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At least once a second, a dim, elderly star somewhere in the cosmos turns into a thermonuclear bomb. Briefly outshining its home galaxy, the explosion, known as a type 1a supernova, unleashes the equivalent of 1028 megatons of TNT — enough energy to destroy an entire solar system.
Astronomers have marveled at these cosmic firecrackers for centuries. But so far nobody has explained in detail how these supernovas explode. Now, theorists are on the verge of attaining that understanding — and just in time, because astronomers are observing type 1a supernovas with a new urgency. In fact, the story these stars have to tell is a matter of cosmic life and death.
When astronomer Robert Kirshner, now at Harvard University, first began observing these cataclysmic explosions in 1972, it didn’t matter that no one understood how they happen. A lack of knowledge about the explosion process didn’t stop Kirshner and his colleagues, along with another team, from using type 1a supernovas to discover in 1998 that a mysterious entity, later dubbed dark energy, is accelerating the expansion of the universe (SN: 2/2/08, p. 74). But today, ignorance about type 1a supernovas is no longer bliss, say Kirshner and other astronomers. Researchers now are not only relying on supernovas as distance markers to deduce the presence of dark energy, but also to unveil its character.
One of the deepest mysteries in all of physics and astronomy, the nature of dark energy determines the fate of the universe. If its density across the universe increases over time, the cosmos will end in a Big Rip, with every atom torn asunder. If it somehow vanishes, cosmic expansion will continue but at a slower rate. And if its strength remains fixed in time, akin to the cosmological constant that Einstein inserted into his equations of general relativity, every galaxy will someday become its own island universe.
To determine whether dark energy varies or remains the same throughout time, astronomers need to measure its equation of state, defined as the ratio of its density to its pressure. And to measure the equation of state at different epochs in the universe, researchers urgently need more detailed information on type 1a supernovas, says Don Lamb of the University of Chicago.
Theorists are beginning to crack the riddle of supernova explosions by borrowing some of the techniques — and computer codes — applied to a surprisingly down-to-Earth system: combustion in gasoline engines. Thanks to these codes, which require the processing power of supercomputers, researchers can now view the full three-dimensional evolution of a stellar explosion instead of a muted, one-dimensional facsimile.
On the computer screen, “it’s like watching a fire consume a forest, you just see these flames working through the star, with all this structure to it,” says theoretical astrophysicist Daniel Kasen of the University of California, Santa Cruz.
Simulations developed by supernova expert Stan Woosley, also of UC Santa Cruz, along with Kasen, Fritz Röpke of the Max Planck Institute for Astrophysics in Garching, Germany, and others now suggest that supernovas that erupted a few billion years back in time may be different — intrinsically brighter — than those exploding today. The team has begun to identify several other features that may affect supernova brightness — such as how rapidly a star rotated before it exploded and its abundance of elements heavier than helium — which might confound dark energy measurements if overlooked.
“We’re starting to make meaningful comments about how useful these supernovae can be for precision cosmology,” Woosley says.
Exploding stellar probes
Astronomers rely on type 1a super-novas to probe the expansion history of the universe because these explosions are almost perfect cosmic mile markers.
Since all 1a’s appear to have the same starting point — blowing up the same amount of mass —they all should have roughly the same luminosity. After adjusting for variations by applying the Phillips relation, which holds that intrinsically brighter supernovas take more time to fade than dimmer ones, researchers can, in principle, read off the wattage of these cosmic lightbulbs. Just as the apparent brightness of a 60-watt bulb predictably diminishes with distance, so too should the observed brightness of a supernova.
When astronomers applied this prescription, they found that light from distant supernovas appeared dimmer than it ought to be based on what had been the accepted model of the universe’s evolution. That unexpected result led in 1998 to an astonishing conclusion: Rather than slowing down, the cosmos has recently sped up its rate of expansion, putting extra distance between nearby and remote supernovas — and the galaxies in which they originated.
