13.7 Billion Years(Gamma Ray Burst)

A gamma-ray burst detected by NASA's Swift satellite in April 2009 has been newly unveiled as a candidate for the most distant object in the universe. In this video, former Penn State University graduate student Antonino Cucchiara discusses this research at a press conference at the 218th meeting of the American Astronomical Society in Boston, Massachusetts, on 25 May 2011.

 25 May 2011 — A gamma-ray burst detected by NASA's Swift satellite in April 2009 has been newly unveiled as a candidate for the most distant object in the universe. At an estimated distance of 13.14 billion light years, the burst lies far beyond any known quasar and could be more distant than any previously known galaxy or gamma-ray burst. Multiple lines of evidence in favor of a record-breaking distance for this burst, known as GRB 090429B for the 29 April 2009 date when it was discovered, are presented in a paper by an international team of astronomers led by former Penn State University graduate student Antonino Cucchiara, now at the University of California, Berkeley. The paper has been accepted for publication in the Astrophysical Journal. (A PDF of the paper is available here.) See: Cosmic Explosion is New Candidate for Most Distant Object in the Universe

Lost in Translation

Photo Credit: NASA

Supernova Remnant Turns 400

Four hundred years ago, sky watchers, including the famous astronomer Johannes Kepler, were startled by the sudden appearance of a "new star" in the western sky, rivaling the brilliance of the nearby planets. Now, astronomers using NASA's three Great Observatories are unraveling the mysteries of the expanding remains of Kepler's supernova, the last such object seen to explode in our Milky Way galaxy.

This combined image -- from NASA's Spitzer Space Telescope, Hubble Space Telescope, and e Chandra X-ray Observatory -- unveils a bubble-shaped shroud of gas and dust that is 14 light-years wide and is expanding at 4 million miles per hour (2,000 kilometers per second). Observations from each telescope highlight distinct features of the supernova remnant, a fast-moving shell of iron-rich material from the exploded star, surrounded by an expanding shock wave that is sweeping up interstellar gas and dust.

See:Supernova Remnant Turns 400

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Given the idea that there is an original version to what is constituted as reality and attempts to describe it are really, "Births by approximation."

Now you have to understand the previous blog posting by this name to understand that I presented supernovas and remnants as a illustration of what happens when we see the universe by itself, is laid out before us, while within that time frame (universe's birth to present), events have happened that are defined as Supernovas.

Several types of supernovae exist that may be triggered in one of two ways, involving either turning off or suddenly turning on the production of energy through nuclear fusion. After the core of an aging massive star ceases to generate energy from nuclear fusion, it may undergo sudden gravitational collapse into a neutron star or black hole, releasing gravitational potential energy that heats and expels the star's outer layers.

See:Supernova

Now in terms of what we now know in what has been demonstrated by being lead by scientific process, a realization that such events as "the Spherical cow embeds parts of the universe in expression." We now know that such a view in terms of 13.7 billion years in the universe's age, has elements within it that are aged as well which should not exceed the age of the universe? How does gravity occur in the totality of the whole universe, for it not to be the same, as the Supernova unfolds.

Type II

Within a massive, evolved star (a) the onion-layered shells of elements undergo fusion, forming an iron core (b) that reaches Chandrasekhar-mass and starts to collapse. The inner part of the core is compressed into neutrons (c), causing infalling material to bounce (d) and form an outward-propagating shock front (red). The shock starts to stall (e), but it is re-invigorated by a process that may include neutrino interaction. The surrounding material is blasted away (f), leaving only a degenerate remnant.

Stars with at least nine solar masses of material evolve in a complex fashion.[5] In the core of the star, hydrogen is fused into helium and the thermal energy released creates an outward pressure, which maintains the core in hydrostatic equilibrium and prevents collapse.

When the core's supply of hydrogen is exhausted, this outward pressure is no longer created. The core begins to collapse, causing a rise in temperature and pressure which becomes great enough to ignite the helium and start a helium-to-carbon fusion cycle, creating sufficient outward pressure to halt the collapse. The core expands and cools slightly, with a hydrogen-fusion outer layer, and a hotter, higher pressure, helium-fusion center. (Other elements such as magnesium, sulfur and calcium are also created and in some cases burned in these further reactions.)

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The event itself and the resulting explosion has to have a basis in terms of geometrics. What shall we call these Supernovas when their previous existence may have been a blackhole? What do we call stars that collapse that make blackholes.

Source: Image Credit: Nicolle Rager Fuller/NSF

Stars shine by burning hydrogen. The process is called nuclear fusion. Hydrogen burning produces helium "ash." As the star runs out of hydrogen (and nears the end of its life), it begins burning helium. The ashes of helium burning, such as carbon and oxygen, also get burned. The end result of this fusion is iron. Iron cannot be used for nuclear fuel. Without fuel, the star no longer has the energy to support its weight. The core collapses. If the star is massive enough, the core will collapse into a black hole. The black hole quickly forms jets; and shock waves reverberating through the star ultimately blow apart the outer shells. Gamma-ray bursts are the beacons of star death and black hole birth.

