THE OUTSIDE OF A STAR
355
/
or about 6 electrostatic units. The Stark effect of a steady field of 6 units
resolves H^ into components extending over 0-7 A. The observed width
of the line should be greater—say 2 to 3 A—since the Stark components
will be shifting about over a wider range owing to the fluctuations of the
field. The actual width of H p in stars corresponding to the assumed con
ditions is about 15 A.
I do not think that the fluctuating Stark effect is in itself sufficient
to account for the great widths often observed. It seems likely that
another point is involved. In the foregoing conditions the average speed
of the electrons is 6-2.10 7 cm. per sec. so that the electron traverses a
distance r 0 in 2*4.10 -13 secs, or 24 periods of the 4-quantum orbit. Some
electrons will approach much closer and some will have greater speeds so
that there will be a considerable amount of disturbance which changes
completely in the course of 3 or 4 periods. Now the Stark effect represents
the disturbance by a steady field, which during one half-revolution
counteracts to a large extent the change of phase produced by it in the
other half-revolution; the theory of the effect is based on the “adiabatic
hypothesis” that the field is established slowly in comparison with the
time of revolution. The quickly fluctuating field should give much larger
effects, and it seems possible that the great width of the lines is produced
in this way.
247. Although the general flow of heat through the photosphere is to
some extent dammed back by line absorption and emission, the main
obstruction is likely to be continuous absorption and emission, just as in
the deep interior.
Our formula for the continuous absorption coefficient at temperatures
of some million degrees was (158-2)
The theory of continuous optical absorption at photospheric temperatures
must be fundamentally the same as that of continuous X ray absorption
at high interior temperatures; but we should scarcely expect the formulae
derived under the simplifications permissible at high temperature to apply
to the photosphere. Milne*, however, has found reason to believe that,
whether by coincidence or by actual appropriateness, this extreme extra
polation of (247-1) gives results not far from the truth.
We apply (247-1) to a typical photospheric region with
Continuous Absorption.
/*№(i -f)
(247-1).
P
T — 6000°, po = 200 dynes/cm. 2
* Monthly Notices, 85, p. 768.
