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Astronomy Picture of the Day |
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Astronomy Picture of the Day |
APOD: November 28, 1998 - A Lonely Neutron Star
Explanation:
How massive can a star get without imploding into a black hole?
These limits are being tested by the discovery of a lone
neutron star in space.
Observations by the Hubble Space Telescope
have been combined with previous observations by the
X-ray
ROSAT observatory and
ultraviolet
EUVE
observatory for the isolated star at the location of the arrow.
Astronomers are able to directly infer the star's size from
measurements of its unblended brightness, temperature, and an upper
limit on the distance.
Assuming that the object is a
neutron star of typical mass,
some previous theories of neutron star structure would have predicted
an implosion that would have
created a black hole.
That this neutron star
even exists therefore allows a window to the extreme
conditions that exist in the interiors of neutron stars.
APOD: November 22, 1998 - The High Energy Crab Nebula
Explanation:
This is the mess that is left when a star explodes. The
Crab Nebula
is so energetic that it glows in
every kind of light known.
Shown above are images of the
Crab Nebula from visible light to the
X-ray band.
NUV stands for "near
ultraviolet" light, FUV means "far
ultraviolet" light, and VIS means visible light. In the center of the
Crab Nebula lies the powerful
Crab pulsar - a spinning
neutron star with mass comparable to our
Sun but with the diameter of only a
small town.
The pulsar expels particles and radiation in a beam that sweeps past the
Earth 30 times a second. The
supernova that created the
Crab Nebula was seen by
ancient
Chinese astronomers and possibly even the
Anasazi Indians -- in 1054 AD, perhaps glowing for a
week as bright as the
full moon. The Crab
still presents mysteries today as the total mass of the nebula and pulsar appears much less than the mass of the original pre-supernova star!
APOD: November 12, 1998 - GLAST Gamma Ray Sky Simulation
Explanation:
This simulated image models the intensities
of gamma rays
with over 40 million times the energy of visible light,
and represents how the sky might appear to the
proposed Gamma-ray Large Area Space Telescope (GLAST)
after its first year in orbit.
Familiar steady stars are absent from
the dramatic 80x80 degree field which looks directly
away from the center of the Galaxy.
Instead,
the Geminga and
Crab pulsars - bizarre, spinning
stellar corpses known to be
neutron stars - are the two brightest
gamma-ray sources.
These and other bright objects in the field,
dense pulsars,
monstrous active galaxies,
and still unknown sources, have been detected by the
Energetic Gamma-Ray Experiment Telescope (EGRET)
on the orbiting
Compton Gamma-Ray Observatory.
However, most of the simulated point sources are new - extrapolating
current ideas and anticipating discoveries
resulting from GLAST's improved gamma-ray vision.
The central broad band of faint gamma-ray emission is
due to high-energy cosmic rays
colliding with interstellar gas in the outer spiral arms of
the Milky Way, while
below is a diffuse energetic glow from
prominent molecular clouds
in Monoceros, Orion, Auriga, and Taurus.
Intended to explore the most extreme energy sources in
the distant cosmos and planned for launch in 2005,
the GLAST mission
is under development by
NASA and a collaboration of U. S. and international partners.
APOD: October 2, 1998 - Magnetar In The Sky
Explanation:
Indicated on this
infrared image of the galactic center region
is the position of SGR 1900+14 - the strongest known magnet in the galaxy.
SGR 1900+14 is believed to be a
city-sized,
spinning, super-magnetic neutron star,
or Magnetar.
How strong is a Magnetar's magnetic field?
The Earth's magnetic field which deflects compass needles is measured
to be about 1 Gauss,
the strongest fields sustainable in Earth-based laboratories are
about 100,000 Gauss, yet the Magnetar's monster magnetic field
is estimated to be 1,000,000,000,000,000 Gauss.
A magnet this strong, located at about half the distance to the Moon
would easily erase your credit cards and suck pens out of your pocket.
From a distance of about 20,000 light-years,
SGR 1900+14 recently generated
a powerful flash of gamma-rays detected
by many spacecraft.
That blast of high-energy radiation is now known to have
had a measurable effect on Earth's ionosphere.
