1135 (1969).
[CrossRef]

Goldsmith, J.

J. Goldsmith, E. H. Byerly, A. A. Vuysteke, in Proc. 8th Convention on Military Electronics, (1964), p. 64.

Kimmitt, M. F.

R. C. Crafer, A. F. Gibson, M. F. Kimmitt, J. Phys. D 2, 1135 (1969).
[CrossRef]

Kruse, P. W.

P. W. Kruse, L. D. McGlauchlin, R. B. McQuistan, Infrared Technology, (Wiley, New York, (1962), pp. 44 and 45.

Lesieur, J. P.

J. P. Lesieur, M. C. Sexton, D. Veron, J. Phys. D 5, 1212 (1972).
[CrossRef]

McGlauchlin, L. D.

P. W. Kruse, L. D. McGlauchlin, R. B. McQuistan, Infrared Technology, (Wiley, New York, (1962), pp. 44 and 45.

McQuistan, R. B.

P. W. Kruse, L. D. McGlauchlin, R. B. McQuistan, Infrared Technology, (Wiley, New York, (1962), pp. 44 and 45.

Patel, B. S.

B. S. Patel, Ph.D. thesis, University of Essex, 1971.

Sexton, M. C.

J. P. Lesieur, M. C. Sexton, D. Veron, J. Phys. D 5, 1212 (1972).
[CrossRef]

Veron, D.

J. P. Lesieur, M. C. Sexton, D. Veron, J. Phys. D 5, 1212 (1972).
[CrossRef]

Vuysteke, A. A.

J. Goldsmith, E. H. Byerly, A. A. Vuysteke, in Proc. 8th Convention on Military Electronics, (1964), p. 64.

J. Phys. D (2)

J. P. Lesieur, M. C. Sexton, D. Veron, J. Phys. D 5, 1212 (1972).
[CrossRef]

R. C. Crafer, A. F. Gibson, M. F. Kimmitt, J. Phys. D 2, 1135 (1969).
[CrossRef]

Other (4)

P. W. Kruse, L. D. McGlauchlin, R. B. McQuistan, Infrared Technology, (Wiley, New York, (1962), pp. 44 and 45.

Sources of data: Ref. 5, Chap. 4; J. E. Kiefer, A. Yariv, App. Phys. Lett. 15, 26 (1969); and some personal measurements.
[CrossRef]

B. S. Patel, Ph.D. thesis, University of Essex, 1971.

J. Goldsmith, E. H. Byerly, A. A. Vuysteke, in Proc. 8th Convention on Military Electronics, (1964), p. 64.

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Figures (3)

Fig. 1
Fig. 1

A laser system for coupling-out the laser power by a rotatable reflector.

Fig. 2
Fig. 2

Losses introduced in the laser cavity by the rotatable reflector set for the angle of incidence ϕ.

Fig. 3
Fig. 3

The lϕ curves for 0.5 cm-thick materials useful in the CO2 lasers.

Tables (1)

Tables Icon

Table I Spectral Behavior of the Output of a Q-Switched CO2 Laser at Various Cavity Losses

Equations (12)

Equations on this page are rendered with MathJax. Learn more.

R = R ( ϕ ) = tan 2 { ϕ - sin - 1 [ ( sin ϕ ) / n ] } tan 2 { ϕ + sin - 1 [ ( sin ϕ ) / n ] } ,
exp ( - a d ) ,
d = t sec { sin - 1 [ ( sin ϕ ) / n ] }
R 1 = I R ,
R 2 = I R ( 1 - R ) 2 exp ( - 2 a d ) ,
R 1 = I R ,
R 2 = I R ( 1 - R ) 2 exp ( - 2 a d ) ,
l 1 = ( 1 / I ) ( R 1 + R 2 + ) .
l 1 = R + { [ R ( 1 - R ) 2 exp ( - 2 a d ) ] / [ 1 - R 2 exp ( - 2 a d ) ] } .
I = I { [ ( 1 - R ) 2 exp ( - a d ) ] / [ 1 - R 2 exp ( - 2 a d ) ] } .
l = ( I - I ) / I = 1 - ( I / I ) · ( I / I ) ,
l = 1 - { [ ( 1 - R ) 2 exp ( - a d ) ] / [ 1 - R 2 exp ( - 2 a d ) ] } 2

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