Printer Friendly

The last three minutes: computing the shape of gravitational waves.

Locked by gravity into a madly whirling partnership, two neutron stars inexorably spiral inward to a final, frenzied embrace. As the partners draw closer together, they swing around each other faster and faster. Each star tugs on the other, stretching it more and more out of shape. Finally, they touch and coalesce.

According to Einstein's general theory of relativity, this suicidal stellar dance also creates extreme distortions in the geometry of the space surrounding the stars. Theorists believe these spacetime disturbances travel outward as gravitational waves that imperceptibly jostle any objects in their paths. During the last few minutes before coalescence, the waves may be strong enough that sensitive detectors on Earth, millions of light-years away, have a chance of reading their distinctive signatures.

By the end of this century, researchers hope to have in operation a network of instruments for detecting gravitational waves produced by spiraling pairs of neutron stars and of black holes. Construction of the two detectors for the Laser Interferometer Gravitational Wave Observatory (LIGO) is set to start later this year in Livingston, La., and Hanford, Wash. (SN: 2/29/92, p.134). Scientists in France and Italy are collaborating on a third detector, VIRGO, to be built near Pisa, Italy.

To help tease out a gravitational wave signal hidden in the noise that will inevitably rattle these detectors, theoretical physicists have now taken on the challenging task of predicting what the signals will look like. Initial results from one of these efforts suggest that physicists may glean more information from these signals than they had previously thought possible.

In the May 17 PHYSICAL REVIEW LETTERS, researchers from the California Institute of Technology in Pasadena and Northwestern University in Evanston, Ill., contend that it may be possible not only to detect gravitational waves but also to infer the masses of the spiraling partners responsible for the waves. Analysis of signals emanating from distant pairs may also lead to new estimates of crucial cosmological parameters, including the expansion rate of the universe and its density,

This new research effort "is changing our understanding of these [gravitational] waves," Caltech's Curt Cutler and his collaborators report. "The waveforms will be far more complex and carry more information than has been expected."

What success these theorists may have hinges on the formidable task of solving the equations underlying the general theory of relativity, The equations describe a physical force, gravity, in terms of geometry-variations in the curvature of space and time.

According to this theory, massive bodies, such as neutron stars and black holes, warp spacetime significantly. Moreover, if a massive body abruptly changes its motion or mass, spacetime in its vicinity undergoes a corresponding convulsion, which travels outward as a gravitational wave.

Although weak, these waves should create detectable gravitational disturbances when they reach Earth. Moreover, different sources of gravitational waves should generate unique wave shapes that can be deciphered to characterize the sources and identify their type.

"We need to know what these signals will look like," says Kip S. Thorne of Caltech. This means using theory to derive a family of gravitational wave "templates" to serve as guides for processing the noisy data obtained at the LIGO and VIRGO detectors - at first to find the signal and then to identify its type.

"As a foundation for this, a major effort is needed in the next few years to compute the waveforms to be expected from various sources," Thorne says. He described recent progress toward this goal and outlined important, unresolved research questions at a symposium on future directions in general relativity research, held last month at the University of Maryland at College Park.

So far, researchers have concentrated mainly on the shapes of gravitational waves emanating from black-hole and neutron-star binaries. Along with the whirling descent of small black holes, neutron stars, and white dwarf stars into supermassive black holes, "these sources are expected to be the 'bread and butter' of the LIGO/ VlRGO ... diet," Thorne says. "Their waveforms should exhibit a wide variety of behaviors that carry a rich harvest of physical and astronomical information."

In the last three minutes before coalescence, spiraling binaries would generate gravitational waves that rapidly sweep upward in frequency from 10 hertz to 1,000 hertz, producing a distinctive "chirping" signal. Earth-based interferometers would observe several thousand cycles of this process.

New theoretical studies reveal that this chirping signal has a form so complicated that researchers could use it to infer the masses, spins, and orbital paths of the two bodies producing the gravitational radiation. From the inferred masses, scientists would have a good idea whether they were observing black holes or neutron stars.

