|
Bulk
Source of Universe's Gamma Rays Identified, Say Columbia
and Barnard Scientists
Reshmi
Mukherjee |
New
York, NY, August 8, 2002-- Scientists at Columbia University
and Barnard College have found that the majority of the
gamma rays outside of our galaxy are likely emitted by galaxy
clusters and other massive structures. This may resolve
a 30-year-old mystery as to the origin of the Universe's
gamma-ray background.
The finding may also provide new insight about how structure
formed in the Universe, as well as the nature of magnetic
fields in the intergalactic medium, of which little is currently
known.
Caleb Scharf of Columbia University and Reshmi Mukherjee
of Barnard College publish this result in an upcoming issue
of the Astrophysica Journal. The finding is based
on the analysis of a nine-year record of gamma rays arriving
at Earth from deep space, collected by NASA's Compton Gamma
Ray Observatory throughout the 1990s.
|
Gamma
rays may map regions of early structure formation
in the Universe.
|
"This
result not only resolves the question of where all these
gamma rays are coming from, but provides a new probe of
the gravity-driven picture of structure formation in the
Universe," said Scharf.
Gamma
rays are the highest-energy form of light. In the Milky
Way galaxy, gamma rays are largely produced when cosmic
rays, atomic particles moving at near light speed, collide
with interstellar gas. Black holes and neutron stars are
also sources of gamma rays.
Galaxy clusters are the largest gravitationally bound structures
in the Universe. The clusters in this analysis contain up
to several thousand Milky Way-size galaxies, and they are
still accumulating material (gas and whole galaxies) from
the surrounding space.
The finding announced today is a confirmation of a theory
of gamma-ray production posed by Prof. Avi Loeb of Harvard
University and Prof. Eli Waxman of the Weizmann Institute
in Rehovot, Israel. Not unlike a black hole, the sheer mass
of a cluster serves as a gravitational drain, drawing in
matter at speeds of up to a thousand miles per second. Electrons
in this flow are accelerated, with an additional boost from
magnetic fields, to near light speed and collide with microwave
light, the afterglow from the big bang known as the cosmic
microwave background.
These microwave light particles, or photons, are bumped
up to the gamma-ray photon energy level. The gamma rays
form a halo around the galaxy clusters. Other scientists,
however, have suggested that the bulk of the gamma-ray background
is produced not by this mechanism but by quasar-type galaxies,
called blazars, each powered by a supermassive black hole.
This background was discovered by NASA's second Small Astronomy
Satellite (SAS-2) in the early 1970s.
Scharf and Mukherjee's new research compared a catalog of
2,469 galaxy clusters with the Compton database. Using sophisticated
statistical techniques, they showed that the sky surrounding
the most massive clusters was systematically brighter in
gamma rays than other regions.
"The more massive the cluster (and greater the gravitational
potential), the brighter the gamma-ray halo," said
Mukherjee. "The enhancement observed was very similar
to that predicted by the Loeb-Waxman theory."
The result announced today also supports the theory of the
cosmic web. Scientists say that matter in the Universe forms
a cosmic web, in which galaxies are formed along filaments
of ordinary matter and dark matter like pearls on a string.
Clusters form at the intersection of these filaments. The
electrons that fuel the gamma-ray production rush into clusters
along these rivers or filaments of matter connecting galaxies
and clusters. Thus, gamma rays serve as probes to the early
structure-forming epoch of the Universe.
Gamma ray halos around clusters also provides a means to
measure intergalactic magnetic fields. Two of the three
variables to measure magnetic fields are known: the mass
of galaxy clusters and the distribution of the microwave
background. The third variable is electron efficiency, which
can now be measured by virtue of gamma-ray production.
The Gamma-ray Large Area Space Telescope (GLAST), scheduled
for launch in 2006, should resolve gamma-ray haloes around
galaxies with unprecedented clarity. GLAST could measure
intergalactic magnetic fields and watch the formation of
structure in the universe through its gamma-ray eyes, the
scientists said.
Click
here to visit NASA's Goddard Space Flight Center news
page, which includes gamma ray animations.
###
CONTACT:
Caroline Ladhani, Columbia University
(212)854-6581
CL2059@columbia.edu
Suzanne Trimel, Barnard College
(212) 854-7583
strimel@barnard.edu
|