Bold emphasis to encourage a conclusive realization about the classification of those events within the universe given to Gamma recordings in our measures.

Hybrids in the Universe?-12.20.06X-ray image of the gamma-ray burst GRB 060614 taken by the XRT instrument on Swift. The burst glowed in X-ray light for more than a week following the gamma-ray burst. This so-called "afterglow" gave an accurate position of the burst on the sky and enabled the deep optical observations made by ground-based observatories and the Hubble Space Telescope. Credit: NASA/Swift Team

A year ago scientists thought they had figured out the nature of gamma-ray bursts. They signal the birth of black holes and traditionally, fall into one of two categories: long or short. A newly discovered hybrid burst has properties of both known classes of gamma-ray bursts yet possesses features that remain unexplained.

The long bursts are those that last more than two seconds. It is believed that they are ejected by massive stars at the furthest edge of the universe as they collapse to form black holes.

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See:

Birth By Approximization

Spherical Cows and their X-ray Sources

The Radius of the Little Circle

Where a dictionary proceeds in a circular manner, defining a word by reference to another, the basic concepts of mathematics are infinitely closer to an indecomposable element", a kind of elementary particle" of thought with a minimal amount of ambiguity in their definition. Alain Connes

With such a statement, the "purity of thought," is speaking to a much more schematic understanding as we discuss the sociological thinking of mathematicians and the worlds they fantasize about? While deeper in reality the thought process(meditative) was engaged at a very subtle level, associated with the energy all pervasive.




Lee Smolin :

Another wonderful spin-off is that it turns out that the charge of the electron is related to the radius of the little circle. This should not be surprizing: If the electric field is just a manifestation of geometry, the electric charge should be, too.

THE TROUBLE WITH PHYSICS-Published by Houghton-Mifflin, Sep. 2006/Penguin (UK), Feb. 2007, Page 46

In "Star Shine," we start from a very large circle, but there is much to see from this circle, when we consider it's radius. We think "continuity" is somehow not involved, if we freeze this circle, and call it a discrete measure of the universe's age? Yet we know to well that the motivation of this universe from a "distant point" measure today entropically lives in the multitude of complexities?

Plato:

Model apprehension is part of the convergence that Lee Smolin and Brian Greene talk about, and without it, how could we look at nature and never consider that Einstein's world is a much more dynamical one then we had first learned from the lessons GR supplied, about gravity in our world?

On page 47 of the Trouble with Physics Lee goes on to say further down the page:

Lee Smolin:

Unfortunately, Einstein and the other enthusiasts were wrong. As with Nordstrom's theory, the idea of unification by adding a hidden dimension failed. It is important to understand why.

If all one had was the "cosmological view" one could be very happy about the way in which his observations have been deduced from the measures of our mechanical means, that we say that GR is very well suited.

Yet it has been through th efforts of reductionism that we have said, "hey there is indeed more depth to the views we have, that the mechanical measures are being tuned accordingly?"



Juan Maldacena:

The strings move in a five-dimensional curved space-time with a boundary. The boundary corresponds to the usual four dimensions, and the fifth dimension describes the motion away from this boundary into the interior of the curved space-time. In this five-dimensional space-time, there is a strong gravitational field pulling objects away from the boundary, and as a result time flows more slowly far away from the boundary than close to it. This also implies that an object that has a fixed proper size in the interior can appear to have a different size when viewed from the boundary (Fig. 1). Strings existing in the five-dimensional space-time can even look point-like when they are close to the boundary. Polchinski and Strassler1 show that when an energetic four-dimensional particle (such as an electron) is scattered from these strings (describing protons), the main contribution comes from a string that is close to the boundary and it is therefore seen as a point-like object. So a string-like interpretation of a proton is not at odds with the observation that there are point-like objects inside it.

While energy is being exemplified according to the nature of the particles we see in calorimetric design, what said that the energy here is not topologically smooth in it's orientations? Even we we move our views to the quantum regime.

Maybe having solved the "Continuum Hypothesis," we learned much about Einstein's inclinations?

The surface of a marble table is spread out in front of me. I can get from any one point on this table to any other point by passing continuously from one point to a "neighboring" one, and repeating this process a (large) number of times, or, in other words, by going from point to point without executing "jumps." I am sure the reader will appreciate with sufficient clearness what I mean here by "neighbouring" and by "jumps" (if he is not too pedantic). We express this property of the surface by describing the latter as a continuum.Albert Einstein p. 83 of his Relativity: The Special and the General Theory

Even Einstein had to add the "extra dimension" so we understood what non-euclidean views meant in a geometrical sense. I again refer here to Klein's Ordering of Geometries so one understands the schematics and evolution of that geometry.

The History of "Star Shine to Now"

In "The String Saga of Star Shine" I gave a distant measure of how we might seen any event from that time to now.

But before I begin I wanted to link Lubos's mention of article from David G to him, to point out the method and determinacy with which I gave the "String Saga Star Shine" it's inital point of measure "from" to our currrent infomration present in this universe now.

