Origin of the Universe,,,,Bang or no Bang

[Pluto]

G'day from the land of ozzzzz

 

jack said

 

I have no scientific background to support or deny any claims. I can only offer my opinion, but to me, I don't see how the big bang theory could be possible, or at least how it could have come from one atom.

 

Just where did this atom come from? Did it just suddenly mysteriously appear?

or did it form from a previous universe that was made up of countless stars which over time were pulled into the center by a core of increased gravity from feeding on the mass of swallowed up stars and galaxies? At what point would this mass say enough is enough and spit everything back out again? If it were able to shrink down to the size of an atom, what exactly would touch it off to explode? Also, wouldn't this mean the universe would have to have a border to be able to gather up the more distant stars, and galaxies. As the old saying goes, what would be beyond the border.

 

Your point of view is quite simple and yet to the point.

 

A singularity is very theoretical and till this date is not proven.

 

So we look at the working parts of the universe and see how they recycle.

 

At what point would this mass say enough is enough and spit everything back out again?

 

We notice Neutron stars and black holes forming jets that expell matter and recycle and reform the galaxies. Maybe this is the process that is never ending.

[Pluto]

G'day from the land of ozzzzz

 

Everytime I come across a paper that is interesting I like to post it and get a feedback from someone.

 

 

One dimensional simulations of radiative collapse

One dimensional simulations of radiative collapse

[Pluto]

G'day from the land of ozzzzzzz

 

If nucleosynthesis of the elements are produced by solar actvity than what is the need of the BBT. I read these links and thought it maybe of interest to some. If these links need to be aborted because of the rules, Its ok.

 

[0807.0818] Nucleosynthesis in Metal-Free and Metal-Poor Stars

 

Nucleosynthesis in Metal-Free and Metal-Poor Stars

 

Authors: Yong-Zhong Qian

(Submitted on 4 Jul 2008)

 

Abstract: There have been a number of important recent developments in theoretical and observational studies of nucleosynthesis, especially regarding nucleosynthetic sources at low metallicities. Those selected for discussion here include the origin of Li6, the primary production of N, the s-process, and the supernova sources for three groups of metals: (1) C to Zn with mass numbers A<70, (2) Sr to Ag with A~90-110, and (3) r-process nuclei with A~130 and above.

 

 

[0807.0814] Chemical Evolution of Heavy Elements in the Early Galaxy: Implications for Stellar Sources

 

Chemical Evolution of Heavy Elements in the Early Galaxy: Implications for Stellar Sources

 

Authors: Yong-Zhong Qian

(Submitted on 4 Jul 2008)

 

Abstract: An overview of the sources for heavy elements in the early Galaxy is given. It is shown that observations of abundances in metal-poor stars can be used along with a basic understanding of stellar models to guide the search for the source of the heavy r-process nuclei (r-nuclei). Observations show that this source produces very little of the elements from C through Zn including Fe. This strongly suggests that O-Ne-Mg core-collapse supernovae (SNe) from progenitors of ~8-11M_sun are the source for the heavy r-nuclei. It is shown that a two-component model based on the abundances of Fe (from Fe core-collapse SNe) and Eu (from O-Ne-Mg core-collapse SNe) gives very good quantitative predictions for the abundances of all the other elements in metal-poor stars.

 

 

[0804.0969] Nucleosynthesis in Magnetically Driven Jets from Collapsars

Nucleosynthesis in Magnetically Driven Jets from Collapsars

 

Authors: Shin-ichiro Fujimoto, Nobuya Nishimura, Masa-aki Hashimoto

(Submitted on 7 Apr 2008)

 

Abstract: We have made detailed calculations of the composition of magnetically driven jets ejected from collapsars, or rapidly rotating massive stars, based on long-term magnetohydrodynamic simulations of their core collapse with various distributions of magnetic field and angular momentum before collapse. We follow the evolution of the abundances of about 4000 nuclides from the collapse phase to the ejection phase and through the jet generation phase using a large nuclear reaction network. We find that the r-process successfully operates only in energetic jets (> 1e51 ergs), such that U and Th are synthesized abundantly, even when the collapsar has a relatively weak magnetic field (1e10 G) and a moderately rotating core before the collapse. The abundance patterns inside the jets are similar to those of the r-elements in the solar system. About 0.01-0.06 Msun neutron-rich, heavy nuclei are ejected from a collapsar with energetic jets. The higher energy jets have larger amounts of Ni56, varying from 0.00037 to 0.06Msun. Less energetic jets, which eject small amounts of Ni56, could induce a gamma-ray burst (GRB) a supernova, such as GRB 060505 or GRB 060614. Considerable amounts of r-elements are likely to be ejected from GRBs with hypernovae, if both the GRB and hypernova are induced by jets that are driven near the black hole.

