186
VARIABLE STARS
and ST e /T e are nearly the same. The theoretical relation between them
has not been worked out and there is no reason to expect exact equality.
We might expect that the “eccentricity,” i.e. the deviation from simple
harmonic oscillation, would increase with the relative amplitude; but there
is no evidence of this in the Table. If there is such a tendency it is probably
masked by the more prominent relation of eccentricity to period noticed
by Hertzsprung (p. 180, footnote).
The amplitude ST e of the temperature oscillation should also corre
spond to the observed change of spectral type. The mean value ± -066 T e
corresponds to a relative range -934 to 1-066 which represents an increase
of about four-tenths of a type. The range given in our Table is generally
greater than this. But a great deal depends on the characteristics chosen
in assigning the type. For the types given in the Table the intensities of
the hydrogen lines were used as the principal criterion. Adams and Joy*
have shown that the hydrogen lines behave anomalously in the Cepheids,
and the more general spectral features indicate a smaller change of type.
For the mean of nine stars they found a range of six-tenths of a type from
the hydrogen lines, and one-tenth from the general features of the spectrum.
Adiabatic Oscillations of a Star.
127. We shall now investigate the theory of the pulsation of a gaseous
star. The exact theory of the changes of temperature and density, taking
into account the flow of heat, involves differential equations of the fourth
order which at present seem unmanageable. But the problem is simplified
by noticing that owing to the high opacity of stellar material the oscil
lations through the greater part of the interior are approximately adiabatic.
We therefore start by considering adiabatic oscillations of a sphere of gas;
we can afterwards calculate the flow of heat which would result, and
determine whereabouts in the star it becomes so great as to render the
adiabatic approximation invalid.
Let P, p, T be the pressure, density, and temperature at a point
distant | from the centre and let g be the value of gravity there. We fix
attention on a particular piece of matter so that £ oscillates with the
pulsation. Let f 0 , P 0 , p 0 , etc. denote the undisturbed values, and let
f - fo = 8f = foil, P-P 0 = SP = P 0 P ± (127-1),
and similarly for all the other variables. If the period of pulsation is
27 r/n, , P x , etc., will contain a factor cos nt. We consider small oscillations
and neglect the square of the amplitude.
For adiabatic changes the pressure and density of a particular piece
of matter are connected by
Pozpy,
* Proc. Nat. Acad. Sci. 4, p. 131.
