Photon-rich x ray observations on bright compact galactic sources will make it possible to detect many fast processes that may occur in these systems on millisecond and submillisecond timescales. Many of these processes are of direct relevance to gravitational physics because they arise in regions of strong gravity near neutron stars and black holes where the dynamical timescales for compact objects of stellar mass are milliseconds. To date, such observations have been limited by the detector area and telemetry rates available. However, instruments such as the proposed X ray Large Array (XLA) would achieve collecting areas of about 100 sq m. This instrument has been described elsewhere (Wood and Michelson 1988) and was the subject of a recent prephase A feasibility study at Marshall Space Flight Center. Observations with an XLA class instrument will directly impact five primary areas of astrophysics research: the attempt to detect gravitational radiation, the study of black holes, the physics of mass accretion onto compact objects, the structure of neutron stars and nuclear matter, and the characterization of dark matter in the universe. Those observations are discussed that are most directly relevant to gravitational physics: the search for millisecond x ray pulsars that are potential sources of continuous gravitational radiation; and the use of x ray timing observations to probe the physical conditions in extreme relativistic regions of space near black holes, both stellar-sized and supermassive

Michelson, Peter F.

Wood, Kent S.

English

NASA Technical Reports Server

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X-RAY TIMING OBSERVATIONS AND GRAVITATIONAL PHYSICS '_ '
PETER F. MICHELSON
Department of Physics
Stanford University
Stanford, California 94305
KENT S. WOOD
Naval Research Laboratory
Washington, D.C.
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Photon-rich X-ray observations on bright compact galactic sources will make
it possible to detect many fast processes that may occur in these systems on
millisecond and submillisecond timescales. Many of these processes are of direct
relevance to gravitational physics because they arise in regions of strong gravity
near neutron stars and black holes where the dynamical timescales for compact
objects of stellar mass are milliseconds. To date, such observations have been limited
by the detector area and telemetry rates available. However, instruments such as the
proposed X-ray Large Array (XLA) would achieve collecting areas of about 100 m 2.
This instrument has been described elsewhere (Wood and Michelson 1988) and was
the subject of a recent prephase A feasibility study at Marshall Space Flight Center.
Observations with an XLA class instrument will directly impact five primary areas of
astrophysics research: the attempt to detect gravitational radiation, the study of
black holes, the physics of mass accretion onto compact objects, the structure of
neutron stars and nuclear matter, and the characterization of dark matter in the
universe. In this talk we will focus on those observations that are most directly
relevant to gravitational physics: the search for millisecond X-ray pulsars that are
potential sources of continuous gravitational radiation; and the use of X-ray timing
observations to probe the physical conditions in extreme relativistic regions of space
near black holes, both stellar-sized and supermassive (>106 solar masses). These
observations can be used to find answers to gravitational physics questions such as
the following.
Are rapidly-spinning neutron stars subject to relativistic instabilities
that lead to the emission of gravitational radiation?
Do marginally stable orbits exist around neutron stars?
Do accreting neutron stars in binaries evolve primarily by orbit decay
associated with gravitational radiation emission?
Are light curves of predicted binary millisecond X-ray pulsars modified
by gravitational lensing?
What are the submillisecond temporal characteristics of galactic black
holes?
What are the angular diameters of X-ray emitting regions around
compact objects in active galactic nuclei?
What is the extent of X-ray emission associated with halos of clusters of
galaxies, and does it imply the presence of dark matter?
The direct detection of gravitational radiation is perhaps the primary goal of
experimental gravitational physics. While emission of such radiation has been
inferred from radio observations of a neutron star binary system, efforts to directly
detect gravity waves have not yet succeeded. The predicted sources of gravitational
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radiation may be broadly subdivided according to whether emission is produced in a
short burst, as a stochastic background, or as a continuous wave at a single
frequency. Continuous wave emission is of interest in connection with bright
accreting neutron stars in binaries.
