The Cosmic Microwave Background (CMB)

What is the CMB?

The radiation left from the early stages of the universe is called cosmic microwave background radiation. When the universe was at this early stage, it was soo hot that all atoms in the universe were ions. An ion is an atom that has positive and negative electrical charges. At this point in time the conditions of the universe may have been similar to that of a star; hot, dense and opaque allowing different atoms to pass through it.

Over time as the universe expanded, this gas cooled down. This ofcourse took several hundred thousand years. Radiation that was left behind from the big bang has been able to travel throughout the universe. As this early universe expanded, the radiation red-shifted to longer wavelengths and was therefore in a form to represent different temperatures. The spectrum of the CMB maintains the shape of a Blackbody spectrum. According to writer of http://hyperphysics.phy-astr.gsu.edu/hbase/mod6.html 

"Blackbody radiation refers to an object or system which absorbs all radiation incident upon it and re-radiates energy which is characteristic of this radiating system only, not dependent upon the type of radiation which is incident upon it. The radiated energy can be considered to be produced by standing wave or resonant modes of the cavity which is radiating."

The presence of CMB radiation with a Blackbody is a strong indication of the Big Bang theory. 

This above picture is a view of the sky after the foreground glow of the solar system dust has been extracted. This image is dominated by emission from interstellar dust in the Milky Way Galaxy. The two bright objects in the center of the lower right quadrant are nearby galaxies, the Large and Small Magellanic Clouds.

Source: Hubblesite.org

The COBE satellite 
The Cosmic Microwave Background Explorer was launched in 1989. Developed by NASA's Goddard Space Flight Center, its mission was to measure the infrared and microwave radiation from the early universe. COBE made some very precise measurements at different wavelengths. These measurements were from a few micrometer to 1 centimeter. 

 

The data on the graph above shows small dots, these small dots are the COBE measurement of the CMB at different frequencies. The X-Axis of the graph represents the frequency cycle per centimeter and Y-Axis represents the brightness of the frequency component. The uncertainty in each measurement is less than size of each dot. The left hand side of the curve that just begins to rise represents data points of a blackbody spectrum.  The above observation matches theoretical predictions of the Big Bang almost with perfection. So much so that there can be little doubt that one is seeing the radiation left behind from a hot, dense beginning from an earlier universe. Researches John Mather and George Smoot were awarded Nobel Prize for this work in 2006.

The above mapping shows the Northern and Southern galactic hemispheres,

Images of different regions of the hemispheres, the second image is of our galaxy. The galactic center is the middle bulged.

 

This graph displays the different magnitudes of the wavelengths from radio waves to X-rays and Gamma rays.

Image of CMB as produced by data collected byt he WMAP.

In 2001 the Wilkinson Microwave Anisotropy Probe (WMAP) made more accurate measurements of the CMB variations.  The above is much more detailed map of the structure of the universe.
In 2013, the European Space Agency (ESA) launched the Planck mission, which went one step further and obtained images in a much higher detail.

The image shows observations of the Cosmic microwave background (CMB) as observed by Planck. The image shows tiny temperature fluctuations that correspond to regions of slightly different densities, representing the seeds of all future structure: the stars, galaxies and nebula's that we have today.

"Most galaxies are usually in a group close by. A neighboring is never too far away. But this galaxy, known as NGC 6503, has found itself in a very lonely position, at the edge of a strange empty patch of space called the Local Void.
The Local Void is a huge stretch of space that is at least 150 million light-years across. It seems completely empty of stars or galaxies"

Source: Hubblesite.org

Star V838 Monocerotis

Source: Hubblesite.org

30 Doradus Nebula, is a giant star-forming region

Source: Hubblesite.org

 
Early scientists predicted that, the early universe must have begun as a singularity and then expanded as radiation and elementary particles. However what do we mean when we say singularity?

According to the FreeDictionary a singularity is "a hypothetical point in space-time at which matter is infinitely compressed to infinitesimal volume"
This means matter which infinitely falls toward a negative value making it smaller than any real value.

The Big Bang theory is fundamental to our understanding of the universe. So far it has resisted any efforts made by researchers to prove it false, as the CMB provides evidence of the scenario of our early universe.

The above image shows the Nucleus of Galaxy Centaurus A.

Source: Hubblesite.org
Some of the crucial discoveries made by the COBE were:

• COBE revolutionized our understanding of the early cosmological structure.
• It measured and mapped the oldest light in the universe -- the cosmic microwave background. This was similar to seeing a baby picture of the universe.
• The cmb spectrum was measured with a precision of 0.005%.
• The results confirmed the Big Bang theory of the origin of the universe.
• The very precise measurements helped eliminate a great many theories about the Big Bang.
• The mission urged scientists into a new age of precision measurements, providing ground for new research into microwave background by NASA's WMAP mission and ESA's Planck mission, that latter provided much more detailed measurements.

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Goodbye for now and see you next time.

Pluto on the Horizon

NASA completed a historic mission of New Horizons to the Pluto system this month, which consisted of exploring Pluto and its moon's; Charon, Styx, Nix, Kerberos and Hydra. To get this mission approved it took around 14 years spanning from 1989 to 2003. 

Clyde Tombaugh discovered Pluto in 1930 at Lowell Observatory in Flagstaff, Arizona. In Tombaugh's time one could only determine Pluto's orbit and color. Pluto's orbit is 284 Earth years and is very elliptical. At perihelion, Pluto is closer to the Sun than Neptune. Pluto's orbit is locked in a 3:2 ratio with that of Neptune's.

In 1978, Christy & Harrington discovered Charon, Pluto's largest moon.  Pluto and Charon have a rocky core which is encapsulated with water ice mantle. They both are also tidally locked, each having a hemisphere that faces the other. 

Not much detail is known about Pluto, but the New Horizon's mission should shed more light in the coming months. Currently around 90% of the data is still aboard the space craft and yet to be transmitted back to NASA communications back on Earth.

 

http://ircamera.as.arizona.edu/NatSci102/NatSci102/lectures/pluto.htm 

Pluto's surface is an icy mix of frozen water, carbon dioxide, nitrogen, methane and carbon monoxide. Pluto also has a very thin atmosphere which holds gasses that freeze when Pluto is further away from the Sun, but when it is closer these gasses heat up.

First look at Pluto by the Hubble Space Telescope.

   Source: Hubblesite.org

Pluto and Charon are perhaps a product of an impact between Kuiper belt objects. Both at one time were thought to be close a double planet system.
 

Pluto has many interesting features with the dark and light patches in the south mainly consisting of large icy solids.

Pluto is at a distance of 5.9 billion kilometers and has a temperature of -229 °C.

Amazing features with alot of details can been seen from this image. The ice glaciers would perhaps flow similar to those on Earth.

Icy mountain ranges of Pluto stretch for hundreds of kilometers.

Pluto and Charon from final approach of New Horizon's.

Size of Pluto and Charon compared with Earth.

Pluto has a diameter of 2372 km according to recent measurements taken by the New Horizons spacecraft. When we compare this with Earth's 12,742 km, we get an idea of how tiny Pluto really is. Pluto maintains a surface gravity of just 0.063g, while Earth's is 1g.

A spectacular view of Pluto with the Sun's light creating  a halo.

Image of Pluto from New Horizon as it made its approach through the years.

Pluto comparison with other moons and Planets.

Simulation view of Nix

Nix is a satellite of Pluto which was discovered in 2005 by the Hubble Space Telescope. New Horizons measured Nix to be 32 Kilometers in diameter.

Simulation view of Kerberos with Pluto and Charon in view.

 Kerberos is another small moon which orbits Pluto.

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Until next time goodbye for now.