[FRIPRO]

G'day from the land of ozzzzzzz

 

If nucleosynthesis of the elements are produced by solar actvity than what is the need of the BBT. I read these links and thought it maybe of interest to some. If these links need to be aborted because of the rules, Its ok.

 

[0807.0818] Nucleosynthesis in Metal-Free and Metal-Poor Stars

 

Nucleosynthesis in Metal-Free and Metal-Poor Stars

 

Authors: Yong-Zhong Qian

(Submitted on 4 Jul 2008)

 

 

 

 

[0807.0814] Chemical Evolution of Heavy Elements in the Early Galaxy: Implications for Stellar Sources

 

Chemical Evolution of Heavy Elements in the Early Galaxy: Implications for Stellar Sources

 

Authors: Yong-Zhong Qian

(Submitted on 4 Jul 2008)

 

 

 

 

[0804.0969] Nucleosynthesis in Magnetically Driven Jets from Collapsars

Nucleosynthesis in Magnetically Driven Jets from Collapsars

 

Authors: Shin-ichiro Fujimoto, Nobuya Nishimura, Masa-aki Hashimoto

(Submitted on 7 Apr 2008)

 

SUBMITED BY FRIPRO>There is much truth in what you are telling us.If it pleases the sensors I would like to add a stero photo by NASA the would give all of you a lot of food for thought.

 

http://www.fripro.com/STEREO UNIVERSE UIDE.htm

 

Follow the instructions for Stereo viewing, an be amazed by what you see of the deepest space photos ever made by NASA Hubble Telescope.of our distant Universe.

 

We must understand if you look carefully at this Stero photo correctly you can see a small part of the real Universe' Globe. An the slowing red shift indicates rotation.

 

Also note all of the Galatic formations, independent of each other--complete galatic systems on a macular scale that one can hardly imagine.

[Pluto]

G'day fripro

 

You said

 

Also note all of the Galatic formations, independent of each other--complete galatic systems on a macular scale that one can hardly imagine.

 

Smile,,,,,I agree with you.

 

The Big Bang people want to hold onto the BBT as long as possible. Why????

God knows why.

[PhysBang]

If nucleosynthesis of the elements are produced by solar actvity than what is the need of the BBT.

Because no theory of stellar nucleosynthesis can account for the presence of hydrogen or the relative abundance of hydrogen to helium,

[Pluto]

G'day Physbang

 

You said

 

Because no theory of stellar nucleosynthesis can account for the presence of hydrogen or the relative abundance of hydrogen to helium,

 

I think you have it wrong.

 

Read on

 

[nucl-th/0610013] Nucleosynthesis in neutron-rich ejecta from quark-novae

Nucleosynthesis in neutron-rich ejecta from quark-novae

 

Authors: Prashanth Jaikumar (Ohio U., ANL), Bradley S. Meyer (Clemson U.), Kaori Otsuki (U. Chicago), Rachid Ouyed (U. Calgary)

(Submitted on 4 Oct 2006 (v1), last revised 20 Aug 2007 (this version, v3))

Abstract: We explore heavy-element nucleosynthesis by rapid neutron capture (r-process) in the decompressing ejecta from the surface of a neutron star. The decompression is triggered by a violent phase transition to strange quark matter (quark-nova scenario). The presence of neutron-rich large Z nuclei (40,95) < (Z,A) < (70,177), the large neutron-to-seed ratio, and the low electron fraction Ye ~ 0.03 in the decompressing ejecta present favorable conditions for the r-process. We perform network calculations that are adapted to the quark-nova conditions, and which mimic usual (n-gamma) equilibrium r-process calculations during the initially cold decompression phase. They match to dynamical r-process calculations at densities below neutron drip (4.10^11 g cm-3). We present results for the final element abundance distribution with and without heating from nuclear reactions, and compare to the solar abundance pattern of r-process elements. We highlight the distinguishing features of quark-novae by contrasting it with conventional nucleosynthetic sites such as type II supernovae and neutron star mergers, especially in the context of heavy-element compositions of extremely metal-deficient stars.

