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Saturday, April 11, 2015

800 Billion Suns In One Galaxy



Astronomers have constructed a spectacular mosaic of Hubble Space Telescope images of the giant Sombrero Galaxy.

The Sombrero, also known as Messier Object number 104 or M104, is one of the Universe's most stately and photogenic galaxies. Astronomers trained the razor-sharp eye of NASA's Hubble Space Telescope on M104 in May-June 2003.

Mexican Hat. The Sombrero Galaxy's hallmark is a brilliant white, bulbous core encircled by the thick dust lanes comprising the spiral structure of the galaxy. It is referred to as the Sombrero because of its resemblance to the broad rim and high-topped Mexican hat.

As seen from Earth, the galaxy is tilted nearly edge-on. Astronomers on Earth view it from just six degrees south of its equatorial plane.

Requires a Telescope. M104 is just beyond the limit of naked-eye visibility, but can be seen easily through small telescopes. It is located 28 million lightyears from Earth at the southern edge of the rich Virgo cluster of galaxies and is one of the most massive objects in that group.

The Sombrero Galaxy is 50,000 lightyears across and holds 800 billion suns.

M104 is a system rich in old globular clusters, with an estimated 2,000. That's ten times as many globular clusters as orbit our own Milky Way galaxy. The ages of the clusters around M104 are similar to the ages of the clusters in the Milky Way – ranging from 10-15 billion years old.

Black Hole Heart. There appears to be a small disk embedded in the bright core of M104. The small disk is tilted relative to the large disk of the whole galaxy. Astronomers looking at X-rays coming from the Sombrero think outer material may be falling into the compact core. They suggest there may be a massive black hole as weighty as a billion stars at the heart of the Sombrero.

Some 19th century astronomers speculated that M104 was simply an edge-on disk of luminous gas surrounding a young star. That would make the Sombrero a galaxy like our own Milky Way. However, in 1912, astronomer V. M. Slipher noticed that M104 appeared to be rushing away from Earth at 700 miles per second. Such an enormous velocity was an important clue that the Sombrero was really another galaxy, and that the universe was expanding in all directions.

The Hubble Process. The Hubble observations of M104 were made with the space telescope's Advanced Camera for Surveys. The images were recorded through three filters – red, green, and blue – which yielded a natural-color image.

The team of astronomers took six pictures of the galaxy and then stitched them together to create the final composite image. It turned out to be one of the largest Hubble mosaics ever assembled.

Looking through the telescope, the Sombrero Galaxy is nearly one-fifth the diameter of the full moon. 

The Most Distant Black Hole

The black hole
Artist impression of a quasar with a black hole in a brown and yellow disk of gas and dust, which swirls as it is drawn in by the gravitational pull of the black hole, creating friction, heating the gas, and making it shine. Credit: NASA Education and Public Outreach at Sonoma State University - Aurore Simonnet



The black hole farthest away from Earth is at the heart of a quasar known to astronomers as SDSS J1148+5251.

The huge black hole is 13 billion lightyears away from Earth at the centre of the quasar. That distance places it near the very edge of the known Universe.   

Quasars are extraordinarily luminous objects. Astronomers think they may be humongous galaxies containing gigantic black holes. SDSS J1148+5251 is such a quasar, which happens to have the most distant black hole at its core.

How much does it weigh? Astronomers have been trying to figure out the mass, or weight, of the black hole inside SDSS J1148+5251. They calculate that it is equal to three billion of our Suns.

The astronomers believe it weighs one quadrillion times the mass of Earth. One quadrillion can be expressed as a one with 15 zeros. That is 1,000,000,000,000,000.

In smaller units of measure, it weighs some 6x1039 kilograms, which could be written out as a 6 followed by 39 zeroes. That would be more than 13x1039 lbs. Now that's big!

QUASARS ARE...