At the surface of the Magnetar,
its powerful magnetic field is thought to buckle and shift the neutron
star crust generating the intense gamma-ray flares.
APOD: September 5, 1998 - The Pulsar Powered Crab
Explanation:
In the Summer of 1054 A.D.
Chinese astronomers reported
that a star in the
constellation of Taurus suddenly became as bright as the full Moon.
Fading slowly, it remained visible for over a year.
It is now understood
that a spectacular supernova explosion -
the detonation of a massive star whose remains
are now visible as the Crab Nebula-
was responsible for the apparition.
The core of the star collapsed to form a rotating
neutron star or
pulsar,
one of the most exotic objects known to 20th century astronomy.
Like a cosmic lighthouse, the rotating Crab pulsar generates beams of
radio, visible, x-ray and gamma-ray energy which, as the name
suggests, produce pulses as they sweep across our view.
Using a stunning series of
visible light images taken with
the Hubble Space Telescope (HST), astronomers have discovered
spectacular pulsar powered motions within the Crab nebula.
Highlights of this
HST Crab "movie" show wisps of material moving
away from the pulsar at half the speed of light, a scintillating halo,
and an intense knot of emission dancing, sprite-like, above the pulsar's pole.
Only 6 miles wide but more
massive than the sun, the pulsar's energy drives the dynamics and emission
of the nebula itself which is more than 10 lightyears across.
In this HST image,
the pulsar is the left most of the two bright central stars.
APOD: September 3, 1998 - SGR 1900+14 : Magnetar
Explanation:
On August 27th
an intense flash of X-rays
and gamma-rays swept through our Solar System.
Five spacecraft of the
Third InterPlanetary gamma-ray burst Network,
Ulysses,
WIND,
RXTE,
NEAR, and
BeppoSAX,
recorded the high energy signal --
a signal so strong that it saturated detectors on WIND and RXTE and
triggered the safety mode
automatic shut-off of the NEAR gamma-ray instrument!
As plotted here, the count rate for the Ulysses detector abruptly
spiked to a high level and then slowly tailed off showing
smaller peaks roughly every 5 seconds.
The signal and location provided by these spacecraft observations leads
researchers to identify the source as a dramatic flare-up from
one of only
four previously known "Soft Gamma Repeaters" .
These exotic
sources of gamma-rays are believed to be
highly magnetized spinning neutron stars
called Magnetars.
Imaginatively cataloged as
SGR 1900+14, this magnetar
is estimated to have been
born in a supernova explosion
about 1,500 years ago and to have a magnetic field
500,000,000,000,000 times stronger
than Earth's.
APOD: July 29, 1998 - The High Energy Heart Of The Milky Way
Explanation:
These high resolution false color pictures of the Galactic center
region in high energy
X-ray and gamma-ray light result from a very long
exposure of roughly 3,000 hours performed from 1990 to 1997 by the
French SIGMA telescope onboard the
Russian GRANAT spacecraft.
Each image covers a 14x14 degree field which includes most of the
central bulge of
our Milky Way Galaxy.
The X-ray picture (left) reveals a cluster of sources
releasing enormous amounts of energy.
They are probably
binary star systems where matter accretes
onto a collapsed object, either
a neutron star or
a black hole.
But
according to recent theories, only those
binary systems with black holes
can radiate above X-ray energies -- in the gamma-ray regime.
In that case, the SIGMA sources also shining in the gamma-ray picture
(right) betray the presence of accreting
stellar black holes!
Surprisingly, no high energy source seems to coincide exactly
with the Galactic center itself,
located near the brightest source at the bottom of both
pictures.
This indicates that
the large black hole
thought
to be lurking there
is unexpectedly quiet at these energies.
APOD: July 23, 1998 - X Ray Pulsar
Explanation:
This dramatic artist's vision shows a
city-sized
neutron star
centered in a disk of hot plasma drawn from
its enfeebled red companion star.
Ravenously
accreting material from the disk,
the neutron star spins faster and faster
emitting powerful particle beams and pulses
of X-rays as it rotates 400 times a second.
Could such a bizarre and inhospitable star system really exist in
our Universe?
