Luminous X-ray binaries (L ;SPMgt; 10 
erg/s) are often classified
as Low Mass X-ray Binary (LMXBs) and High Mass X-ray
Binary (HMXBs) systems depending on the mass of the donor
star. While this classification leaves unspecified the nature of the
accreting collapsed object (which indeed can be a NS or a black hole in
either class), it allows to distinguish the phenomenology of the X-ray
sources and their optical counterpart in a natural way (see Table 1.1).
and have a galactic disc distribution
characteristic of young stars (population I). Of the 
40 X-ray
pulsators known, about 35 are associated with this class of X-ray
binaries. Mass transfer in most of
these systems takes place because part of the intense stellar wind emitted
by the OB star is captured by the gravitational field of the collapsed
object. The energy production budget in HMXBs is often dominated by the
optical luminosity of the OB star, with the X-ray flux emitted in the
vicinity of the collapse object providing only a small perturbation.
Correspondingly the optical spectra are stellar-like (Rappaport & Joss
1983, and references therein).
Periodic X-ray pulsations with periods ranging from 0.069s to 1455s
are present in a large number ( 35) of HMXBs. This signal
originates from the beamed radiation which is produced close to the
magnetic poles of the young accreting neutron star with a surface field
of 10 
G. Due to the misalignment of the magnetic and
rotational axes, the neutron star rotation modulates the X-ray intensity
in a light-house fashion. Period or phase changes introduced by the
binary motion allow to measure some of the orbital parameters of these
systems. Together with the duration of the X-ray eclipse (which is
present in several HMXBs) and the Doppler velocity and photometric
modulation of the optical star, these measurements provide the absolute
orbital solution and the masses of the two components. Secular spin
period changes arise because of the torque exerted on the neutron star
magnetosphere by the accreting matter (Henrichs 1983 and reference
therein; Frank, King & Raine 1992; King 1995). X-ray pulsations from
luminous X-ray binaries provide an incontrovertible signature of
accretion onto a magnetised neutron star.
Table: Classification of NS in X-ray binaries
1 kpc to the galactic plane)
can be accounted for by means of kick velocities imparted on the neutron
star during the supernova event in which they are born. The required kick
velocity distribution is also consistent with that observed for radio
pulsars (Lyne & Lorimer 1994).
LMXBs formation by accretion induced collapse of a white dwarf appears to
be consistent with the kinematic properties of LMXBs.
The short orbital period of LMXBs (0.19 - 398 hr) is usually inferred
from the orbital
modulation of the optical and/or X-ray flux, rather than from X-ray
eclipses (which are rare) (Parmar & White 1988; White, Nagase & Parmar
1995). In most cases mass transfer takes place via Roche lobe overflow
and spills matter with high specific angular momentum J towards the
collapsed star, causing the formation of an accreting disc. The intrinsic
optical luminosity of the low mass companion is orders of magnitude lower
than the X-ray luminosity emitted by the accreting compact object. The
spectral features of the late type star are usually outshone by the
reprocessing at optical wavelengths of the X-ray flux intercepted by
the accretion disc and the star.
All but 8 known X-ray pulsators are associated with HMXBs and their origin
is still unclear (see Appendix §A.2 for more details). Much more frequent
instead, is the phenomenon of (type I) X-ray bursts (see below).
Pulsations are not expected from the old neutron stars in bursting
sources if their magnetic field has decayed to 10 
G, a value
below which accretion is not significantly funneled close to the magnetic
poles. On the other hand, LMXBs are likely to be progenitors of the old,
``recycled'' millisecond pulsars which are found in increasing number
especially in globular clusters (see van den Heuvel 1991 for a detailed
review). In this case the neutron star magnetic field of 10 
- 10 
G inferred from the radio pulsar observations should also
characterise the LMXBs stage, and low amplitude X-ray pulsations in the
millisecond range would be expected if accretion occurs preferentially
along the magnetic field lines. To date the search for fast pulsations
in the persistent emission from LMXBs gave negative results (see Wood et al.
1991 and Vaughan et al. 1994).
Recently coherent pulsations at a period
of 2.75ms were discovered in five out of seven bursts from the bright
X-ray source 4U1728-34 (Strohmayer et al. 1996).
About 45 pulse periods has been discovered so
far with periods between 70ms and 1455s (see also Appendix, §A.2).
