76      Charles Freed

                  where B is the principal rotational constant given in Eq. (2). At trot = 400 K, Jmw
                  = 19. This is  the primary  explanation of  why  the  (OOOl)-[lOOO,   02001, P(20)
                  transition dominates in a  12C160, laser. It also explains that in a long CO,  laser
                  with a simple two-mirror cavity bnly the I-P(20) transition will oscillate. As an
                  example, a CO,  laser with an optical cavity mirror spacing of L = 3 m, will have
                  longitudinal cavity  modes  [18,19] spaced every  c/2L  = (3 x 108)/6 = 50 MHz
                  apart. This mode spacing is less (as explained in the next section) than even the
                  Doppler-broadened gain profile of about 60 MHz, so that there always will be a
                  cavity mode under the gain profile no matter how far a cavity mirror is tuned.
                  Hence, a frequency-dispersive optical cavity element, such as a diffraction grating
                  for instance, should always be used when low-gain transitions are to be obtained.


                   6.  LINESHAPE FUNCTIONS AND BROADENING DUE TO  GAS
                   PRESSURE AND DOPPLER SHIFT IN CO,  GAS

                      The  phenomena  of  laser  emission  and  saturable  absorption  are  both  the
                  result  of  an  electromagnetic  wave  interacting  with  an  atomic  or  molecular
                  medium. This interaction occurs over a finite frequency bandwidth.
                      Spontaneous  emission occurs  without the  inducement of  a  radiation  field
                  because there is a finite probability that an atom (molecule in the case of CO,)  in
                  level 2 of a system of energy levels El will spontaneously undergo a transition to
                   level 1, emitting in the process a photon of energy hv = E,-E,.  It can be shown
                   [ 18.191 from basic quantum-mechanical considerations and verified experimen-
                   tally that both the emission and the absorption of  radiation are described by the
                   same lineshape function g(v) that gives the distribution of  emitted (or absorbed)
                   intensity as a function of frequency v. The lineshape function is usually normal-
                   ized so that






                   One of the possible causes for the frequency spread of  spontaneous emission is
                   the finite lifetime tj of the emitting level. In the case of atomic or molecular tran-
                   sitions between an upper level (u) and a lower level (l), the coherent interaction
                   of an atom or molecule in either level (u or 1) with the electromagnetic field can
                   be interrupted by  the finite lifetime of the level (T[( or tl) or by an elastic colli-
                   sion, which erases any phase memory (T~[( or t,,).  In this case, a normalized line-
                   shape function with a Lorentzian profile is obtained:

                                                    AVL
                                                                                 (7)
                                              (v - v0)' + (AvL / 2)']  '