Now, astronomers want to know the inherent brightness of type 1a supernovas to within a few percent, rather than the previous error margin of 20 percent — and how that brightness varies among different populations. Suppose, for example, that supernovas containing a lower abundance of heavy elements — typical of stars earlier in the history of the universe — areon average intrinsically brighter than supernovas exploding today. The Phillips relation says that the supernovas with fewer metals should remain bright for a longer period of time than others. Indeed, models suggest that such cosmic bulbs would last longer than younger supernovas, but not quite as long as the relation predicts, Woosley and collaborators now find. This effect cannot be ignored if researchers want to use type 1a’s to measure distances to an accuracy of 1 or 2 percent, which will be required to assess whether or not dark energy varies with time, Kasen says.
If type 1a supernovas vary in brightness according to a random statistical distribution, with some explosions brighter and some dimmer than average, simply observing many more of them will beat down the error in using them as standard lightbulbs, Kasen says. But if some type 1a’s, such as distant ones, are systematically different from others, as his team now suggests, a problem emerges.
If such properties aren’t accounted for, “our errors would be greater than we really believe” in using type 1a supernovas to measure the expansion of the universe and the nature of dark energy, says Mike Zingale of Stony Brook University in New York.
Road to kaboom
Most astronomers agree that a type 1a supernova starts with a white dwarf — an aging star that crams as much mass as the sun into a volume no bigger than Earth. Most white dwarfs are cold and inert. But if the star has a companion, it will siphon mass off the neighbor star until tipping the scales at about 1.4 solar masses. At that mass, the white dwarf becomes dense and hot enough to initiate an explosion.
No one really knows the nature of the partner stars, exactly how or where the initial nuclear flame is sparked, or how a relatively slow flame transitions into an inferno that races through the star at supersonic speeds. Because white dwarfs are so dim, astronomers have never even seen one right before it blows up as a supernova.
But based on the information they do have, theorists have developed dazzling if complex computer models to mimic and learn about these stellar bombs. Watching flames racing across the screen, it’s easy to lose sight of one of the most important properties that researchers are now trying to pin down. A single number, the amount of nickel-56 forged at the core of the exploding star by the fusing together of lighter nuclei, determines a type 1a’s luminosity.
Although the explosion itself lasts for only a few seconds, the slow radioactive decay of nickel-56, which generates photons that diffuse out of the exploded star’s core and heat the outlying shrapnel, causes supernovas to glow brightly and linger in the sky for months. It’s Kasen’s task, in the UC Santa Cruz group, to determine if models reproduce the observed amounts of nickel-56, how long photons would take to travel through the supernova debris and how bright the simulated supernova would appear to observers on Earth.
Different supercomputer models have to handle different aspects of a mind-boggling array of distance scales — from less than a millimeter to 2,000 kilometers. Also, the approximations embraced by physicists and astronomers for other computational problems do not apply to supernovas, which are highly asymmetrical, involve complex, turbulent flows, and explode under conditions of high density and extreme gravity.
“We’ve been learning a lot from the people who study combustion,” Woosley says. Internal combustion engines exhibit two types of burning that supernovas, at least in theory, also exhibit. A car engine normally operates at a slow burn, with the flame ignited by the compression of gasoline and oxygen traveling at speeds considerably slower than the speed of sound through the fluid. That sluggish burning is known as deflagration. In car engines that knock, the flame travels supersonically, a burning known as detonation.
In exploding stars, models in which a thermonuclear flame travels exclusively at subsonic speeds produce a much dimmer explosion than telescopes have recorded. Also, such models leave too much carbon and oxygen unburned. At the other extreme, simulations in which a flame travels only at supersonic speeds burn the white dwarf’s material so rapidly and thoroughly that all the lighter-weight elements are squeezed together. This squeezing forges the heaviest elements a supernova can make in abundance — nickel, cobalt and iron. But that also doesn’t match observations, which reveal intermediate-weight elements including magnesium, calcium and silicon in the supernova debris.
In the early ’90s, Woosley and Alexei Khokhlov, now at the University of Chicago, independently proposed that a hybrid model, in which a supernova begins as a deflagration and transitions to the more rapid detonation, might be the most likely scenario. The original simulation, however, was only in one dimension, limiting its usefulness. In 2003, a team led by Elaine Oran and Vadim Gamezo, both of the Naval Research Laboratory in Washington, D.C., showed that the hybrid model, when extended to three dimensions, did indeed match observations. But the underlying physics that would cause a transition from deflagration to detonation remains unclear.