Based on data from the orbiting
Rossi X-Ray Timing Explorer (RXTE)
satellite, research teams have
recently announced a discovery which fits
this exotic scenario well - a "millisecond" X-ray pulsar.
The newly detected celestial X-ray beacon
has the unassuming catalog
designation of SAX J1808.4-3658 and is located a comforting
12,000 light years away in the
constellation Sagittarius.
Its X-ray pulses offer evidence of rapid,
accretion powered rotation
and provide a much sought after
connection between
known types of radio and X-ray
pulsars and the
evolution
and ultimate demise of
binary star systems.
APOD: May 27, 1998 - Magnetar
Explanation:
What do you call a neutron star with a super-strong magnetic field?
You guessed it ... a Magnetar.
Imagine a star with more mass than the sun,
the density of a neutron, and
a magnetic field about a thousand trillion (a one followed by
15 zeroes) times stronger than Earth's.
It sounds exotic and theoretical, but
strong evidence for the existence of magnetars has recently
been announced based
on data from orbiting
X-ray and
Gamma-ray observatories.
Neutron stars are formed in the violent crucibles of stellar explosions.
Some become pulsars
with relatively weak magnetic fields,
spinning and emitting pulses of
electromagnetic radiation as their rotation slows.
However, astronomers now believe that some become magnetars,
with magnetic fields so intense that the solid neutron star crust
buckles and shifts under its influence.
The resulting star quakes could repeatedly
generate brief flashes of hard X-rays and soft gamma-rays
giving rise to the rare but
mysterious "soft gamma repeaters"
(not to be confused with "
gamma-ray bursters"!).
This still frame from an
animation illustrating a spinning, flashing magnetar
emphasizes the looping magnetic field lines embedded in the X-ray hot
neutron star surface.
APOD: May 7, 1998 - A Powerful Gamma Ray Burst
Explanation:
Gamma-ray bursts are thought to be the most powerful explosions in
the Universe, yet the cause of these high-energy flashes
remains a mystery.
Blindingly
bright for
space-based gamma-ray detectors the burst sources are
so faint at visible wavelengths that
large telescopes and sensitive cameras are required to search for them.
The faint optical flash from
a relatively intense gamma-ray burst
detected on December 14th of last year seems to have originated in
the galaxy indicated in
this Hubble Space Telescope image - taken
months after the burst had faded from view.
Astronomers have recently announced that
this galaxy's spectrum, recorded using the large
Keck telescope atop Hawaii's Mauna Kea,
indicates that it lies at a distance of about 12 billion light-years.
The energy required to produce the observed flash of gamma-rays from
this distance would be staggering!
Some estimates suggest that in a few seconds the
burster released the equivalent energy of several hundred
supernovae (exploding stars).
The eruption of such a large amount of energy in such a short time is
so extreme that even
exotic theoretical models
of the bursters are being challenged.
Could the bursts be caused by
the cataclysmic merger of
neutron stars
with black holes ... or something as yet unknown?
APOD: April 25, 1998 - Supernova Remnant and Neutron Star
Explanation:
A massive star ends life as a supernova, blasting
its outer layers back to interstellar space.
The spectacular death explosion is
initiated by the collapse of what has become an impossibly dense
stellar core.
However, this core is not necessarily destroyed. Instead, it may be
transformed into an exotic object with the density of an
atomic nucleus but more total mass
than the sun -
a neutron star.
A neutron star is hard to detect directly because it is
small (roughly 10 miles in diameter)
and therefore dim, but newly formed in this violent crucible
it is intensely hot,
glowing in X-rays.
These
X-ray images from the orbiting ROSAT observatory may offer a premier
view of such a recently formed neutron stars' X-ray glow.
Pictured is the supernova
remnant Puppis A, one of the brightest
sources in the X-ray sky,
with shocked gas clouds still expanding and
radiating X-rays. In the inset close-up view,
a faint pinpoint source of X-rays is visible which is most likely
the young neutron star,
kicked out by the asymmetric explosion and
moving away from the site of the original supernova at about 600 miles
per second.
APOD: March 21, 1998 - The Gamma Ray Sky
Explanation:
What if you could "see" gamma rays?