 

 

[astro-ph/0702573] Inhomogeneous Galactic halo: a possible explanation for the spread observed in s- and r- process elements

 

Inhomogeneous Galactic halo: a possible explanation for the spread observed in s- and r- process elements

 

Authors: G.Cescutti

(Submitted on 21 Feb 2007)

 

Abstract: The considerable scatter of the s- and r-process elements observed in low-metallicity stars, compared to the small star to star scatter observed for the alpha elements, is an open question for the chemical evolution studies. We have developed a stochastic chemical evolution model, in which the main assumption is a random formation of new stars, subject to the condition that the cumulative mass distribution follows a given initial mass function. With our model we are able to reproduce the different features of alpha-elements and s-and r-process elements. The reason for this resides in the random birth of stellar masses coupled with the different stellar mass ranges from where alpha-elements and s-and r-process elements originate. In particular, the sites of production of the alpha elements are the whole range of the massive stars, whereas the mass range of production for the s- and r-process elements has an upper limit of 30 solar masses.

 

 

[0708.4163] Chemical evolution of neutron capture elements in our Galaxy and in the dwarf spheroidal galaxies of the Local Group

Chemical evolution of neutron capture elements in our Galaxy and in the dwarf spheroidal galaxies of the Local Group

 

Authors: Gabriele Cescutti (Astronomy Department, Trieste University)

(Submitted on 30 Aug 2007)

 

Abstract: By adopting a chemical evolution model for the Milky Way already reproducing the evolution of several chemical elements, we compare our theoretical results with accurate and new stellar data of neutron capture elements and we are able to impose strong constraints on the nucleosynthesis of the studied elements. We can suggest the stellar sites of production for each element. In particular, the r-process component of each element (if any) is produced in the mass range from 10 to 30 Msun, whereas the s-process component arises from stars in the range from 1 to 3 Msun. Using the same chemical evolution model, extended to different galactocentric distances, we obtain results on the radial gradients of the Milky Way. We compare the results of the model not only for the neutron capture elements but also for alpha-elements and iron peak elements with new data of Cepheids stars. We give a possible explanation to the considerable scatter of neutron capture elements observed in low metallicity stars in the solar vicinity, compared to the small star to star scatter observed for the alpha-elements. In fact, we have developed a stochastic chemical evolution model, in which the main assumption is a random formation of new stars, subject to the condition that the cumulative mass distribution follows a given initial mass function. With our model we are able to reproduce the different features of neutron capture elements and alpha-elements. Finally, we test the prescriptions for neutron capture elements also for the dwarf spheroidal galaxies of the Local Group. We predict that the chemical evolution of these elements in dwarf spheroidal galaxies is different from the evolution in the solar vicinity and indicates that dwarf spheroidal galaxies (we see nowadays) cannot be the building blocks of our Galaxy.

 

 

 

The Nuclear Cycle that Powers the Stars: Fusion, Gravitational Collapse and Dissociation

[astro-ph/0511379] The Nuclear Cycle that Powers the Stars: Fusion, Gravitational Collapse and Dissociation

 

The Origin, Composition, and Energy Source for the Sun

[astro-ph/0411255] The Origin, Composition, and Energy Source for the Sun

[freeztar]

G'day Physbang

 

I think you have it wrong.

 

Read on

 

The links you give do nothing to refute Physbang's statement. If I am mistaken, then please point out specifically where you have refuted his claim.

[modest]

[nucl-th/0610013] Nucleosynthesis in neutron-rich ejecta from quark-novae

 

Heavy elements. PhysBang is pointing out that there aren't many of them which there would be if there were no big bang. To counter this you link a paper which proposes a new method of creating more heavy elements! This is not only consistent with PhysBang's argument, it supports it. ;)

 

Can you explain how the theoretical ejection of heavy elements from a neutron star supports your argument? Or, is this just a random article you picked out that mentions heavy elements? Or, are you trying to support what PhysBang said? I honestly cannot figure any sensible reason you posted this. Can you please comment on this particular paper - why you posted it - what you think it claims - etc.

 

Do not post links to other sites as proof of your claims without commenting what the relevant sites say and why they are important to the current discussion.

 

Hypography site rules

 

~modest

[Pluto]

G'day from the land of ozzzzzzzzz

 

I have read your comments

 

I will come back to it

 

Short of time.

[Pluto]

G'day from the land of ozzzzz

 

I have posted the previous posts as information to the workings of stars and the formation of the elements.