The intrinsic pulse periods
measured for a number of X-ray pulsars have been sufficiently well
measured over the past decades to provide important information
regarding the torques exerted on the NSs by the accreting material.
Examining the pulse period histories of these pulsars, it is apparent
that three types of behaviour are present: the pulse period shows a
linear decrease with time, with erratic variations around the trend, an
almost constant value of the pulse period, and a steady increase in
pulse period (for a review see Rappaport & Joss 1983; Nagase 1989;
White, Nagase & Parmar 1995). The spin-up trend in most of the X-ray
pulsars towards secular decrease in the period can be understood in terms
of torques exerted by the matter accreting onto the NS which can be
calculated for the case where the matter has roughly circular Keplerian
velocities at the magnetosphere of the NS. The rate of change, 
,
of the intrinsic pulse period P is related to the X-ray luminosity and
the physical properties of the NS itself (Ghosh & Lamb 1979):
where the dimensionless function f is expected to be of order of unity
for a NS. The observed spin-up timescale ranges from 100 to 100000 yr.
From the pulse timing analysis of the transient source EXO2030+375,
Parmar et al. (1989) obtained a clear dependence of on the
luminosity 
as - 
by directly
measuring the over a wide range of luminosity. This observed
dependence is consistent with the accretion torque theory for disc fed
pulsators developed by Ghosh & Lamb (1979), eq. (
).
An equilibrium is reached when the NS magnetosphere corotates with the
inner edge of the disc, i.e. when 
equals 
.
Close to corotation, the fields line in the transition zone
(where magnetic field begins to thread the disc) are swept backwards, and
a negative torque is exerted on the NS (see also §1.1.1). The NS is then
spun down, even accretion still continue.
No overall trend in the pulse period history is expected for those systems (both wind or disc driven) where inhomogeneities in the accretion flow occur.
Type I X-ray bursts have been observed from
40 LMXB sources so
far. Bursts are described as sudden rise of X-ray luminosity
which typically lasts for tens of seconds, a characteristic cooling
in the decay phase and recur on timescales of hours (see Fig. 1.1). These
bursts account
for only a small fraction of the time-averaged luminosity of LMXBs. They
originate from thermonuclear flashes in the freshly accreted matter on the
surface of a weak magnetised neutron star.
In general, burst profiles depend strongly on photon energy; decays are
much shorter at high photon energies than a low energies. This energy
dependence corresponds to a softening of the burst spectrum during the
decay, which is the result of the cooling of the NS photosphere.
Burst intervals can be regular or irregular on time scale of hours to
days: they range from 5 min to days; burst activity can stop as
well for periods from days to months. In some
cases, a relation has been observed between burst profile and the
persistent emission. The persistent flux of 4U1820-303 (Clark et al.
1977) increased by a factor 5 while the burst interval gradually
decreased by 50%.
In a few LMXBs the bursting activity ceases when the persistent emission
X-ray luminosity increases above a level of 10 
erg/s (van
Paradijs & Lewin 1988 and references therein).
The time dependent energy spectra of X-ray bursts are usually well described by a blackbody spectrum. The result of the spectral analysis of type I bursts show that during burst decay, one finds often that the blackbody radius is approximatively constant while, during expansion phase the luminosity remains approximatively constant.
For 10 sources strong burst-like events, lasting up to 1500s,
have been observed. It is believed that during these bursts the luminosity
becomes so high (close to the Eddington limit) that temporarily the
atmosphere of the NS, expands due to the radiation pressure, possibly
through the formation of a stellar-wind outflow of material from the NS.
After the luminosity decreases below the Eddington limit, the photosphere
contracts.
10 ms (1254-690; Mason
et al. 1980).
Recently coherent pulsations at a period
of 2.75ms were discovered in five out of seven bursts from the bright
X-ray source 4U1728-34 (Strohmayer, Zhang & Swank 1996).
Beside type I bursters there is one ``abnormal'' X-ray sources,
namely Rapid Burster, which display bursts on shorter
time scale. Rapid Burster, when active, displays both type I bursts
and bursts produced in quick succession with recurrence intervals as
short as 7s. The latter features are known as type II bursts and
are thought to be related with spasmodic episodes of accretion (Lewin,
van Paradijs & Taam 1995 and references therein). Moreover, quasi
periodic oscillations (QPOs) of
2-5 Hz were discovered in Rapid Burster in several long type II
bursts (Tawara et al. 1982; Stella et al. 1988a, 1988b). No QPOs have been
observed to date in any type I burst from this source. It is presently
unclear whether the QPOs observed have any relation to other forms of
QPOs observed in LMXBs.