If you could, the sky would seem to be filled
with a shimmering high-energy glow from
the most exotic
and mysterious objects in the Universe.
In the early 1990s NASA's orbiting Compton Observatory,
produced this premier vista of the entire
sky in gamma rays
- photons with more than 40 million times
the energy of visible light.
The diffuse gamma-ray glow from the plane of
our Milky Way Galaxy runs horizontally through the false color image.
The brightest spots in the galactic plane (right of center)
are pulsars - spinning magnetized neutron stars
formed in
the violent crucibles of stellar explosions.
Above and below the plane,
quasars,
believed to be powered by supermassive
black holes, produce gamma-ray beacons at the edges of the universe.
The nature of many
of the fainter sources remains unknown.
APOD: February 11, 1998 - Ultra Fast Pulsar
Explanation:
Pulsars are rotating
neutron stars, born in the violent
crucibles of supernova explosions.
Like cosmic lighthouses, beams of radiation from surface hotspots sweep
past our viewpoint creating pulses which reveal the rotation rates
of these incredibly dense stellar corpses.
The most famous pulsar of all is found in the nearby supernova
remnant, the Crab Nebula.
The Crab's young pulsar is fast.
Rotating at 33 times a second,
its radiation energizes the surrounding
gaseous stellar debris.
But using
archival observations from orbiting X-ray telescopes,
astronomers have recently identified another "Crab-like" pulsar
that is even faster.
Located in the Large Magellanic Cloud (LMC),
X-ray pulses from this newly discovered pulsar,
in the supernova remnant N157B,
indicate an even faster rotation rate - 62 times a second -
making it
the fastest known pulsar associated with a supernova remnant.
This contoured, false color X-ray image of
a portion of the LMC
shows the location of N157B along with
the core of the nearby
hot star cluster R136,
and the site of another Crab-like pulsar in SNR 0540-69.3
(rotating a mere 20 times a second).
The image is about 1,500 light-years across.
APOD: February 8, 1998 - M1: Filaments of the Crab Nebula
Explanation:
The Crab Nebula, filled with mysterious filaments, is the result of a
star that exploded in 1054 AD.
This spectacular supernova
explosion was recorded by Chinese and (quite probably) Anasazi Indian astronomers.
The filaments are mysterious because they appear
to have less mass than expelled in the original supernova
and higher speed than expected from a free explosion.
In the above picture, the color indicates what is
happening to the electrons in different
parts of the Crab Nebula.
Red indicates the electrons are recombining with protons to form neutral hydrogen,
while green indicates the electrons are whirling around the magnetic field
of the inner nebula. In the nebula's
very center lies a pulsar: a neutron star rotating, in this case, 30 times a second.
APOD: September 26, 1997 - A Lonely Neutron Star
Explanation:
How massive can a star get without imploding into a black hole?
These limits are being tested by the discovery of a lone neutron star in space. Observations by the
Hubble Space Telescope
released Wednesday,
have been combined with previous observations by the
X-ray ROSAT observatory and
ultraviolet
EUVE
observatory for the isolated star at the location of the arrow.
Astronomers are able to directly infer the star's size from measurements of its
unblended brightness, temperature, and an upper limit on the distance.
Assuming that the object is a
neutron star of typical mass,
some previous theories of neutron star structure would have predicted
an implosion that would have created a
black hole. That this
neutron star
even exists therefore allows a window to the extreme
conditions that exist in the interiors of neutron stars.
APOD: May 1, 1997 - A Galactic Cloud of Antimatter
Explanation:
The center of our Milky Way Galaxy is full of surprises.
Its latest spectacular is
a mysterious cloud glowing in gamma rays produced
by annihilating antimatter particles!
Star Trek fans are all too familiar with the consequences of mixing
matter (electrons) and antimatter (positrons) -
the particles
catastrophically annihilate
converting their masses to energy according to Einstein's famous
E=mc2.
Positron/electron annihilation energy is emitted
as gamma rays with
photon energies of 511,000 electron volts.