“It looks promising, but no one is there yet,” Woosley says.
Determining how fast a thermonuclear flame moves and where it starts is critical, says Woosley. His team’s most recent studies show that these properties affect how much nickel-56 will be produced and how bright a supernova can become.
For instance, Röpke now finds that if the flame originates as a slightly off-center deflagration, just 20 to 80 kilometers from the core, the star doesn’t “puff up” as much in response to the slow-moving burning front. Then, when the burning switches to a detonation, the higher density of the exploding star makes it easier to fuse lighter nuclei into heavier ones to produce nickel-56.
Differences in the location of ignition, which may vary from one white dwarf to another and result in a lopsided explosion, “may be the critical factor” for accounting for the diversity of type 1a supernovas, and why they don’t all have exactly the same brightness, Kasen says. Because the central regions of the stars are so turbulent before they explode, “we don’t expect ignition to originate in the same way in every supernova.” Kasen, Röpke and Woosley report their findings online at arXiv.org and in an upcoming Nature.
Building on previous studies, the team also finds that small deficits in a white dwarf’s metal content — in this case a lack of elements heavier than oxygen and carbon — can generate slightly brighter supernovas by generating more nickel-56. In a few cases, the model created some supernovas that were as much as 10 percent more luminous than others, Kasen says. That’s important because white dwarfs with few metals tend to hail from remote reaches of the universe, seen as they appeared farther back in time, before stars had a chance to produce an abundance of heavy elements. So type 1a’s from more distant reaches of the universe might be systematically brighter than the nearby explosions. Observing more supernovas won’t address these differences; it will only eliminate the statistical ones.
“We’re at a point now where we can vary the properties of the white dwarf and get a sense of what the systematic errors [in brightness] might be,” Kasen adds.
From slow to fast
Although theorists have made progress in simulating the two-step burning process, they’re still debating how a slow-burn becomes a detonation. How this happens could have consequences for nickel-56 production, and ultimately how bright a 1a supernova can become.
In Woosley’s view, the flame acts as a barrier, keeping apart hot ash and the cold, unburned carbon and oxygen fuel. Late in the explosion, as the white dwarf expands and densities within the star become low enough, turbulent gases rip through the flame and quench it, allowing the hot ash and cold fuel to mix.
If the ash and fuel remain well mixed, they can combine into a large volume of material that ignites all at once, triggering a high-speed burning front, or detonation, says Woosley. “We don’t completely understand the physics of [the transition] yet, but we understand the density when it would happen.”
In another model, developed by Lamb and his colleagues at the University of Chicago’s FLASH center in 2004, a series of ignition points within a white dwarf meld into a hot, burning bubble that rises rapidly, breaks through the surface of the star and spreads quickly across the surface. Waves of ash sloshing around the surface in opposite directions collide at high temperatures, creating a set of outwardly and inwardly directed jets. The inward jets penetrate the star’s interior, generating temperatures and densities high enough to initiate a detonation.
In an updated version of the FLASH model, reported last year, researchers demonstrated that the simulation produces a range of nickel-56 abundances that could explain observed variations in supernova brightness, Lamb says. In an upcoming Astrophysical Journal, the researchers show that the detonations can naturally occur in their three-dimensional models. In past versions, the detonation had to be added to the model.
At the Naval Research Laboratory, Oran and Gamezo are exploring how turbulent gases in a white dwarf might generate shock waves that force the transition. They expect to unveil a new simulation in a few months.
“We’re [all] getting at the physical underpinnings of supernovas,” says Kasen. Researchers are hoping that those details will prove to be a giant step forward in unmasking dark energy.
Found in: Astronomy and Planetary Science
- Cowen, R. 2008. Embracing the dark side. Science News 173 (Feb. 2):74. [Go to]
- NASA’s multimedia presentation on dark energy: hubblesite.org/hubble_discoveries/dark_energy
- Kasen, D., F. Roepke, and S.E. Woosley. In press. The diversity of type Ia supernovae from broken symmetries. Nature. [Go to]
- Breaking it Down
- FOR KIDS: Island of hope
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- 2009 Science News of the Year
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I think there's an error in magnitude in this article. Please clarify.