Type I and II bursts usually do not occur in X-ray pulsar binaries
because the strong magnetic field ( 10 G) of young neutron
stars confines the infalling plasma to the polar caps, thereby increasing
dramatically the accretion rate per unit area (compared to weakly
magnetic neutron stars) and giving rise to steady (as opposed to
flash-like) thermonuclear burning in the accreting material (Fujimoto,
Hanawa & Miyaji 1981; Hanawa & Fujimoto 1984). A
transient X-ray
source was observed recently for the first time by 
-ray CGRO
satellite (Fishman et al. 1995; Kouveliotou et al. 1996; Finger, Wilson & van
Paradijs 1996). GRO J1744-28 was soon noticed to possess properties which
differ from those of other known high-energy burst source. In
particular, the bursts seen in GRO J1744-28 have some similarities with
the type II bursts seen in the Rapid Burster (the thermonuclear flashes
model of type I bursts has been ruled out based on energetics arguments;
Kouveliotou et al. 1996), and are also likely to involve some unknown
accretion instability. Moreover, coherent X-ray pulsations at a period
of 467 millisecond with nearly sinusoidal profile were detected. The
requirement to have sub-Keplerian velocities at the magnetosphere
radius for the infalling matter implies 
, which
is consistent with arguments supporting accretion-induced magnetic
field decay in NS (Taam & van den Heuvel 1986; Romani 1990).
An important issue concerning X-ray pulsators is the study of pulse
profiles as an indicator of X-ray emission geometry. The pulse profile
of X-ray pulsators shows great variety from source to source, ranging
from sinusoidal-like profiles, to highly structured and
energy-dependent modulations (4U1626-67, Her X-1, 4U0900-40,
etc; Rappaport & Joss 1983; White, Kallman & Swank 1983).
The shape of the periodic signal contains information on the emission
geometry from the regions close to the NS magnetic poles where accretion
is concentrated. Detailed modelling of the emission pattern emerging from
the accreting polar cap(s) of a NS has shown that beamed emission and
complex pulse profiles can be produced primarily because of the effects of
the magnetic field and the interaction of the radiation with the
infalling matter. The preferred beaming direction depends on whether a
stand-off shock and, therefore, a dense deceleration region are present
above the polar cap. For high luminosity ( 
erg/s) a radiative
shock is expected to form. In this case photons will escape
preferentially from the sides of the high density post-shock accretion
column, giving rise to a fan-beam pattern. For lower luminosities
( 
erg/s) the infalling material might be decelerated in a
collisionless shock above the polar cap possibly arising from plasma
instabilities, or by Coulomb and nuclear collisions at the NS surface. If
the latter occurs, the emission region will be located in a thin layer on
the NS surface and radiative transfer effects in the strong magnetic
field will favor photons escaping in the direction of the field lines,
therefore giving rise to a pencil-beam pattern. If a collisionless shock
occurs a fan-beam is likely to form, as in the high-luminosity case
(Basko & Sunyaev 1976; Mészáros 1984).
known X-ray
pulsars, provided only marginal evidence in favor of fan-beam,
producing the complicated pulse profiles in several high luminosity
X-ray pulsars, and a pencil beam, giving rise to a quasi-sinusoidal
modulations of low luminosity X-ray pulsators (White, Kallman & Swank
1983). In particular, the transient X-ray pulsar EXO 2030+375 (42s pulse
period) offered to study the pulse profile of an individual source
(without uncertainties related to the different distance and magnetic
field strength of different sources) for luminosities ranging from 
to 
erg/s (Parmar et al. 1989; Parmar, White &
Stella, 1989). It was apparent that drastic changes in the shape of the
pulses took place as the luminosity decreased. In particular the
broad peak at a pulse phase of 0.6-0.9 became gradually less pronounced
as the luminosity decreased and virtually disappeared for luminosities of
erg/s (see Fig.1.2). On the contrary, the feature centered
around a
phase of 0.4 increased as the luminosity decreased during the
outburst and became dominant around erg/s.