Searching for these high energy photons,
the OSSE instrument onboard NASA's orbiting
Compton Gamma Ray Observatory has
recently produced this map of the
Galactic Center (GC) region. As anticipated, it shows
annihilation gamma rays
as a bright spot at the GC
with fainter horizontal emission from the galactic plane.
Astoundingly, it also reveals a large and unexpected cloud
of annihilation radiation, probably about 4,000 light years across,
extending nearly 3,500 light years above the GC.
What could have created this cloud?
Associated with no previously known object,
it seems to imply that a
fountain of antimatter positrons streams from the GC.
Present guesses about the source of the positrons include
the violent and exotic environments surrounding starbirth,
neutron star collisions, and black holes at the GC.
Are there other such clouds in our Galaxy?
APOD: April 13, 1997 - Jets from SS433
Explanation: SS433
is one of the most exotic star systems known. Its unremarkable
name stems from its inclusion in a catalog of stars which emit
radiation characteristic of atomic hydrogen.
Its very remarkable behavior stems from a compact object, a black hole
or neutron star,
which has produced an accretion disk with jets. As illustrated
in this artist's vision
of the SS433 system
based on observational data,
a massive, hot star (left) is locked in a mutual orbit with a
compact object. Material transfers from the massive star into
an accretion disk surrounding the
compact object blasting out two jets of ionized gas in opposite
directions - at about 1/4 the speed of light!
Radiation from the jet tilted toward the observer is blueshifted,
while radiation from the jet tilted away is redshifted.
The binary system itself completes an orbit in about 13 days while
the jets precess (wobble like a top) with a period of about 164
days. Are the jets from SS433 related to those from black holes at the centers of galaxies?
APOD: February 22, 1997 - The Gamma Ray Sky
Explanation:
What if you could "see" gamma rays?
If you could, the sky would seem to be filled
with a shimmering high-energy glow from the most exotic
and mysterious objects in the Universe.
In the early 1990s
NASA's orbiting Compton Observatory,
produced this premier vista of the entire
sky in gamma rays
- photons with more than 40 million times
the energy of visible light.
The diffuse gamma-ray glow from the plane of
our Milky Way Galaxy runs horizontally through the false color image.
The brightest spots in the galactic plane (left of center)
are pulsars - spinning magnetized neutron stars
formed in
the violent crucibles of stellar explosions.
Above and below the plane,
quasars,
believed to be powered by supermassive
black holes, produce gamma-ray beacons at the edges of the universe.
The nature of many
of the
fainter sources remains unknown.
APOD: February 7, 1997 - M1: Filaments of the Crab Nebula
Explanation: The Crab Nebula is filled with mysterious
filaments. The Crab Nebula
is the result of a star that exploded in 1054 AD.
This spectacular supernova
explosion was recorded by Chinese
and (quite probably) Anasazi Indian
astronomers. The filaments are mysterious because they appear
to have less mass than expelled in the original supernova
and higher speed than expected from a free explosion.
In the above picture,
the color indicates what is happening to the electrons in different
parts of the Crab Nebula.
Red indicates the electrons are recombining with protons to form neutral hydrogen,
while green indicates the electrons are whirling around the magnetic field
of the inner nebula. In the nebula's
very center lies a pulsar:
a neutron star
rotating, in this case, 30 times a second.
APOD: January 15, 1997 - Black Hole Signature From Advective Disks
Explanation: What does a black hole look like? If alone,
a black hole
would indeed appear
quite black, but many black hole candidates are part of binary star systems.
So how does a black hole binary system
look different from a neutron star binary system?
The above drawings indicate it
is difficult to tell! Recent theoretical work,
however, has provided a new way to tell them apart: advective accretion flows (ADAFs).
A black hole system so equipped
would appear much darker than a similar neutron star
system. The difference is caused by the hot gas from the ADAF disk
falling through the event horizon
of the black hole and disappearing - gas that would have emitted
much light were the central object only a neutron star. Recent observations
of the soft X-ray transient
V404 Cyg
has yielded a spectrum
much like an ADAF onto a black hole
- and perhaps brighter than allowable from an ADAF onto a neutron
star.
APOD: November 14, 1996 - Supernova Remnant and Neutron Star
Explanation:
A massive star ends life as a supernova, blasting
its outer layers back to interstellar space.