Rapidly rotating neutron stars become secularly unstable wheal subjected to
viscous dissipative forces or gravitational radiation reaction (Chandrasekhar 1970,
Friedman and Schutz 1978). Modes that grow via gravitational radiation reaction are
damped by viscosity and vice versa. This process, often referred to as the
Chandrasekhar-Friedman-Schutz (CFS) instability, was originally considered
applicable to a situation in which a neutron star is born with a spin period near 1 ms
and then deacceleratedby the torque associatedwith gravitational radiation. In a
reference frame rotating with the star, the CFS mode manifests itself as a
nonaxisymmetric deformation of the star (with mode number m = 3 or 4) that
counter-rotates. For the CFS mechanismto deliver CW gravitational radiation over a
prolonged time, the angular momentum radiated away must be replenished. Nature
provides an appropriate situation when a neutron star with a weak magnetic field
accretes material from a binary companion. In an accretion environment, the
neutron star need not start with a short period. Accretion provides a spin-up torque
that can first drive the neutron star into the unstable regime and then keep it there,
ultimately reaching an equilibrium in which angular momentum lost by
gravitational radiation equals that gained from accretion. This scenario was recently
described theoretically by Wagoner (1984). The model requires that the star have a
weak magnetic field in order that the accretion disk extend to the stellar surface and
deliver angular momentum continuously.
In equilibrium, gravitational radiation is emitted at a frequency f associated
with the pattern speed of the nonaxisymmetric distortion as seen in the observer's
frame. This frequency depends on details of the neutron star's structure and its
viscosity. It is predicted to lie in the range 200 Hz < f < 800 Hz, below the rotation
frequency of the star.
X-ray radiation is emitted as a consequence of the accretion process. Indeed,
most of the gravitational energy of the accreting matter is released in X-rays, while
most of the angular momentum is removed by gravitational radiation. Because of the
nonaxisymmetric distortion of the star, the X-ray flux is expected to be weakly
modulated at the same frequency as the gravitational radiation. This situation
constitutes a new kind of binary X-ray pulsar that has never been detected, probably
because the frequency is very high, the level of modulation is very low, and the
pulsar is in a binary system. All of these conditions make detection with a small
aperture detector very difficult. An XLA class instrument enormously improves the
detection probability.
Detection in either the X-ray or the gravity wave channel facilitates the
search in the other channel. One could discover the pulsar in X-rays and use
knowledge of the frequency to search for the gravity wave signal. Detection of the
X-ray pulsations by itself would be significant, settling some major issues in
astrophysics. The period of the X-ray modulation would give information about the
equation of state of matter at high densities and information about the viscosity. The
theory of the X-ray pulsation mechanism in these systems could be tested. Dual-
channel detection of the source in both X-rays and gravity waves would provide two
measures of the neutron star distortion and would lead to a variety of new
observational tests, e.g., tracking the angular momentum as it is added by accretion
and removed by gravitational radiation.
99
We now turn to consideration of how X-ray timing applies to the study of black
holes. These gravitationally collapsed objects are an allowed endpoint of evolution of
massive bodies in General Relativity. Specific astrophysical candidates have been
identified in two very different mass ranges: stellar candidates such as Cygnus X-1
and active galactic nuclei (AGN), with masses from about 105 to perhaps more than
107 solar masses. Black holes play a fundamental role in astrophysics, in large part
because accretion onto black holes is thought to be the energy release mechanism
that powers the quasars and other AGNs.
X-ray and even gamma-ray observations have contributed enormously to the
identification and study of black hole candidates, mainly because it is in these high-
energy channels that the sources are highly luminous and well-isolated. Since the
radiation emitted by accretion can vary on the relevant dynamical timescales, fast
timing and time-resolved spectroscopy are crucial, just as for neutron stars.
However, we must acknowledge that no high-energy observations by themselves
have yet provided a rigorous observational demonstration that a black hole is present
in these systems. For the stellar mass cases in particular, the experimental approach
most often used is proof by mass determination: if the compact, accreting object
exceeds the maximum stable mass of a neutron star, then it must be a black hole. The
mass determination is usually made by optical observations of the companion that
determine the mass function of the accreting binary system. X-ray observations
establish the compact nature of the source. This approach is indirect in that it
establishes a black hole by excluding a particular alternative, a stable non-collapsed
configuration, rather than by observing some distinctive signature indicative of an
event horizon in the system. Excluding alternatives is not quite the same as
demonstrating a horizon.