In the final seconds before coalescence, the signal would change to reflect "tidal" distortions that the bodies induce in each other's shape just before they merge. In the case of two neutron stars, complete coalescence would occur within a few revolutions spanning less than a second, thereby shutting off the gravitational wave signal quite abruptly.

In principle, physicists could use the details of the coalescence waveforms to establish how a neutron star's mass depends on its radius. From this information, they could infer such characteristics as the density and composition of the nuclear matter making up these highly compact, massive stars. The possibility that stellar and black-hole coalescence also produces intense bursts of gamma rays adds to the interest in modeling the behavior of these binaries.

One intriguing possibility involves the use of gravitational wave signals from binaries in galaxies beyond the Milky Way as a cosmological probe. By determining the characteristics of a large number of binaries in which at least one partner is a neutron star, physicists could establish more firmly the relationship between distance and redshift - the increase in the characteristic wavelengths of light emitted by stars - caused by the expansion of the universe.

"By contrast with electromagnetic cosmological measurements, which suffer from light absorption and source evolution, this method will suffer just one type of propagation noise (gravitational lensing by mass inhomogeneities)," Cutler and his collaborators contend in their paper. Computer simulations show that signal distortions due to the bending of gravitational waves around large masses, such as distant galaxies, should be negligible compared with detector noise.

The central problem that theorists hope to solve before the gravitational wave observatories come on line concerns the behavior of a pair of orbiting, spinning black holes (SN: 9/3/88, p. 152). "This is the Holy Grail of numerical relativity," Thorne says.

"Interacting astrophysical black holes are potentially the strongest source of gravitational radiation accessible to detectors like the LIGO/VIRGO ... system currently under construction," says Richard Matzner of the Center for Relativity at the University of Texas at Austin.

With the increasing availability of extremely fast computers with mammoth memories and with a better understanding of how to handle and interpret the complicated equations describing the gravitational interactions of a pair of black holes, this task now appears feasible, Matzner remarks.

Researchers are exploring several avenues toward solving the problem and eventually simulating in three dimensions the evolution of black-hole behavior, given any mass ratio and spin rate. So far, most efforts have concentrated on special cases involving two-dimensional black holes that aren't spinning (see box).

"We have a lot of work to do," Matzner says. "Maybe in five years we'll be able to predict the radiation emitted [by a blackhole binary]."

The race is on. Can the theorists calculate and predict what the waveforms will look like before the observers detect their first gravitational wave signals?

A variety of obstacles stand in the way of both the theoretical work and the construction of the detectors. Both projects are massive undertakings. Both face unforeseeable technical difficulties. And LIGO itself will cost about $250 million and must endure continued congressional scrutiny,

But if both endeavors succeed, a new field of astrophysics could open up around the study and interpretation of gravitational waves.
COPYRIGHT 1993 Science Service, Inc.
No portion of this article can be reproduced without the express written permission from the copyright holder.
Copyright 1993, Gale Group. All rights reserved. Gale Group is a Thomson Corporation Company.

Article Details
Printer friendly Cite/link Email Feedback
Title Annotation:network of gravitational wave detectors planned
Author:Peterson, Ivars
Publication:Science News
Article Type:Cover Story
Date:Jun 26, 1993
Previous Article:Prolonged nursing and the risk of bone loss.
Next Article:Ringing a black hole.

Related Articles
Intimations of gravity waves.
A satellite triangle for gravity waves.
Relativity by the numbers: supercomputers help physicists picture collapsing stars and gravitational waves.
Found: memories of gravitational waves.
Two sites for catching gravitational waves.
A new X-ray in the sky.
Ringing a black hole.
Catch a Wave.
Superstar Search.
Whirling to a chaotic finale.

Terms of use | Copyright © 2016 Farlex, Inc. | Feedback | For webmasters