Dark Matter-Energy And “Higgs”?
Energy-Mass Superposition
The Fractal Oneness Of The Universe
All Earth Life Creates and Maintains Genes
A. On Energy, Mass, Gravity, Galaxies Clusters AND Life, A Commonsensible Recapitulation
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The universe is the archetype of quantum within classical physics, which is the fractal oneness of the universe.
Astronomically there are two physics. A classical physics behaviour of and between galactic clusters, and a quantum physics behaviour WITHIN the galactic clusters.
The onset of big-bang's inflation, the cataclysmic resolution of the Original Superposition, started gravity, with formation - BY DISPERSION - of galactic clusters that behave as classical Newtonian bodies and continuously reconvert their original pre-inflation masses back to energy, thus fueling the galactic clusters expansion, and with endless quantum-within-classical intertwined evolutions WITHIN the clusters in attempt to delay-resist this reconversion.
B. Updated Life's Manifest May 2009
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All Earth life creates and maintains Genes. Genes, genomes, cellular organisms - All create and maintain genes.
For Nature, Earth's biosphere is one of the many ways of temporarily constraining an amount of ENERGY within a galaxy within a galactic cluster, for thus avoiding, as long as possible, spending this particularly constrained amount as part of the fuel that maintains the clusters expansion.
Genes are THE Earth's organisms and ALL other organisms are their temporary take-offs.
For Nature genes are genes are genes. None are more or less important than the others. Genes and their take-offs, all Earth organisms, are temporary energy packages and the more of them there are the more enhanced is the biosphere, Earth's life, Earth's temporary storage of constrained energy. This is the origin, the archetype, of selected modes of survival.
The early genes came into being by solar energy and lived a very long period solely on direct solar energy. Metabolic energy, the indirect exploitation of solar energy, evolved at a much later phase in the evolution of Earth's biosphere.
However, essentially it is indeed so. All Earth life, all organisms, create and maintain the genes. Genes, genomes, cellular organisms - all create and maintain genes.
Dov Henis
(Comments from 22nd century)
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S Gruhn ...
yes that 1028 value popped up in my mind as way too low.
1 Megaton = 4x10^15 joules
According to WIKI a Type 1A releases between:
1x10^44 and 2x10^44 joules ...
So that would mean, literally, BAZILLIONS of megatons of TNT for a Type 1A ... I think that is the correct term .... ;-)
Jim
Ekshully, that would be 10s of trillions of quadrillions of megatons. American terminology. British, 10s of thousands of trillions of megatons.
:)
nucleus of atoms expand/explod all a time and emit/radiate energywaves that have a nature of electrons and particles. Also electrons and particles expand/explod all a time and emit/radiate exploding energywaves.
Electrons just move to next elpoloding nucleus of atoms and get this exploding faster. Before that, electrons give some change of pressure for energywaves who push themselfs out from exploding nucleus of atoms and then born new electrons who go some other nucleus of atoms etc..
Galaxies*
The galaxies rotate like wheels. If there would exist a drafting force, should the galaxies have ten times larger mass than it is at present observed. This is because the farthest stars of galaxies circulate the centre of galaxy so fast. The gravity of observed mass is not able to keep them in their orbits. The stars that circulate the furthest should be thrown away from their tracks.
Although the modern physics does not understand how the gravitation is transfered, it still has found out that galaxies consist of some mystery substace that has this drawing force.
The dark substace is different from the observed substance. Yet it has the the same kind of drawing force as the observed substance has.
No, there is no gravitation!
All the stars of the galaxies have arised from the black holes of the giant centres of the galaxies. They expand three-dimentionally, opening up energywaves that have the nature of atoms. The stars expand and push themselves away from the galaxy centre in a curved orbit in a same relation as they expand.
That is to say that also the furthest stars are thrown away from the centre of the galaxy. The same way as their speed of movement around the galaxy centre lets us suppose. Only this is not observed, because everything expands three-dimentionally in same relation.