One of the ways that X-ray observations can be used in the study of black holes
is to observe strong gravitational field effects associated with the hole that can be
isolated in the short timescale X-ray variability of the source. (Another tool is X-ray
polarimetry measurements. See R. Stark's contribution in this volume.) For example,
the mass and angular momentum of a black hole are two properties that can, in
principle, be determined by external measurements. These properties of the hole
determine the innermost marginally stable orbit around the hole, which, in turn,
sets the inner boundary of the accretion disk. For a known mass, the period of the
innermost stable orbit is a function of the magnitude and direction of the angular
momentum of the hole. Thus, if we knew the mass and could measure the innermost
stable orbit period, the angular momentum of the hole could be determined.
There is some evidence that emission from the inner disk can be isolated.
From observations of the rapid X-ray variability from Cygnus X-I, Meekins, et al.
(1984) found that a substantial fraction of the emission was modulated near a
preferred timescale of 3 milliseconds. Order of magnitude considerations show that
the timescale and magnitude of these fluctuations require an origin in the inner
accretion disk. In addition, a turnover in the variability power was found on
timescales shorter than 3 ms. This may signal detection of the inner edge of the disk.
It must be stressed that these results were based not on the detection of single
bursts but rather from the study of long strings of data. In other words the bursts
are not studied singly but in a statistical aggregate. An XLA class instrument is
needed to see individual burst events and measure their temporal profiles and energy
100
spectra. These observations should lead to a much improved theory of the inner edge
of the disk and therefore its use as a probe of the gravitational metric in this region.
In this talk we have stressed two applications of X-ray timing observations
with a large area detector. There are many others. In conclusion, we point out that
the historical experience in X-ray timing, from the UHURU satellite onward, has been
one of continual surprise. EXOSAT (launched 1983) is particularly remembered for
the discovery of quasiperiodic oscillations in neutron stars: a phenomenon that was
unforseen when EXOSAT was launched. In the age of the NASA Space Station, it will
be possible to construct instruments with 100 m 2 aperture and the commensurate data
handling capability that will make possible X-ray timing observations on timescales
as short as a few tens of microseconds. These timescales are at least a factor of 1,000
shorter than the shortest accessible with past and current generation satellites and
about 10 5 shorter than typical capabilities. This is a largely unknown territory but,
based on past experience, we can anticipate many important discoveries.
REFEREN__,S
Chandrasekhar, S. 1970, Phys. Rev. Lett., 24, 611.
Friedman, J. L., and Schutz, B. F. 1978, Astrophys. J., 222, 281.
Meekins, J. F., et al. 1984, Astrophys. J., 278, 288.
Wagoner, R. V. 1984, Astrophys. J., 278, 345.
Wood, K. S., and Michelson, P. F. 1988 in Experimental Gravitational Physics, P. F. Michelson and Hu En-ke,
eds. (World Scientific Publishing Co., Singapore).
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DISCUSSION
SCHUTZ: I'd like to reinforce what you said about the relation of this experiment to
ground-based gravitational wave detectors. If we could detect Wagoner's accretion-
driven unstable neutron stars we would learn a great deal about neutron star
structure and the equation of state of neutron matter. But even broad-band laser
interferometers may not have sufficient sensitivity to detect the gravitational waves
without using narrow-banding techniques to enhance sensitivity at the frequency
of the wave. So they will need to know this frequency ahead of time, and XLA can
make a big contribution to gravitational wave astronomy.
WOOD: Yes, that's correct. In principle one could use either type of detector,
gravitational wave or X-ray, for initial discovery of the continuous-wave signal and
then look in the other channel at the frequency that had been discovered. It appears
that prospects for initial discovery are far better in X-rays. I should stress that it is
important to know not only the frequency of the CFS signal in the center-of-mass
frame of the neutron star but also the orbital elements of the binary system, because
orbital motion introduces a substantial frequency modulation. The large X-ray
aperture overcomes the FM by providing sufficient sensitivity for detection in a
small fraction of an orbital period, and once the signal is found, it can be used to
work out the necessary orbital elements. The X-ray and gravitational wave
observations contribute complementary information about the source.