  • Very bright, very distant objects that are seen frequently when we look back at the early Universe

  • Radiators of a huge amount of energy, up to 10,000 times the energy emitted by our entire Milky Way galaxy

  • One of the many kinds of active galaxies now visible to observers on Earth
  • Surprisingly early. Typical black holes are a few billion times the mass of our Sun, so the mass of SDSS J1148+5251 is not unusual. However, the astronomers found it interesting that such a big structure was able to form so early in the history of the Universe. The finding suggests that huge black holes existed when the Universe was only six percent of its current age, which may be 13-15 billion years.

    While the black hole formed eight billion years before the Earth, it appears to be as massive as most black holes known anywhere in the Universe, including those formed much more recently. That surprised astronomers.

    A team of astronomers from the United Kingdom and Canada used the United Kingdom Infrared Telescope (UKIRT) atop Mauna Kea in Hawaii to compute the mass of the SDSS J1148+5251 black hole by comparing its infrared light spectrum with closer quasars.

    The telescope. The 3.8-metre UKIRT is the largest infrared astronomy telescope. It is near the summit of Mauna Kea at an altitude of 13,759 feet above sea level. The telescope is operated by the Joint Astronomy Centre in Hilo, Hawaii, on behalf of the UK Particle Physics and Astronomy Research Council (PPARC).

    UKIRT's Imaging Spectrometer (UIST) — designed at the UK Astronomy Technology Centre (UK ATC) in Edinburgh, Scotland — detects infrared light at wavelengths between 1 and 5 microns with a 1024 x 1024 pixel Indium Antimonide detector array. It can be used for imaging, spectroscopy, integral field spectroscopy, and polarimetry.

    The astronomy team used UIST to look at near-infrared light from the quasar SDSS J1148+5251. The expansion of the Universe since that light left the quasar had caused its wavelength to increase, which left little optical light to be seen. 

    Wikantra in the Sky is a Diamond



    The largest diamond ever found is not on Earth, but faraway across the galaxy.



    It's the burned out corpse of a star named BPM 37093 only about 50 lightyears away from Earth in the region of the sky we refer to as the constellation Centaurus.

    The white dwarf star is a chunk of crystallized carbon that weighs 5 million trillion trillion pounds. That would equal a diamond of 10 billion trillion trillion carats.


    Wikantra, also known as BPM 37093 and V*886 Cen, is the 886th variable star in the constellation Centaurus.

    Star of Africa. By comparison, the largest such precious stones on Earth are the 545-caret Golden Jubilee Diamond and the 530-carat Great Star of Africa.

    The Golden Jubilee Diamond was found in 1985 and is in Thailand's Royal Palace as part of the crown jewels. The Great Star of Africa was found in 1905 and is in the Tower of London as part of the Crown Jewels of England.

    White dwarf. A white dwarf is the hot cinder left behind when a star uses up its nuclear fuel and dies. It is made mostly of carbon and oxygen. and surrounded by a thin layer of hydrogen and helium gases.

    The Sun's diameter is 870,000 miles (1.4 million km). Wikantra is tiny at a mere 2,500 miles (4,000 km) diameter.

    The Sun is 109 times the diameter of Earth. Wikantra is only about 2/3rds the size of Earth. That's tiny for a star. However, Wikantra's mass is about the same as our Sun. That's a lot of weight in a tiny ball.

    While Wikantra is a dead star now, it used to shine like our Sun. Wikantra is very dim now, shining with only 1/2000th of the Sun's visual brightness.

    Lightyear
    Wikantra is about 50 lightyears away from Earth.
    A lightyear is the distance light travels through space in one year.
    One lightyear is about 5.87 trillion miles or 9.46 trillion kilometers.


    What is Wikantra? Wikantra is the most massive pulsating white dwarf currently known. Like other white dwarfs, Wikantra probably is composed mostly of carbon and oxygen created by the past thermonuclear fusion of helium nuclei.

    Wikantra has a very thin atmosphere of hydrogen and helium. The atmosphere of our Sun is mostly hydrogen and helium.