 

I know its not complete.

 

But! I thought this link hits the nail on the head

 

The Nuclear Cycle that Powers the Stars: Fusion, Gravitational Collapse and Dissociation

Authors: O. Manuel, Michael Mozina, Hilton Ratcliffe

(Submitted on 12 Nov 2005)

Abstract: The finding of an unexpectedly large source of energy from repulsive interactions between neutrons in the 2,850 known nuclides has challenged the assumption that H-fusion is the main source of energy that powers the Sun and other stars. Neutron repulsion in compact objects produced by the collapse of stars and collisions between galaxies may power more energetic cosmological events (quasars, gamma ray bursts, and active galactic centers) that had been attributed to black holes before neutron repulsion was recognized. On a cosmological scale, nuclear matter cycles between fusion, gravitational collapse, and dissociation (including neutron emission) rather than evolve in one direction by fusion. The similarity Bohr noted between atomic and planetary structures may extend to a similarity nuclear and stellar structures.

 

 

AGN, quasars, and neutron stars are highly prevalent, observable phenomena in all parts of the known universe. They have two significant properties in common: Exceptionally high specific gravity and the generation of copious amounts of “surplus” energy. In view of the repulsive forces recently identified between neutrons [3-5] and the frequency and products of galactic collisions [22], we conclude that neutron repulsion is the main energy source for the products of galactic collisions.

 

 

We know that Neutrons are produced and that these Neutrons can be changed to Protons and than to Hydrogen. Tha Via fusion to other elements.

 

As we speak I'm reading through compact matter such as Neutron, quark and composites and the processes involved in the production of matter from ejected degenerated matter.

 

Do I understand it fully? No way and it will take me a few years to do so.

The more I read, it seems that I'm learning that there is more to this than meets the eye.

 

As I grow I hope to add more concrete evidence to this topic.

[coldcreation]

My favorite link, THE ORIGIN OF HELIUM AND THE OTHER LIGHT ELEMENTS, provides a very nice explanation for light element production and abundances observed without the need of ad hoc model-based primordial creation.

 

More soon...:shrug:

 

 

cc

[Pluto]

G'day cold creation

 

 

Thank you coldcreation

 

Darn,,,,,,,,,,I had that on pdf file

 

 

THE ORIGIN OF HELIUM AND THE OTHER LIGHT ELEMENTS

http://cass.ucsd.edu/personal/burbidge/pubs/985623.pdf

 

ABSTRACT

The energy released in the synthesis of cosmic 4He from hydrogen is almost exactly equal to the energy contained in the cosmic microwave background radiation. This result strongly suggests that the 4He was produced by hydrogen burning in stars and not in the early stages of a big bang. In ddition, we show that there are good arguments for believing that the other light isotopes, D, 3He, 6Li, 7Li, 9Be, 10B, and 11B, were also synthesized in processes involving stars. By combining these results with the earlier, much more detailed work of Burbidge et al. and of Cameron, we can finally conclude that all of the chemical elements were synthesized from hydrogen in stars over a time of about 10^11 yr.

 

The next step of research for my learning is in the formation of subatomic particles, such as Quarks to Neutrons and protons and than to Hydrogen.

 

Interesting to look at the influence of the so called monopoles to Neutrons and protons.

[CraigD]

But! I thought this link hits the nail on the head

 

The Nuclear Cycle that Powers the Stars: Fusion, Gravitational Collapse and Dissociation

Authors: O. Manuel, Michael Mozina, Hilton Ratcliffe

…

We know that Neutrons are produced and that these Neutrons can be changed to Protons and than to Hydrogen. Tha Via fusion to other elements.

That neutron stars, AGNs, or other very dense astronomical objects emit large number of neutrons is far from an accepted hypothesis, so I wouldn’t agree that “we know” is an correct description of it. The hypothesis is mostly advanced by a small number of authors, principly Oliver K. Manuel, formerly of UM-Rolla. Though not well known, Manuel is better known for his hypothesis that the Sun is not a main-sequence star, but rather the mostly iron remnant of a supernova – pretty much the same as his ideas about galaxies, but on the smallest possible scale (see University Of Missouri-Rolla. "The Sun: A Great Ball Of Iron?." ScienceDaily 17 July 2002. 16 August 2008, or The Sun is a ball of Iron!).

