M. Dekool et U. Anzer, A SIMPLE ANALYSIS OF PERIOD NOISE IN BINARY-X-RAY PULSARS, Monthly Notices of the Royal Astronomical Society, 262(3), 1993, pp. 726-734
We present a simple method for determining whether the noise in the pu
lse period history of X-ray pulsars can be described by a random walk
process. This is done by calculating the mean difference in angular ve
locity between different observations as a function of the time interv
al between these observations. We apply the method to 10 X-ray pulsars
for which more than 10 period determinations are available. For Vela
X-1, we confirm earlier results that the pulse period behaviour is ver
y well fitted by a random walk in period. In GX 301 - 2 the pulse peri
od behaviour is also consistent with a random walk. Analysing the puls
e period history of three X-ray pulsars with a Be companion, we find t
hat a random walk is not consistent with the data. The pulse period hi
story of the two best-studied X-ray pulsars that have an accretion dis
c, Cen X-3 and Her X-1, is not consistent with a random walk, but if a
linear trend is removed the remaining variations are as expected for
a random walk. In the systems showing random walk behaviour, the noise
level is well correlated with the X-ray luminosity, and is not very d
ifferent for the wind-accreting and disc-accreting systems. If we assu
me that in the wind-accreting sources the random walk results from acc
retion torques that change sign, as found in some turbulent accretion
wake simulations in the literature, and that the specific angular mome
ntum of the accreting matter is that of a Kepler orbit at the magnetos
pheric radius, we can derive a typical reversal time-scale from the ob
served noise level which is of the order of hours. This is in good agr
eement with the time-scales predicted by the simulations. In the disc-
accreting systems, which are probably close to their equilibrium perio
d, the noise is likely to be caused by short-term unbalanced fluctuati
ons in either the spin-up or braking torques, and we derive lower limi
ts on the magnitude of the required fluctuations. It is not clear yet
why the disc systems should obey the same noise level-luminosity corre
lation as the wind-accreting systems.