The spectacular death explosion is
initiated by the collapse of what has become an impossibly dense
stellar core.
However, this core is not necessarily destroyed. Instead, it may be
transformed into an exotic object with the density of an
atomic nucleus but more total mass
than the sun -
a neutron star.
Directly viewing a neutron star is difficult because it is
small (roughly 10 miles in diameter)
and therefore dim, but newly formed in this violent crucible
it is intensely hot,
glowing in X-rays.
Images from the ROSAT X-ray observatory above may offer a premier
view of such a recently formed neutron stars' X-ray glow.
Pictured is the supernova
remnant Puppis A, one of the brightest
sources in the X-ray sky,
with shocked gas clouds still expanding and
radiating X-rays. In the inset close-up view,
a faint pinpoint source of X-rays is visible which is most likely
the young neutron star,
kicked out by the asymmetric explosion and
moving away from the site of the original supernova at about 600 miles
per second.
APOD: September 9, 1996 - The High Energy Crab Nebula
Explanation:
This is the mess that is left when a star explodes. The
Crab Nebula
is so energetic that it glows in
every kind of light known.
Shown above are images of the
Crab Nebula from visible light to the
X-ray band.
NUV stands for "near
ultraviolet" light, FUV means "far
ultraviolet" light, and VIS means visible light. In the center of the
Crab Nebula lies the powerful
Crab pulsar - a spinning
neutron star
with mass comparable to our
Sun but with the diameter of only a
small town.
The pulsar expels particles and radiation in a beam that sweeps past the
Earth 30 times a second. The
supernova that created the
Crab Nebula was seen by
ancient
Chinese astronomers and possibly even the
Anasazi Indians
-- in 1054 AD, perhaps glowing for a week as bright as the
full moon. The Crab
still presents mysteries today as the total mass of the nebula and pulsar appears much less than the mass of the original pre-supernova star!
APOD: May 31, 1996 - The Pulsar Powered Crab
Explanation:
In the Summer of 1054 A.D. Chinese astronomers reported
that a star in the
constellation of Taurus suddenly became as bright as the full Moon.
Fading slowly, it remained visible for over a year. It is now understood
that a spectacular supernova explosion -
the detonation of a massive star whose remains
are now visible as the Crab Nebula-
was responsible for the apparition.
The core of the star collapsed to form a rotating
neutron star or
pulsar,
one of the most exotic objects known to 20th century astronomy.
Like a cosmic lighthouse, the rotating Crab pulsar generates beams of
radio, visible, x-ray and gamma-ray energy which, as the name
suggests, produce pulses as they sweep across our view.
Using a stunning series of
visible light images taken with
the Hubble Space Telescope (HST), astronomers have recently discovered
spectacular pulsar powered motions within the Crab nebula.
Highlights of this
HST Crab "movie" show wisps of material moving
away from the pulsar at half the speed of light, a scintillating halo,
and an intense knot of emission dancing, sprite-like, above the pulsar's pole.
Only 6 miles wide but more
massive than the sun, the pulsar's energy drives the dynamics and emission
of the nebula itself which is more than 10 lightyears across.
In the HST image above,
the pulsar is the left most of the two bright central stars.
APOD: March 6, 1996 - Jets From SS433
Explanation:
SS433 is one of the most exotic star systems known to astronomers.
Its unremarkable name stems from its inclusion in a catalog of
stars which emit radiation characteristic of
atomic hydrogen.
Its very remarkable behavior stems from a compact
object, a
black hole or
neutron star, which has produced an
accretion disk with jets.
As illustrated in this
artist's vision of
the SS433 system based on
observational data,
a massive, hot star (left) is locked in
a mutual orbit with a compact object. Material transfers from the
massive star into
an accretion disk surrounding the
compact object
blasting out two jets of ionized gas in opposite directions -
at about 1/4 the speed of light! Radiation from the jet tilted toward
the observer is blueshifted, while radiation from the jet tilted away
is redshifted.
The binary system itself completes an orbit in about 13 days while the jets
precess (wobble like a top) with a period of about 164 days.