 

Manuel is somewhat infamous (or famous, among his supporters) for offering sometimes bizarre alternative hypotheses to well accepted ones, a trait that’s wise to keep in mind when reading him, so as not to mistake him for an “accepted mainstream scientist”. The breath of his contrarianism is extensive – a nuclear chemist by education, he opposes the mainstream consensus in domains from the very small (nuclear chemistry), the midsize (the Sun and stars), to the very large (cosmology), with forays into the politically topical (global warming, which he denies).

 

Although it should not, in principle, be a factor in considering his scientific opinions, it’s IMHO informative to note that Manuel has, to put it mildly, a bizarre personal life. His 5 now-adult children allege that he repeatedly raped them, from 1967 to 1990, which lead to his criminal indictment and suspension from UMR in 2006. His prosecution appears to have been ongoing as of 2007, after which I’ve been unable to find any news. This appears to explain why he’s not written any scientific papers recently. (souces: themissouriminer.com - Dr. Oliver Manuel arrested for multiple counts of rape and sodomy of his children; Professor emeritus faces sexual abuse charges | KY3 | Related Content)

[Pluto]

G'day from the land of ozzzzzzzz

 

Hello CraigD

 

I have read

The Sun: A Great Ball Of Iron?

The Sun: A Great Ball Of Iron?

 

ScienceDaily (July 17, 2002) — For years, scientists have assumed that the sun is an enormous mass of hydrogen. But in a paper presented before the American Astronomical Society, Dr. Oliver Manuel, a professor of nuclear chemistry at UMR, says iron, not hydrogen, is the sun's most abundant element.

 

Oliver does not state that Iron is the most abundant element.

 

But! to assume that the Sun is an enormous mass of Hydrogen is also a mistake.

Two problems arise. One keeping the solar envelope from expanding and secondly over heating. These two need to be controlled by an extreme density mass at the core. Normal elements are unable to reach extreme densities, so I would asssume some form of degenerate matter, maybe a Neutron composite.

 

 

CraigD you said

 

Though not well known, Manuel is better known for his hypothesis that the Sun is not a main-sequence star, but rather the mostly iron remnant of a supernova – pretty much the same as his ideas about galaxies, but on the smallest possible scale

 

You have read Olivers words out of context. He has not implied a Iron remnant but a Neutron core Remnant that formed a solar envelope that we see as our Sun. This process is not to far from star formation theory.

 

Just thinking aloud: Although other papers that I have read talk of Iron crust around the core of a Neutron Star.

 

I understand that I'm still learning and that it will take me years to even understand the full complexity.

 

One more thing I never look at the personal life of a scientist. Even Einstein had a black book.

[Moontanman]

G'day from the land of ozzzzzzzz

 

Hello CraigD

 

I have read

The Sun: A Great Ball Of Iron?

The Sun: A Great Ball Of Iron?

 

 

 

Oliver does not state that Iron is the most abundant element.

 

But! to assume that the Sun is an enormous mass of Hydrogen is also a mistake.

Two problems arise. One keeping the solar envelope from expanding and secondly over heating. These two need to be controlled by an extreme density mass at the core. Normal elements are unable to reach extreme densities, so I would asssume some form of degenerate matter, maybe a Neutron composite.

 

 

CraigD you said

 

 

 

You have read Olivers words out of context. He has not implied a Iron remnant but a Neutron core Remnant that formed a solar envelope that we see as our Sun. This process is not to far from star formation theory.

 

Just thinking aloud: Although other papers that I have read talk of Iron crust around the core of a Neutron Star.

 

I understand that I'm still learning and that it will take me years to even understand the full complexity.

 

One more thing I never look at the personal life of a scientist. Even Einstein had a black book.

 

If that is ture what does it say about the age of the earth and the life time of the sun?

[Pluto]

G'day from the land of ozzzzzzz

 

Moontanman said

 

If that is ture what does it say about the age of the earth and the life time of the sun?

 

Age of the earth about 5 billion years. First sedimentary rocks I think about 4.2 billion years ago indicating water flow.

 

Our Sun is estimated to be about 5 billion give or take. It may have another 5 to 7 billion years. But! I think the Milky Way and Andromeda have a meeting in about 4 to 5 billion years time. Our Sun belongs to a cluster of stars and merging maybe a possiblity.

 

The density and mass of the core would determine the life of the Star.

 

At this moment I reading up papers on Neutron and Quark composites cores in stars.

 

I hope one to understand. Right now I know very little.