The Universe on a String By BRIAN GREENE

This striking pattern of convergence, linking concepts once thought unrelated, inspired Einstein to dream of the next and possibly final move: merging gravity and electromagnetism into a single, overarching theory of nature's forces.

In hindsight, there was almost no way he could have succeeded. He was barely aware that there were two other forces he was neglecting — the strong and weak forces acting within atomic nuclei. Furthermore, he willfully ignored quantum mechanics, the new theory of the microworld that was receiving voluminous experimental support, but whose probabilistic framework struck him as deeply misguided. Einstein stayed the course, but by his final years he had drifted to the fringe of a subject he had once dominated.

Low and behold we measure the "high energy in our sun" but least we remember the lower ends of the spectrum how shall we ascertain the images of the Sun if we did not include the lower measures in what we discern of the "sterile neutrino?"

Lest we forget about the "idea of convergence here" we might again refer to Lee Smolin's Book, The Trouble with Physics." Might Brian Greene be referring to the "latest debate?"

The relationship here being expounded upon, holds this principal that Lee Smolin talks about in what a new theory can do. Pastes it in our heads as I have shown the historical value of what began with "Pauli's Ghost particle" as the "now" of today, askes us to consider the value of the "sterile Neutrino" as a value in the discernation of that weak gravitational field?

Arrow of Time?

Let's look at Kip Thornes definition of the "timeline(star shine's) history" shall we?


Dr. Kip Thorne, Caltech 01-Relativity-The First 20th Century Revolution

So here we are, fully appreciating and understanding the "measure of distance" as we look at the "new image" of the sun?



Yes, we are to include now not only the valuation of high energy dissertations here but what value we have of the immediate presence of the neutrinos from the sun. We now have a much more comprehensive view of what the sun saids to us over "this distance of time?" How we may look at the image as we look at the way the sun looks in that picture shown by JoAnne of Cosmic Variance above.

A lot of people do not understand that if you look to the cosmo, you do not just look at what is evident from observation, but that your observation is increased, as you enhance your perceptions about the "real depth" of that universe.

So the lesson here, is that the mathematics "first born to mind" is a very suttle thing, as we peer deeper into the very beginning of this universe. While Einstein did not see in the way we do now, the relevance of that distance in time, is still held to every mind to consider in GR, that the depth of perception s still needed on a quantum level.

While the point made here is "gravitational in nature," the issuance is from the "other dimensions" to now. Quantum dynamcically this has been revealled while the discrete notion has been applied to our thinking as the "oscillation factor" has been understood in the muon to electron neutrino?

So should I point to the nature spread out before us, as you look at the effect of the neutrinos on the Kamiokande screen? Other ways, that I have shown, as we look at the aurora borealis, or the rainbow in our skies?



The effect of "our reason" for such processes in physics are extremely versatile on a sociological level, that one might question indeed where such "pure thoughts in mathematics" could arise to the "symbolistic nature predating( monte carlo methods of computerization)" of that physics?

Model apprehension is part of the convergence that Lee Smolin and Brian Greene talk about, and without it, how could we look at nature and never consider that Einstein's world is a much more dyamical one then we had first learnt from the lessons GR supplied about gravity in our world?

Yes GR is still a theory, but with experimental consequences, much as the model string theory offers you, as we look at the oscillatory nature of what asymmetry provides for us, from that pure "high energy state?" Gravity, very strong, to what is weak in the measures of the neutrino characters?

I gave some pictures to consider while I continue. Some may move ahead of me if they like:) Maybe Stefan and Bee of Backreaction?

The String Saga of Star Shine?

So lets say that the universe has always existed? Imagine approximately 13 billion years as a length of time measured?


The Distant Gamma-Ray Burst GRB 050904. Image credit: ESO

Mon, 12 Sep 2005 - An Italian team of astronomers have found a gamma ray burst that blew up 12.7 billion light-years away - the most distant ever seen. Astronomers have calculated that it exploded with 300 times more energy than our Sun will put out in its entire 10+ billion year lifespan. The blast was discovered by NASA's Swift satellite, which is dedicated to discovering these powerful explosions.

We just want to know what motivates any "inflationary idea" to have it consider in all the entropic states that we recognize today, may have arisen from a simpler time. We may be talking about the beginning of the universe here, but also the the birth of blackholes. So, if we can see that far back, what remnants of the explosion sits with us today?

Well I looked at our sun as an example.

How were Sun's formed?


Source: Image Credit: Nicolle Rager Fuller/NSFStars shine by burning hydrogen. The process is called nuclear fusion. Hydrogen burning produces helium "ash." As the star runs out of hydrogen (and nears the end of its life), it begins burning helium. The ashes of helium burning, such as carbon and oxygen, also get burned. The end result of this fusion is iron. Iron cannot be used for nuclear fuel. Without fuel, the star no longer has the energy to support its weight. The core collapses. If the star is massive enough, the core will collapse into a black hole. The black hole quickly forms jets; and shock waves reverberating through the star ultimately blow apart the outer shells. Gamma-ray bursts are the beacons of star death and black hole birth.