The orbital periods of X-ray binaries
have been determined from the observation of one or more of the
following features: eclipses, smooth periodic modulation,
periodically recurring X-ray absorption features, periodically recurring
transient X-ray outbursts, pulsar arrival time variations,
radial-velocity variations and pulsar-orbital beat period. The orbital
periods range from 0.19hr to 398 hr and from 4.8hr and 187days for LMXBs
and HMXBs, respectively.
The supergiant systems typically are eclipsing and show extreme intensity and absorption variability on all timescales. The shorter orbital period systems have circular orbits, whereas the longer period systems are eccentric. In LMXBs eclipses are instead rare (see Table 1.1) even if the system is viewed almost edge-on and the compact X-ray source is hidden by the disc. X-rays are still seen because they are scattered in a photo-ionised corona above the disc. As a consequence the source will appear extended and the eclipse partial. The orbital modulation shapes are almost sinusoidal with, in many cases, a minimum close to the partial eclipse due to the partial occultation of an accretion disc corona (ADC) by a structure near the rim of the disc caused by its interaction with the incoming gas stream (X1822-371, X0748-676, etc.; see White, Nagase & Parmar 1995 for a review and Fig. 1.3). A handful of LMXBs show also irregular dips, a sudden decrease of the source intensity, that usually recur periodically. These dips are due to material which is projected above the disc plane by a splash point, where the gas stream from the companion hits the accretion disc. A total of ten dipping sources are known so far.
To account for all these orbital features, the observed properties
of LMXBs should depend on the viewing angle (see White, Nagase & Parmar
1995). At a low inclination (;SPMlt; 70 
), no X-ray dips or
eclipses are seen, but
an optical modulation from the X-ray heated companion may still reveal
the orbital period. At an intermediate inclination, periodic dipping
behaviour is seen which is caused by a structure at the edge of the
accretion disc; in a few cases, a very brief eclipse by the companion may
be seen. In high inclination systems ( 80%), the central X-ray
source is hidden behind the disc rim, but X-ray scattered via an ADC are
still seen giving rise to a partial eclipse.
During the search of expected fast pulsations in LMXBs, a
different
phenomenon was discovered in an increasing number of bright LMXBs:
namely oscillations with frequencies of 1-1000 Hz and a poor coherence.
These quasi periodic oscillations
(QPOs) display large frequency variations on timescale as short as tens
of seconds and, therefore, cannot represent the rotation of the NS. Their
phenomenology is very complex, and different QPO modes have been
identified which correspond to a different spectral and activity states
(Lewin et al. 1988; Stella 1988).
A number of sources show a mode in which
the QPO frequency, 
, increases with the source luminosity.
This property played a key role in the development of QPO models: the
correlation is suggestive of the presence of a NS
magnetosphere which is compressed for increasing accretion rates. In the
beat frequency model (BFM), the interaction between the disc and the
magnetosphere causes the accretion flow to be modulated at the beat
frequency between the disc Keplerian frequency at the magnetosphere
boundary, 
, and the NS spin frequency 
.
In this case the QPO frequency is approximatively given by
where 
is the magnetic dipole field at the neutron star surface
in units of 10 Gauss, 
the X-ray luminosity in units of
10 erg s 
. The equation above assumes also that the rest
energy of the accreting matter is converted into X-ray with a constant
efficiency of 10%. When used to fit the relation
observed in bright LMXBs like GX 5-1, Sco X-1 and Cyg X-2 (see
Fig. 1.4), this
model predicts a NS spin frequency of 
Hz, and a surface
magnetic field of 
, in agreement with the idea that
these systems contain a weakly magnetised NS which has been spun up by
accretion (Lamb et al. 1985). Periodic pulsations at the NS spin frequency
are expected as well in the BFM, although their amplitude might be
drastically reduced by the effects of electron scattering. However in the
absence of measurements of the magnetic field strength and the NS spin
period, it is difficult to use LMXBs to verify the validity of the BFM.
20% broad peak at about 0.2 Hz
reveals the presence of the QPOs (Angelini, Stella & Parmar 1990).
Hz was obtained from the BFM. This was in
remarkable agreement with the observed value. These results provided the
first quantitative confirmation of the BFM and showed that the model can
work as well in the presence of an accretion disc interacting with a
rotating NS magnetosphere (Angelini, Stella & Parmar 1990). Other examples of
pulsating X-ray sources showing QPOs are Cen X-3 and 4U1626-67.