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Authors_;
*Mr. Rupak Bhattacharya- Bsc(cal) Msc(JU) 7/51 purbapalli,po-sodepur dist 24 parganas(north) Kol-110
**Professor Pranab kumar Bhattacharya MD(cal) FIC Path(ind) Professor of pathology, institute of post graduate medical education & research,244 a AJC Bose Road, Kolkata-20, India
***Mr.Ritwik Bhattacharya B.com(cal) 7/51 purbapalli, Po-sodepur Dist 24 parganas(north) , Kolkata-110,WestBengal, India
****Miss Upasana Bhattacharya- Student
**** Mrs. Dalia Mukherjee BA(hons) Cal Swamiji Nagar, Habra, 24 Parganas(north) West Bengal, India
Dr Avisnata Das MBBS(cal) Ex House physician, Medical college Kolkata, West Bengal, India
****Dr. Srabani Chakraborty MD(cal) Asst. Professor Pathology, IPGMER, Kolkata-20
Stars last too long in the universe. For an astronomers to see any evolution of a star or death of a star, in the course of his/their life time, unless he/they is/are lucky enough to see one star destroying itself in a supernova or in a nova explosion or turning towards a Red giant . My old and recently diseased father , late Mr. Bholanath Bhattacharjee of 7/51 purbapali, po-sodepur,24 parganas(north) kol-110, West Bengal, India ,used to teach our brothers and sister in our young ages, with his built up notion like this”….. Stars are long lived objects with ages, they are as old as our galaxy is, as old as our universe is and they are symbol of eternity they may be 2.5 billion years – 3 billion years old from a first generation stars explosions and are almost perfect cosmic mile markers even very close to Big Bang. Today we know that looking at a supernova of a very distant star almost at horizon of the universe, or of a Nebula, we can understand the mystery of creation of the Universe, the Big Bang it self. They are really the symbol of the eternity. Edington suspected, that the nuclear reactions in the interior of the stars are primary sources of energy for it’s luminosity and fusion of hydrogen to make Helium and that can take place in it, in time bound scale for this ranges, from millions to millions years. Our sun has lost it’s brightness by more then 1% from it’s birth, due to change in it’s internal structure for past 107 years. But the question remains how these supernovas explode? What is the mechanism behind it? No physics probably answered it. Here may be some explanations by my brothers Rupak Bhattacharya and Ritwik Bhattacharya the authors
If we consider the mode of generation of energy in the star, nuclear process provide the only source of energy adequate to keep the stars ongoing luminous. The nuclear fusion in which Hydrogen is built up into Helium, can function sufficient fast at temperature, like those at central core of star (12-25 million degrees). The Helium burning process are important 1) Carbon Nitrogen cycle at which a carbon-12 nucleus (12C) capture proton and is converted into 13C, Nitrogen-4 and nitrogen –15. At a final temperature, a proton leads to a fusion yielding original 12C nucleus to a Helium nucleus .2) The Proton- Proton process, in which protons are built direct Helium nuclei through steps, involving first in production of a deuterium and helium3 nuclei to form Helium4 nucleus and two protons. 3) Carbon burning process where 12C nucleus undergoes fusion reaction in the interior of a star producing neutron, proton, and Alfa particles with huge temperature. The first reaction probably dominates into the star, applicable to more massive stars then Sun. The second and third reaction is applicable for Sun and in less massive stars then Sun respectively. Thermonuclear reactions like those in a hydrogen bomb are powering the Sun in a contained and continuous explosions converting some four hundred millions tons (4x1014 grams) of hydrogen into helium. When we look up in the sky in night and see the stars we see them shining because of distant nuclear fusion in them .But hydrogen fusion can not continue for ever. Our Sun is ~ 4.7109 years old star. The energy produced in our ordinary star Sun in each second, is equivalent to the destruction of 41/2 millions tons of hydrogen mass in every second, a mere fleabite compared with the mass of the Sun which is two thousand billion and billion tones. In the Sun or in any other stars, there is limited so much hydrogen in it’s hot interior. Although Helium is predominating as net fusing of Hydrogen, other elements like “carbon”, “Iron”, “L element” “Manganese” “Chromium”, EU, yttrium, Magnesium, SR, Nickel, Osmium are also built up in the interior of the stars. Arnett and Truran [Arnett W.D and Truran. JW –Astrophysics.J-Vol157;P339,1969] showed that nuclear reaction net work in the sun when 12C nuclei began to under go the fusion reaction in the interior of sun many elements are produced such as