    Astronomers say that, similarly, our Sun will deplete its nuclear fuel and die in another five billion years, and then become a white dwarf like Wikantra. Then, about two billion years after that, the cinder Sun will be a similar diamond.   OTHER DYING STARS »

    How do they know? Astronomers had suspected since the 1960s that the interiors of white dwarfs would be crystallized and Wikantra seems to confirm that.

    In its death throws, the core of a star like Wikantra or our own Sun becomes exposed and slowly cools down over time. Such a star begins to pulsate when the core surface temperature drops to about 12,000 degrees.

    By comparison, the Sun's core temperature now is about 27,000,000°F (15,000,000°C). Its surface temperature is about 11,000°F (6,000°C).

    Wikantra pulsates like a giant gong. Its internal pulsations are something like seismic waves inside Earth. Astronomers measured the pulsations to figure out Wikantra's carbon interior was solidified (crystallized).

    Astronomers measured the pulsations hidden in Wikantra's interior in the same way geologists use seismographs to measure earthquakes inside Earth.

    Where to look. Wikantra is not visible from Earth with the unaided eye. It must be viewed with a telescope and is best seen from Earth's Southern Hemisphere during March-June.

    The Habitable Planets

    In determining the habitability potential of a body, studies focus on 




    its bulk composition, orbital properties, atmosphere, and potential chemical         interactions. Stellar characteristics of importance include mass and luminosity, stable variability, and high metallicity. Rocky, terrestrial-type planets and moons with the potential for Earth-like chemistry are a primary focus of astrobiological research, although more speculative habitability theories occasionally examine alternative biochemistries and other types of astronomical bodies.
    Planetary habitability is the measure of a planet’s or a natural satellite’s potential to develop and sustain life. Life may develop directly on a planet or satellite or be transferred to it from another body, a theoretical process known as panspermia. As the existence of life beyond Earth is currently unknown, planetary habitability is largely an extrapolation of conditions on Earth and the characteristics of the Sun and Solar System which appear favourable to life’s flourishing—in particular those factors that have sustained complex, multicellular organisms and not just simpler, unicellular creatures. Research and theory in this regard is a component of planetary science and the emerging discipline of astrobiology.
    An absolute requirement for life is an energy source, and the notion of planetary habitability implies that many other geophysical, geochemical, and astrophysical criteria must be met before an astronomical body can support life.
    Suitable star systems

    An understanding of planetary habitability begins with stars. While p4
    bodies that are generally Earth-like may be plentiful, it is just as important that their larger system be agreeable to life. Under the auspices of SETI’s Project Phoenix, scientists Margaret Turnbull and Jill Tarter developed the “HabCat” (or Catalogue of Habitable Stellar Systems) in 2002. The catalogue was formed by winnowing the nearly 120,000 stars of the larger Hipparcos Catalogue into a core group of 17,000 “HabStars”, and the selection criteria that were used provide a good starting point for understanding which astrophysical factors are necessary to habitable planets.