Quite recently (van der Klis et al. 1996a, 1996b, 1996c; Lewin et al. 1996; van
Paradijs et al. 1996; Strohmayer et al. 1996) very fast QPOs
(600-1200 Hz) were detected in several LMXBs thanks to the unprecedented
time resolution and effective area of the XTE satellite detectors.
In the case of the LMXB 4U1608-52 (Berger et al. 1996) narrow QPO peaks at
frequencies between 850 and 890 Hz were detected on Mar. 3 and 6, while
a broad peak around 690 Hz on Mar. 9. The root mean square amplitude of
QPOs increases steadily from 5% at 2 keV to 20% at 12 keV.
When an X-ray colour colour diagram was
assembled from observations in
the 1.5-30 keV band (Fig. 1.5) it was soon noticed that different
X-ray source classes (either persistent and transient) occupied different
regions of the diagram (White & Marshall 1984). The horizontal axis
is the spectral hardness ratio (7-30/3-7 keV) while the vertical axis
represents
the softness ratio (1.5-3/3-10 keV). The former indicates the spectral
hardness while
the latter the intrinsic absorption measure. Based on these differences
and those obtained similarly in the energy intervals below 1 keV and
above 10 kev, several spectral
components were identified. They are briefly
outlined below:
erg s .
10.
Galactic bulge source with high luminosity ( 
),
such as GX17+2 or GX9+1, belong to this class (White et al. 1988).
15. These values are
similar to those obtained from the fit to the very soft spectrum of
BHCs in their high state, such as LMC X-3 and LMC
X-1. 10 
erg/s) have
been found so far. SSSs are believed to be mainly white dwarf accreting
at very high rate from a companion star and undergoing steady
thermonuclear burning of the accreting material. Also NSs can have a
similar component (Kylafis & Xilouris 1993; Hughes 1994).
Besides persistent
sources the X-ray sky is populated by a number of
transient sources which remain in their quiescent state for most of the time
and sporadically undergo bright outbursts with peak luminosities of
erg/s , durations ranging from weeks to months, and
recurrence timescales of 1-10 years or longer.
Throughout the years a very clear analogy of the X-ray characteristics
of bright transient sources with those of persistent sources has emerged.
In particular, a number of X-ray transients display coherent X-ray
pulsations or bursts, testifying to the presence of neutron stars, which
undergo sporadic surges of accretion. Like in the case of persistent
sources, X-ray bursting transients have low mass companions and
relatively soft X-ray spectra,
whereas X-ray pulsations are usually observed from transients in
Be-star high mass binaries which are characterised by
hard X-ray spectra extending up to tens of keV (White,
Kaluzuenski & Swank 1984).
The identification of the optical counterparts of bright transients, in
crowded and often heavily absorbed regions of the galactic plane, is
often made
easier by the optical flux increase associated with the outburst. In the
case of low mass systems, in particular, the reprocessing of high energy
radiation can induce an increase of more than a factor of 100 above the
quiescent optical flux level (Lewin & Joss 1983).
Contrary to the case of persistent low mass X-ray binaries,
detailed photometric and spectroscopic studies of the
companion star are often possible in low mass transient sources,
due to the fact that in the quiescent state their optical spectrum is not
dominated by the reprocessing of X-ray radiation or by the emission from the
accretion disc around the collapsed object.
X-ray transient sources are also extremely useful as they allow to investigate accretion onto collapsed stars over a range of X-ray luminosities, and therefore, accretion rates, much larger than persistent sources.
In the case of hard X-ray transients, the outburst is driven by
sporadic accretion phenomena over a wide interval of accretion rates
onto the magnetosphere of NSs. For low 
, the magnetosphere radius is
generally larger than the corotation one and matter is ejected because of
super-Keplerian drag exerted by magnetosphere on the infalling matter
(centrifugal inhibition).
As increases the magnetosphere radius is forced to shrink
( 
) and if becomes smaller than
, accretion onto the NS surface sets in, giving rise to the
beginning of an outburst. Centrifugal inhibition acts again at the end of
an outburst because, for decreasing , increases till the
condition 
is met resulting in a sudden ``turn
off'' of the X-ray emission.