12C+12C---- 23Na+P+2.238mev----23Mg+ n+2.623mev------20Ne+ 27Al +4.616mev and the reaction goes on endlessly. A large number of computed reactions are possible as the liberated neutron and gamma particles begin reaction with all the nuclear species generated within the hydrogen fusion. In fact Arnett and Truran produced 99 different reactions only in 12C carbon burning net work and 23Na,20Ne, 24Mg,27Al,29Si, and some31P elements are also produced. Beside these Li, Be, B ( Known as leptons)are also produced in the stars due to hydrogen burning. Another more most elementary particles are produced in huge quantities. They are Neutrinos or ghost particles due to hydrogen burning procedure ( Professor Pranab Bhattacharya & Mr. Rupak Bhattacharyya). Conversion of hydrogen into helium in the center of the stars or of the Sun, not only accounts for Sun’s brightness in photons of visible light. It also produces a radiance of a more ghostly kind. The sun glows faintly in neutrinos , which like photons, weight nothing and travel at speed of light. Neutrinos emitted from Sun carry an intrinsic angular momentum or spin while photons has no spin. Matter is transparent to neutrinos which can pass effortlessly through the earth and through the Sun. Only a tiny fraction of them is stopped by intervening matter. As you look up our sun, a billions neutrinos pass through your eye ball. They are not stopped by Retina as ordinary photons do ,but continue unmolested through the back of your head. The curious part is that if at night if I look down at ground, towards the place where sun would be, almost exactly same numbers of solar neutrinos pass through my eye ball, pouring through an interposed earth which is as transparent to neutrinos as a plane of clear glass is to visible light. Neutrinos on very rare occasion convert chlorine atoms into argon atoms with the same number of protons and neutrons. Davis first used a beautiful technique of Pontecours and Alvarez based on the reaction 37C1(V,e-)37Ar to place an upper limit on the solar neutrinos flux on earth
The previous view regarding the “L atoms elements” was that each star makes it’s own share of these “L atoms elements”i.e (autogenously origin). But the concept of autogenic view has been now abandoned, because highest abundance values for stellar Li & Be have shown to be not larger than interstellar upper limit. The formation of each “L atoms” requires the acceleration of about 1erg fast proton. To account auto genetically for lithium abundance in T. Tauri stars (L1/H=109), the time integrated amount production of energy into particle acceleration must be comparable with gravitational release, implying an unlikely high efficiency for acceleration mechanism. So nuclear mechanism is responsible for generation of “L atoms” in the star. It involves high-energy process (Thermonuclear reactions). These L atoms” can be formed in two different ways within the stellar interiors. By the collision of incident light particles on the heavier atoms of interstellar gas (For instance fast protons on stationary C, N, O) or the reverse (for instance fast C, N, O on hydrogen at rest). In the first case the Products “ L atoms are to remain in rest, while in the second case, the products are moving at a velocity comparable with that of cosmic rays. The fate of “ L atoms” generated by fast protons on stationary C, N, O stationary atoms and are all rapidly thermalised and become part of ISM.
“L atoms” generated by reverse process have a fate which depends on the initial energy of “L atoms”. L atoms with energy E 0.3Gev neucleon-1 will suffer nuclear transformation of various elements in the stellar interior.
