by neufer » Thu Jan 09, 2014 6:14 pm
Chris Peterson wrote:Ann wrote:
Oxygen, in fact, is formed in stars (and even in supernovae, I think). But our dear old Earthly O2, which we breathe, is formed by green plants through photosynthesis. But those tadpoles don't get to breathe any of that. Lucky us, though!
That's a somewhat confusing statement, with the word "form" being used in two different ways.
Oxygen is primarily
created in the CNO hydrogen/helium fusion process.
The
CNO hydrogen/helium fusion process mostly produces
unstable oxygen isotopes
(or stable oxygen isotopes that quickly burn into fluorine by fusing with hydrogen).
Stable oxygen isotopes are primarily
a byproduct of the triple-
alpha process helium/carbon fusion process:
http://en.wikipedia.org/wiki/Triple-alpha_process wrote:
<<The triple-alpha process is a set of nuclear fusion reactions by which three helium-4 nuclei (alpha particles) are transformed into carbon.
Older stars start to accumulate helium produced by the proton–proton chain reaction and the carbon–nitrogen–oxygen cycle in their cores. The products of further nuclear fusion reactions of helium with hydrogen or another helium nucleus produce lithium-5 and beryllium-8 respectively, both of which are highly unstable and decay almost instantly back into smaller nuclei. When the star starts to run out of hydrogen to fuse, the core of the star begins to collapse until the central temperature rises to 108 K (8.6 keV). At this point helium nuclei are fusing together faster than their product, beryllium-8, decays back into two helium nuclei.
Once beryllium-8 is produced a little faster than it decays, the number of beryllium-8 nuclei in the stellar core increases to a large number. Then in its core there will be many beryllium-8 nuclei that can fuse with another helium nucleus to form carbon-12, which is stable:
Because the triple-alpha process is unlikely, it needs a long time to produce much carbon. One consequence of this is that no significant amount of carbon was produced in the Big Bang because within minutes after the Big Bang, the temperature fell below that necessary for nuclear fusion.
Ordinarily, the probability of the triple alpha process is extremely small. However, the beryllium-8 ground state has almost exactly the energy of two alpha particles. In the second step, 8Be + 4He has almost exactly the energy of an excited state of 12C. These resonances greatly increase the probability that an incoming alpha particle will combine with beryllium-8 to form carbon. The existence of this resonance was predicted by Fred Hoyle before its actual observation, based on the physical necessity for it to exist, in order for carbon to be formed in stars. In turn, prediction and then discovery of this energy resonance and process gave very significant support to Hoyle's hypothesis of stellar nucleosynthesis, which posited that all chemical elements had originally been formed from hydrogen, the true primordial substance.
As a side effect of the process, some carbon nuclei can fuse with additional helium to produce a stable isotope of oxygen and release energy:
- 12C + 4He → 16O + γ (+7.162 MeV)
This creates a situation in which stellar nucleosynthesis produces large amounts of carbon and oxygen but only a small fraction of these elements is converted into neon and heavier elements. Both oxygen and carbon make up the 'ash' of helium-4 burning. The anthropic principle has been controversially cited to explain the fact that nuclear resonances are sensitively arranged to create large amounts of carbon and oxygen in the Universe.
Fusion processes produce nuclides only up to nickel-56 (which decays later to iron); heavier elements (those beyond Ni) are created mainly by neutron capture. The slow capture of neutrons, the s-process, produces about half of these heavy elements. The other half are produced by rapid neutron capture, the r-process, which probably occurs in a core-collapse supernova.>>
[quote="Chris Peterson"][quote="Ann"]
Oxygen, in fact, is formed in stars (and even in supernovae, I think). But our dear old Earthly O[sub]2[/sub], which we breathe, is formed by green plants through photosynthesis. But those tadpoles don't get to breathe any of that. Lucky us, though![/quote]
That's a somewhat confusing statement, with the word "form" being used in two different ways.
Oxygen is primarily [i]created [/i]in the CNO hydrogen/helium fusion process.[/quote]
The [url=http://en.wikipedia.org/wiki/CNO_cycle]CNO hydrogen/helium fusion process[/url] mostly produces [u][b][color=#FF0000]un[/color][/b][/u]stable oxygen isotopes
(or stable oxygen isotopes that quickly burn into fluorine by fusing with hydrogen).
Stable oxygen isotopes are primarily [u]a byproduct[/u] of the triple-[url=http://en.wikipedia.org/wiki/Alpha_process]alpha process[/url] helium/carbon fusion process:
[quote=" http://en.wikipedia.org/wiki/Triple-alpha_process"]
[float=right][img3=""]http://upload.wikimedia.org/wikipedia/commons/8/8d/Triple-Alpha_Process.png[/img3][/float]<<The triple-alpha process is a set of nuclear fusion reactions by which three helium-4 nuclei (alpha particles) are transformed into carbon.
Older stars start to accumulate helium produced by the proton–proton chain reaction and the carbon–nitrogen–oxygen cycle in their cores. The products of further nuclear fusion reactions of helium with hydrogen or another helium nucleus produce lithium-5 and beryllium-8 respectively, both of which are highly unstable and decay almost instantly back into smaller nuclei. When the star starts to run out of hydrogen to fuse, the core of the star begins to collapse until the central temperature rises to 108 K (8.6 keV). At this point helium nuclei are fusing together faster than their product, beryllium-8, decays back into two helium nuclei.
Once beryllium-8 is produced a little faster than it decays, the number of beryllium-8 nuclei in the stellar core increases to a large number. Then in its core there will be many beryllium-8 nuclei that can fuse with another helium nucleus to form carbon-12, which is stable:
Because the triple-alpha process is unlikely, it needs a long time to produce much carbon. One consequence of this is that no significant amount of carbon was produced in the Big Bang because within minutes after the Big Bang, the temperature fell below that necessary for nuclear fusion.
Ordinarily, the probability of the triple alpha process is extremely small. However, the beryllium-8 ground state has almost exactly the energy of two alpha particles. In the second step, 8Be + 4He has almost exactly the energy of an excited state of 12C. These resonances greatly increase the probability that an incoming alpha particle will combine with beryllium-8 to form carbon. The existence of this resonance was predicted by Fred Hoyle before its actual observation, based on the physical necessity for it to exist, in order for carbon to be formed in stars. In turn, prediction and then discovery of this energy resonance and process gave very significant support to Hoyle's hypothesis of stellar nucleosynthesis, which posited that all chemical elements had originally been formed from hydrogen, the true primordial substance.
[b][color=#0000FF]As a side effect of the process, some carbon nuclei can fuse with additional helium to produce a stable isotope of oxygen and release energy:[/b]
[list][size=150][sup]12[/sup]C + [sup]4[/sup]He → [sup]16[/sup]O + γ (+7.162 MeV)[/size][/list][/color]This creates a situation in which stellar nucleosynthesis produces large amounts of carbon and oxygen but only a small fraction of these elements is converted into neon and heavier elements. Both oxygen and carbon make up the 'ash' of helium-4 burning. The anthropic principle has been controversially cited to explain the fact that nuclear resonances are sensitively arranged to create large amounts of carbon and oxygen in the Universe.
Fusion processes produce nuclides only up to nickel-56 (which decays later to iron); heavier elements (those beyond Ni) are created mainly by neutron capture. The slow capture of neutrons, the s-process, produces about half of these heavy elements. The other half are produced by rapid neutron capture, the r-process, which probably occurs in a core-collapse supernova.>>[/quote]