Are the jets from SS433 related to those from
black holes at the centers of galaxies?
APOD: February 27, 1996 - X-ray Moon and X-ray Star
Explanation:
An X-ray star winks out behind the Moon in these before and after
views of a
lunar occultation of the
galactic X-ray source designated GX5-1.
The false color images were made using data from the
ROSAT
orbiting observatory and show high energy X-rays in yellow (mostly from
GX5-1), and lower energy X-rays in red (the Moon reflecting
X-rays from the Sun). GX5-1 is a
binary system consisting of a
neutron star and a companion star in
mutual orbit about the system's center of mass.
The gas in the companion star's outer envelope falls toward the neutron star
and accumulates in a disk around it.
This disk material swirls deeper in to
the neutron star's gravitational well, and is finally dumped onto
its surface - in the process creating tremendous
temperatures and generating the high energy X-rays.
Tomorrow's picture: Explosions Discovered Near
APOD: January 3, 1996 - The X-ray Timing Explorer
Explanation:
Launched
Saturday on a Delta rocket, the
X-ray
Timing Explorer (XTE) will watch the sky for rapid changes in
X-rays.
XTE carries
three separate X-ray telescopes. The
Proportional
Counter Array (PCA) and the
High Energy
X-ray Timing Experiment (HEXTE) will provide the best
timing information in the widest X-ray energy range yet available. They
will observe stellar systems that contain
black holes,
neutron stars, and
white dwarfs as well as study the
X-ray properties of the
centers of active
galaxies.
XTE's
All Sky
Monitor (ASM) will scan the sky every 90 minutes
to find new X-ray transients and track the variability of old ones. XTE has
a planned life time of two years.
Tomorrow's picture: Symbiotic Star System R Aquarii
APOD: January 2, 1996 - The X-Ray Sky
Explanation:
What if you could see
X-rays?
If you could, the
night sky would be a strange and unfamiliar place.
X-rays are about 1,000 times more energetic
than visible light photons and are produced in violent and high
temperature astrophysical environments. Instead of the familiar
steady stars, the sky would seem to be filled with
exotic binary star systems
composed of white dwarfs,
neutron stars, and
black holes, along with
flare stars, X-ray bursters,
pulsars,
supernova remnants and
active galaxies.
This X-ray image of the entire sky was constructed with
Skyview,
using data from the first
High Energy Astronomy Observatory (HEAO 1),
and plotted in a coordinate system centered on the galactic center
with the north galactic pole at the top.
Sources near the galactic center are seen to dominate in this
false color map which shows regions of highest X-ray intensity in yellow.
Astronomers' ability to observe the sky at X-ray energies
will be greatly enhanced by the recently launched
X-ray Timing Explorer (XTE) satellite.
Tomorrow's picture: The X-ray Timing Explorer
APOD: December 30, 1995 - LMC X-1: A Black Hole Candidate
Explanation:
The strongest source of X-rays in the
Large Magellanic Cloud originates
from an unusually energetic
binary star system. This strong source, dubbed
LMC X-1, is thought to be a normal and compact star orbiting each other.
Gas stripped of the normal star
falls onto the compact star, heats up, and
emits X-rays. The X-rays shining from the system knock electrons off atoms
for light years around, causing some atoms to glow noticeably in X-rays
when the electrons re-combine. Motion in the binary system indicates the
compact star is probably a
black hole, since its high mass -
roughly five times that of our
Sun -
should be enough to cause even a
neutron star to implode.
Tomorrow's picture: The X-ray Sources of M31
APOD: December 26, 1995 - Accretion Disk Binary System
Explanation:
Our
Sun is unusual in that it is alone - most
stars occur in multiple or
binary systems. In a binary system, the
higher mass star will evolve faster and will eventually
become a compact object - either a
white dwarf star, a
neutron star, or
black hole. When the lower mass star later
evolves into an expansion phase, it may be so close to the compact star
that its outer atmosphere actually falls onto the compact star. Such is
the case
diagrammed
above. Here
gas from a blue giant star is
shown being stripped away into an accretion disk around its compact binary
companion. Gas in the accretion disk swirls around, heats up, and
eventually falls onto the compact star. Extreme conditions frequently
occur on the surface of the compact star as gas falls in, many times
causing detectable
X-rays,
gamma-rays, or even
cataclysmic novae explosions. Studying the extreme conditions in these
systems tells us about the inner properties of ordinary matter around us.