Analysis of Old stars can give us some idea that heavy elements are produced in the interior of the stars and are subsequently ejected into the ISM either through the supernova explosion or through stellar winds or through cosmic rays. The total mass loss, from all stars in a galaxy will be roughly 1MO per year. A fraction of these accumulate in the galactic nuclei, which are center of the gravitational attraction. The halo of our galaxy is nearly spherical region containing very old stars, which have a smaller content of heavy elements than our sun has. It is usually assumed that some how cloud of gas condensed to form our galaxy and that the halo stars were formed during the collapse process and left with a nearly spherical distribution. These stars are ultra high velocity stars. These stars show weak spectral lines corresponding to abundance of carbon and heavier elements [relative to hydrogen] that are lower than our Sun. Because these stars are oldest in our galaxy quite distinct type of nuclear process have been postulated for different groups of elements. The most abundant nuclei are 32S and 58Fe those can be formed by silicon burning process while 16O, 20Ne,23Na 24Mg,28S may be produced by explosive carbon burning process. When heavier elements notably Sr, Y, Zr, Ba etc require neutron capture on slow time scale, by iron group nucleotide already present in the star. A peculiar type of star 73 DRA has been investigated for many a time. It is full of chromium with europium and strontium. The star showed the presence of Cr, Eu, Sr and also Mn, Fe, Ni, in gaseous form while osmium (z=76) is present in both neutral and ionized form. The importance of these heavy elements is that, some of them such as Iridium, gold, uranium are also produced in the stars in the gamma process of nucleus synthesis [Neutron capture slow process]
So Helium, L atoms, Carbon, Iron, gold, chromium, nickel, silicon and many other elements are built up in the stellar interior. Although the net fusing of hydrogen into helium dominates however at this stage. Helium builds up in the core. The supply of hydrogen fuel diminishes and eventually becomes in sufficient to provide energy to hold up the strain position. As the energy production decreases, the core of the star contracts and heats up through release of gravitational energy. With a hotter center there is a greater outward pressure and the outer layer of the star expands, so that the star now becomes a RED GIANT. The red giant has a radius hundred times that of a sun. Mean while in the hotter core a new series of fusion reactions begins and with the helium as the fuel many elements like carbon oxygen, neon, magnesium. When helium will exhaust as a fuel, the carbon burning process will start as 12C as a fuel in the star. In any star the internal temperature and density and therefore the rate at which the energy is generated depend sensitively on the opacity of the stellar material or in other words, on the ease with which the photons can escape from the stellar core. In simple terms you can say greater the opacity harder it is for heat to get out making core hotter. Opacities in normal star can be calculated reliably from knowledge for the abundance of the constituent elements and their ionization site
Suernova-: Another important thing in our universe are the supernovas or novas. The supernovas are the explosion of the central core or outer core of a giant massive star. These supernovas are found in the biniary star system. A star may end its life cycle either in the form of a RED GIANT or in the form of a white dwarf or in the form of a “ black Dwarf” or in the form of “ neutron Star” or in Black Hole” or in the form of Supernova Explotion”. When the explosion of a star occurs in small scale, we call it Nova. In Big bang concept, apart from hydrogen, a little helium was produced. Every atom of every element had been built up by the nuclear fusion reaction in the stellar pressure cooker. The elements only could arrive in the interstellar space to mingle in the clouds of forminig protostars is through this supernovas Novas are however quite different from supernovas. Novas occur in biniary star system and are powered by silicon or carbon fusion. Supernovas occur in single associated with old population II stellar system such as elliptic galaxies and in globular clusters. The classical supernovas are therefore a subset of the cataclysmic variable class of objects, which undergoes out bursts with peak luminiocity ~ 5x1037 to 5x 1038 ergs S-1 in every 104 to 105 years. Around 10-5 to 10-4 MO material are ejected at velocity typically 1000 Kms-1 at each outburst of supernova. The central system is a semi detached binary stars, containing a white dwarf . Classical supernova out burst was observed in 1901, where as dwarf nova out burst was first observed in 1986.
Supernovas are two types Type-1(SN-I) and Type 2(SN_II) supernovas. Most astronomers agree that a type 1a supernova starts with a white dwarf — an aging star that crams as much mass as the sun into a volume no bigger than Earth. Most white dwarfs are cold and inert. But if the star has a companion, it will siphon mass off the neighbor star until tipping the scales at about 1.4 solar masses. At that mass, the white dwarf becomes dense and hot enough to initiate an explosion.mass accreting white dwarfs, in close binary system of stars are Type-1 supernovas, while low mass (M70t in close binary system of stars are Type-1 supernovas, while low mass (M70t
in close binary system of stars are Type-1 supernovas, while low mass (M70t
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