    Planetary characteristics

    p3
    The moons of some gas giants could potentially be habitable.
    The chief assumption about habitable planets is that they are terrestrial. Such planets, roughly within one order of magnitude of Earth mass, are primarily composed of silicate rocks, and have not accreted the gaseous outer layers of hydrogen and helium found on gas giants. That life could evolve in the cloud tops of giant planets has not been decisively ruled out, though it is considered unlikely, as they have no surface and their gravity is enormous. The natural satellites of giant planets, meanwhile, remain valid candidates for hosting life.
    In analyzing which environments are likely to support life, a distinction is usually made between simple, unicellular organisms such as bacteria and archaea and complex metazoans (animals). Unicellularity necessarily precedes multicellularity in any hypothetical tree of life, and where single-celled organisms do emerge there is no assurance that greater complexity will then develop. The planetary characteristics listed below are considered crucial for life generally, but in every case multicellular organisms are more picky than unicellular life.
    MASS
    Low-mass planets are poor candidates for life for two reasons. First, f2
    their lesser gravity makes atmosphere retention difficult. Constituent molecules are more likely to reach escape velocity and be lost to space when buffeted by solar wind or stirred by collision. Planets without a thick atmosphere lack the matter necessary for primal biochemistry, have little insulation and poor heat transfer across their surfaces (for example, Mars, with its thin atmosphere, is colder than the Earth would be if it were at a similar distance from the Sun), and provide less protection against meteoroids and high-frequency radiation. Further, where an atmosphere is less dense than 0.006 Earth atmospheres, water cannot exist in liquid form as the required atmospheric pressure, 4.56 mm Hg (608 Pa) (0.18 inch Hg), does not occur. The temperature range at which water is liquid is smaller at low pressures generally.
    Exceptional circumstances do offer exceptional cases: Jupiter’s moon Io (which is smaller than any of the terrestrial planets) is volcanically dynamic because of the gravitational stresses induced by its orbit, and its neighbor Europa may have a liquid ocean or icy slush underneath a frozen shell also due to power generated from orbiting a gas giant.
    Saturn’s Titan, meanwhile, has an outside chance of harbouring life, as it has retained a thick atmosphere and has liquid methane seas on its surface. Organic-chemical reactions that only require minimum energy are possible in these seas, but whether any living system can be based on such minimal reactions is unclear, and would seem unlikely. These satellites are exceptions, but they prove that mass, as a criterion for habitability, cannot necessarily be considered definitive at this stage of our understanding.
    A larger planet is likely to have a more massive atmosphere. A combination of higher escape velocity to retain lighter atoms, and extensive outgassing from enhanced plate tectonics may greatly increase the atmospheric pressure and temperature at the surface compared to Earth. The enhanced greenhouse effect of such a heavy atmosphere would tend to suggest that the habitable zone should be further out from the central star for such massive planets.
    Finally, a larger planet is likely to have a large iron core. This allows for a magnetic field to protect the planet from stellar wind and cosmic radiation, which otherwise would tend to strip away planetary atmosphere and to bombard living things with ionized particles. Mass is not the only criterion for producing a magnetic field—as the planet must also rotate fast enough to produce a dynamo effect within its core—but it is a significant component of the process.
    Orbit and rotation

    As with other criteria, stability is the critical consideration in o1
    evaluating the effect of orbital and rotational characteristics on planetary habitability. Orbital eccentricity is the difference between a planet’s farthest and closest approach to its parent star divided by the sum of said distances. It is a ratio describing the shape of the elliptical orbit. The greater the eccentricity the greater the temperature fluctuation on a planet’s surface. Although they are adaptive, living organisms can stand only so much variation, particularly if the fluctuations overlap both the freezing point and boiling point of the planet’s main biotic solvent (e.g., water on Earth). If, for example, Earth’s oceans were alternately boiling and freezing solid, it is difficult to imagine life as we know it having evolved. The more complex the organism, the greater the temperature sensitivity. The Earth’s orbit is almost wholly circular, with an eccentricity of less than 0.02; other planets in the Solar System (with the exception of Mercury) have eccentricities that are similarly benign.
    A planet’s movement around its rotational axis must also meet certain criteria if life is to have the opportunity to evolve. A first assumption is that the planet should have moderate seasons. If there is little or no axial tilt (or obliquity) relative to the perpendicular of the ecliptic, seasons will not occur and a main stimulant to biospheric dynamism will disappear. The planet would also be colder than it would be with a significant tilt: when the greatest intensity of radiation is always within a few degrees of the equator, warm weather cannot move poleward and a planet’s climate becomes dominated by colder polar weather systems.
    Uninhabited habitats