WEISS: Can you compare XLA with XTE? (The X-ray Timing Explorer).
WOOD: XLA represents the genera and has far greater capability. XLA is 200 times
larger and has a maximum telemetry data rate several hundred times greater than
that of XTE, both of which are needed for working at higher signal-to-noise on very
short timescales. The two experiments operate in the same energy range and can
isolate essentially the same set of sources (excepting transients active for one and not
the other). XLA can make all the observations that XTE's proportional counter array
can make, but it also can carry out other observations that go far beyond XTE's
capabilities. These latter observations are the ones that have been discussed here.
Being 100 times larger does not make it 100 times as expensive. There should be very
significant economies of scale in the manufacture of many proportional counters.
Some of the functions 0f the free-flyer satellite that carries XTE are in the case of XLA
provided by the Space Station, for example power and telemetry. The Space Station
provides maintenance access as well.
HELLINGS: Can this detector act as a polarimeter in the sense of Richard Stark's
suggestion?
WOOD: There is a possibility that polarimetry capability could be incorporated, by
measuring the pulse rise time as well as the amplitude for each X-ray event. This
approach was examined some years ago and found to be sufficiently sensitive only
when there are very large numbers of photons, but that is exactly what the large
area of XLA provides. This issue needs to be re-examined in the XLA context. In any
X-ray polarimetry it is essential to be able to distinguish real polarization effects
from spurious effects of instrumental origin. Laboratory work on that is needed.
SHAPIRO: What sort of angular resolutions do you expect to obtain with your array
and how do you plan to achieve them?
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WOOD: The basic proportional counter units have mechanical collimators that
provide a field of view of 1 square degree. This is sufficient to isolate the bright
sourcesthat will be used for the timing work, i.e., the 2000 brightest sources in the
sky. It would be straightforward to have a co-aligned monitor imaging detector
observing the field simultaneously. (A coded aperture could monitor the field with
resolution of a few arcminutes.) We regard this as an option, not absolutely essential,
becausein those caseswhere it was desirableto monitor the field of view it might be
possible to arrange simultaneousobservation with another instrument such as AXAF.
Very high angular resolution for mapping on fine scales is achieved by using
XLA in conjunction with a distant occulting edge that moves slowly across the field of
view, either a natural occulter (the moon) or an artificial one. The angular
resolution achievable varies with the source and observing configuration, but it
would be possible to reach milliarcsecondson sourcesas faint as the brighter quasars
and active galactic nuclei. One must be able to see the source at sufficient signal-to-
noise in the time the occulter sweepsthe angular scale of interest. This is roughly a
thousandfold better than the best angular resolution achievable in X-rays by other
means.
FAIRBANK: What is the angular resolution if you provide a knife edge with another
satellite?
WOOD: There are several reasonsto provide an artificial satellite with a smooth edge
that can be steered around to provide artificial occultations. The machined edge
removes the necessity for knowing the lunar terrain in the region that provides the
occultation, which means that the limit on angular resolution with a bright source
will be set by diffraction and might become as fine as 100 micro-arcseconds. It is
possible to steer the artificial occulter to any point on whole sky, so that there is
access to a much larger sample of targets, and the artificial occultations can be
scheduledto occur at convenient times.
To get the occulter to move slowly enoughit must be at roughly the distanceof
the moon. The technical problems involved in realizing precision navigation of a
satellite is such a high orbit are (i) minimizing the control impulse (propellant)
required for navigation and (ii) the error budget, that is, determining what
correctionto apply to achieveoccultation. A study done by NRL and Stanford showed
that both problems could be solved by placing the satellite in an orbit perpendicular
to the lunar orbit and suitably phased so that the gravitational pull of the moon
advancesthe orbit plane without fuel expenditure. Control impulse is applied only to
in-track maneuvering.
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