Tomorrow's picture: Nova Cygni 1992
APOD: December 1, 1995 - 51 Pegasi: A New Planet Discovered
Explanation:
Are we alone in the
universe? Do other
stars have
planets too? Humanity
took one step closer to answering these questions in October 1995 when it
was announced that the star
51 Pegasi harbors at least
one planet. In the above picture of
51 Peg the planet
is not visible - it can only be detected by noticing small changes in the
star's motion.
Claims of planets
orbiting other
stars are rare, with
perhaps the most credible pertaining to a
neutron star - a star much
different than the
Sun. But new ground was broken when the planetary
detection claimed around the normal Sun-like star 51 Peg was confirmed. The
planet, discovered by Michel Mayor and Didier Queloz, is thought to be like
Jupiter - except orbiting so close to the parent
star that it's year lasts only about 4 days! In the above picture the
lines centered on 51 Peg are caused by the telescope itself and are not
related to the star or planet.
Tomorrow's picture: Lightning Below
APOD: November 22, 1995 - M1: The Exploding Crab Nebula
Explanation:
The Crab Nebula resulted from a star that
exploded - a
supernova. The outer
layers of the star were thrown violently into space, while the inner core
collapsed to form a
neutron star. This
neutron star is visible to us today as a
pulsar - a rotating star
at the center of the nebula that emits
visible flashes of light. The
Crab Pulsar flashes about 30 times every
second. Although the stellar explosion that caused the Crab Nebula was
seen over 900 years ago, the nebula itself still expands and shines. How
the nebula obtains the energy needed to shine was a mystery eventually
solved by noting that this energy could be released by the slowing of the
pulsar's rotation.
APOD: October 27, 1995 - The Tarantula and the Supernova
Explanation:
In this close-up of the Large Magellanic Cloud,
the spidery looking nebula on the left is fittingly known as
as the Tarantula nebula. It is an
emission nebula
surrounding a cluster of hot, young stars
called the 30 Doradus super cluster. This
cluster may contain the most massive stars known (about 50 times
the mass of the Sun). Such massive stars put out
more than 100 times as much energy as our Sun.
The bright "star" (lower right) is actually
Supernova 1987a
and is a harbinger of things to come for the stars
within the Tarantula. Massive stars
burn their nuclear fuel at drastically enhanced rates to support
their high energy output. As a result their lives
last only a few million years compared to the Sun's few billions of years.
They end in a spectacular death explosion, a
supernova,
like the star which exploded in 1987 as seen above.
Supernovae may leave behind imploded stellar cores which
form neutron stars or
black holes.
APOD: July 25, 1995 - M1: The Crab Nebula
Explanation:
In the year 1054 a star in the constellation of Taurus exploded in a
spectacular
supernova so bright it appeared to
dominate the sky except for the Sun and Moon for many days.
It left behind one of the most
brilliant nebulae, listed first in
Charles Messier's list of nebulous sky
objects. Today we know that the center of the nebula houses the remnant
of the explosion: a spinning
neutron star called a pulsar.
The Crab pulsar
is visible in almost every part of the electromagnetic spectrum, and has
been a useful astronomical tool. It is still unclear how the the pulsar
emits the light that we see.
APOD: June 24, 1995 - Gamma Ray Crab, Geminga
Explanation:
What if you could "see" in gamma-rays? If you could, these two
spinning
neutron stars
or pulsars
would be among the brightest objects in the sky. This computer processed
image shows the Crab Nebula pulsar (below and right of center)
and the Geminga pulsar (above and left of center) in the "light" of
gamma-rays. Gamma-ray photons are more than 10,000 times more
energetic than visible light photons and are blocked from the
Earths's surface by the atmosphere. This image was produced by
the high energy gamma-ray telescope "EGRET" on board NASA's orbiting
Compton Observatory satellite.
APOD: June 16, 1995 - Neutron Star Earth