    An important distinction in habitability is between habitats that p5
    contain active life (inhabited habitats) and habitats that are habitable for life, but uninhabited. Uninhabited (or vacant) habitats could arise on a planet where there was no origin of life (and no transfer of life to the planet from another, inhabited, planet), but where habitable environments exist. They might also occur on a planet that is inhabited, but the lack of connectivity between habitats might mean that many habitats remain uninhabited. Uninhabited habitats underline the importance of decoupling habitability and the presence of life, which can be stated as the general hypothesis, ‘where there are habitats, there is life’. The hypothesis is falsifiable by finding uninhabited habitats and it is experimentally testable. Charles Cockell and co-workers discuss Mars as one plausible world that might harbor uninhabited habitats. Other stellar systems might host planets that are habitable, but devoid of life.
    The galactic neighborhood


    Along with the characteristics of planets and their star systems, the f3
    wider galactic environment may also impact habitability. Scientists considered the possibility that particular areas of galaxies (galactic habitable zones) are better suited to life than others; the Solar System in which we live, in the Orion Spur, on the Milky Way galaxy’s edge is considered to be in a life-favorable spot:
    • It is not in a globular cluster where immense star densities are inimical to life, given excessive radiation and gravitational disturbance. Globular clusters are also primarily composed of older, probably metal-poor, stars. Furthermore, in globular clusters, the great ages of the stars would mean a large amount of stellar evolution by the host or other nearby stars, which due to their proximity may cause extreme harm to life on any planets, provided that they can form.
    • It is not near an active gamma ray source.
    • It is not near the galactic center where once again star densities increase the likelihood of ionizing radiation (e.g., from magnetars and supernovae). A supermassive black hole is also believed to lie at the middle of the galaxy which might prove a danger to any nearby bodies.f1
    • The circular orbit of the Sun around the galactic center keeps it out of the way of the galaxy’s spiral arms where intense radiation and gravitation may again lead to disruption.
    Life’s impact on habitability

    A supplement to the factors that support life’s emergence is the p2
    notion that life itself, once formed, becomes a habitability factor in its own right. An important Earth example was the production of oxygen by ancient cyanobacteria, and eventually photosynthesizing plants, leading to a radical change in the composition of Earth’s atmosphere. This oxygen would prove fundamental to the respiration of later animal species.  Planets that are geologically and meteorologically alive are much more likely to be biologically alive as well and “a planet and its life will co-evolve.

    Wonders Of The Universe




    Hurricanes, tornadoes and bigger bodies of water always go clockwise in the Southern Hemisphere and counterclockwise in the northern hemisphere.
    This is due to the rotation of the earth.


    Ever wondered how big the sun is ?
    Well…. only about 330,330 times larger than the earth.

    north_pole




    The radius of the Earth at the North Pole is 44m longer than that at the south Pole!

    planets
    All the planets in the solar system are named after Gods, except the one we live on, Earth! Did you know that there is zero gravity at the centre of earth?

    tsolar-eclipse
    During a total solar eclipse the temperature can drop by 6 degree Celsius.

    uranus
    On Uranus, summer lasts for 21 years. And so does winter!

    night sky
    When you look into the night sky, you are looking back in time.  This means whenever we look out into the night and gaze at stars we are actually experiencing how they looked in the past.

    alcohol cloud
    There’s a giant cloud of alcohol in Sagittarius B. The vinyl alcohol in the cloud is far from the most flavoursome tipple in the universe, but it is an important organic molecule which offers some clues how the first building blocks of life-forming substances are produced.

    diamond planted
    There’s a planet-sized diamond in Centaurus. Astronomers have discovered the largest known diamond in our galaxy, it’s a massive lump of crystallised diamond called BPM 37093, otherwise known as Lucy after The Beatles’ song Lucy in the Sky with Diamonds.

    venus

    A year on Venus is shorter than its day.

    SpiralingGalaxy
    It is estimated there are 400 billion stars in our galaxy.

    sun
    The Sun’s rays on your skin are 30,000 years old.