First we had dark mass, now we
have gamma ray emitters without sources.
Surely these are not black holes?
Away we go again. Cosmology is
wonderful in producing masses of untestable hypothesis on the basis of an
infinite amount of apparent data.
I would anticipate a collapsing
object to finish off with gamma rays.
This is at least recognition that
a slew of objects will not show any other signature and that it is certainly
not a statistical anomaly.
On the other hand, dark matter
seems to be the theory presently in fashion, so maybe it is a dark black
hole. Since our understanding of that
phenomenon is slim it becomes an exercise of who is to say? I personally anticipate that we will discover
that gravitational collapse structures pass through a quasar phase in which
mass is consumed and ejected as photonic energy and that the remnant often ends
up as a small dense gamma emitting body.
These objects may be surrounded by lots of dust.
In the meantime our picture of
the universe is becoming richer and richer and deeply in need of stereoscopic
viewing.
600 Mysteries in the Night Sky
Oct 18, 2011: NASA's Fermi team recently released the second
catalog of gamma-ray sources detected by their satellite's Large Area Telescope
(LAT). Of the 1873 sources found, nearly 600 are complete mysteries. No one
knows what they are.
"Fermi sees gamma rays coming from directions in the sky where
there are no obvious objects likely to produce gamma rays," says David
Thompson, Fermi Deputy Project Scientist from Goddard Space Flight Center.
An all-sky map of gamma-ray emissions made by the Fermi Space
Telescope. Hundreds of the sources in the map are complete mysteries.]
Gamma rays are by their very nature heralds of great energy and
violence. They are a super-energetic form of light produced by sources such as
black holes and massive exploding stars. Gamma-rays are so energetic that
ordinary lenses and mirrors do not work. As a result, gamma-ray telescopes
can't always get a sharp enough focus to determine exactly where the sources
are.
For two thirds of the new catalog's sources the Fermi scientists can,
with at least reasonable certainty, locate a known gamma ray-producing object*,
such as a pulsar or blazar, in the vicinity the gamma-rays are coming from. But
the remaining third – the "mystery sources" -- have the researchers
stumped, at least for now. And they are the most tantalizing.
Nearly 600 sources in the latest Fermi catalog are unidentified.
"Some of the mystery sources could be clouds of dark matter –
something that's never been seen before," speculates Thompson.
About 85% of the gravitational mass of the universe is dark matter. The
stuff we see makes up the rest. Dark matter is something that pulls on things
with the force of its gravity but can't be detected in any other way. It
doesn't shine – doesn't emit or scatter light – hence the adjective
"dark."
Astronomers cannot detect dark matter directly using optical or radio
telescopes. But dark matter just might shine in gamma rays.
"We've been using Fermi to search for dark matter for a long
time," says the principal investigator for the Large Area Telescope, Peter
Michelson of Stanford
University .
Some researchers believe that when two dark matter antiparticles bump
into each other, they will annihilate, producing gamma rays. Concentrated
clouds of dark matter could form a gamma ray source at specific wavelengths
detectable by Fermi.
"If we see a bump in the gamma-ray spectrum -- a narrow spectral
line at high energies corresponding to the energy of the annihilating particles
– we could be the first to 'apprehend' dark matter,” says Michelson.
The team plans to continue observing the mystery sources. Fermi scans
the entire sky ever three hours, and this ongoing sequence of observations
"piles up" gamma rays for the researchers to analyze. So far, too few
gamma rays have been collected from the mystery sources to form definite
conclusions.
Colliding galaxy clusters are one possible explanation for the mystery
sources.
Another, less-dark possibility for some of the mystery sources is
colliding galaxy clusters. According to Michelson and Thompson, clashes of such
magnitude would generate super large scale shock waves that would accelerate
particles. Others of the sources, they say, might be some brand new phenomenon,
perhaps something involving galactic black holes.
When all is said and done, many of the mystery sources could prove to
be familiar. "[They] will probably turn out to be members of known source
classes – things we know but haven't recognized yet, like undiscovered pulsars,
binary systems, and supernova remnants," says Michelson.
"Of course we're hoping for something really exotic like dark
matter, but we have to look first at all the other options," says
Thompson. "Fermi is an ongoing mission. We'll continue to search for
answers to these puzzles and perhaps turn up even more surprises."
Will notorious dark matter finally be nabbed? Stay tuned!
Fermi Gamma-ray Space Telescope --
home page
Footnote: *Among the known classes in the second Fermi LAT catalog
are almost 100 gamma-ray pulsars -- super dense neutron stars that are blinking
in gamma rays. They are 1 ½ times the mass of our sun, but crushed to the size
of a city."Pulsars rotate rapidly and the light from them sweeps past us
like light from a light house," explains Thompson. "Some of them
rotate as fast as a kitchen blender -- hundreds of times per second!" The
LAT team has rock- solid identification on 83 pulsars in our own galaxy. But
the largest single class of gamma-ray sources the LAT "sees" is
blazars from active galactic nuclei. Blazars make up over 1000 of the 1873
sources. "They are of course extra-galactic," says Michelson.
"Only about 25 of these are rock solid identifications, but we believe the
others, because of their location, are likely associated with active galactic
nuclei blazars too." Active galactic nuclei are the cores of galaxies.
"The gamma rays are probably coming from the vicinity of black holes,
which have 1 million to 1 billion times the mass of our sun," says
Thompson. "A black hole pulls everything into itself by virtue of its
unbelievable strong gravity. As it does so, enormous energy is released and
squirted away from the black hole as a beam of particles and radiation moving
at nearly the speed of light. It's called a blazar if the jet is aimed at us
and we are looking down the barrel. But the jet of energy doesn't come out of
the black hole itself; rather it is powered by material falling into the black
hole." Binary systems constitute another known source class in the new
catalog. They are made up of a neutron star or black hole orbiting a large
normal star.
Credits: NASA's Fermi Gamma-Ray Space Telescope mission is an
astrophysics and particle physics partnership, developed in collaboration with
the U.S. Department of Energy, along with important contributions from academic
institutions and partners in France, Germany, Italy, Japan, Sweden, and the
United States. The mission's main instrument, the Large Area Telescope (LAT),
is making pioneering observations of gamma-ray bursts at higher energies than
ever before from space. Another instrument onboard, the Fermi Gamma-Ray Burst
Monitor, is monitoring gamma-ray bursts at lower energies. The combination of
the GBM and the LAT provides a powerful tool for studying GRBs over a very wide
range of energies. The GBM is a collaboration among scientists at the Marshall Space
Flight Center ,
the University of Alabama in Huntsville ,
the Max Planck Institute for Extraterrestrial Physics in Germany , and the Los Alamos
National Laboratory.
Once again speculation based on gravitational cosmology will yeild only confusion and misinformation.
ReplyDeleteDark matter doesn't exist emperically.
Electric universe.