304
THE SOURCE OF STELLAR ENERGY
a rate comparable with the Kelvin time-scale (E = 0) and the subatomic
energy will fail to achieve the purpose for which it was introduced.
The danger of over-stability must again be recalled; E has to increase
with contraction but not much faster than T 2 or the star will be set
oscillating. It seems unlikely that a plausible law can be found between
such narrow limits; so that we prefer *to suppose that there is a lag of a
few months up to a thousand years in the response of E to the changed
conditions. The response must be rapid enough to save a giant star from
collapse.
The second reason for denying that E is independent of p and T is
that the assumption would make L¡M solely a function of the age of the
material. It supposes that the material has gone on degenerating at a rate
independent of physical conditions past and present so that its stage of
exhaustion is determined solely by its age. The question what zero the
age is to be reckoned from remains unanswered. We cannot fit the
astronomical facts into so cast-iron a rule, as was shown in § 207. It is
true that the admission of a dependence on p and T has not helped us
far forward in reconciling the facts; but it does leave us free to explore
further instead of coming to a blank wall of contradiction.
The result that E increases with contraction of the star sometimes
enables us to eliminate one of the variables p and T in a comparison. For
example, imagine the material of Capella to be slowly compressed until
it reaches the temperature of the sun. Then since p oz T 3 the density
becomes | that of the sun. We have now the comparison that at the same
temperature the material of Capella emits more than 30 times as much
energy per gram at a density | that of the sun.
Since the dependence on T may be very complicated, whilst the
dependence on p is expected to be fairly simple we can get a clearer idea
of the exhaustion of the solar material in this way. 212
212. We shall try to classify the possible ways in which we think that
€ (the liberation of energy per gram) might depend on p and T.
To begin with, a nucleus must be concerned in the emission. If nothing
else is concerned the emission by the nucleus is independent of the
statistical state of the system and e is independent of p and T. (It is
possible that the structure of the nucleus may be modified by temperature
and density, that is to say, nuclei of different kinds may be evolved in
different physical conditions; but in that case we regard the emission as
a consequence of the event which creates the radio-active nucleus, and it
falls under one of the succeeding alternatives.)
If, in addition, something extraneous to the nucleus is concerned, this
may be (1) a bound electron, (2) a free electron, (3) the field of radiation.
Two nuclei may also be concerned although their repulsion tends to keep
