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I have seen on this site some questions regarding the nature of gravitational-force, and the ways in which it could be interpreted. Most of them mention that the space-time fabric came into existence due to the big-bang. But I cannot understand why it came into existence during the big-bang, and had no earlier existence. Also, how should I develop my notion regarding the form of a gravitational-singularity? My current concept holds it that a gravitational singularity, is a compact-clump of spatial and temporal curves, where laws of Classical Physics are rarely(?) valid. But more often, I "like" to compare a garvitational-singularity with a huge go-down of energy, that is longing to burst open, and thus, maximize its entropy, and minimize its energy. If in-any way my current-notion is to a-certain degree acceptable, would it then be correct for me to guess that "minute"(?)-fabrics of space-time come into existence whenever there is a conversion of matter into an equivalent amount of energy, according to Einstein's equation E=m.(c^2) ?

Please take care of the fact that I am a high-school student-with a corresponding limited-knowledge on Physics, and especially, Quantum-Mechanics.

abstract
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    _ space-time fabric came into existence due to the big-bang_ This doesn't seem to be a physics statement. – jinawee Jun 08 '14 at 09:47
  • @jinawee: little did I mention in my post that I am a Physics student--I am a learner. As for precision, see the post of Ooker in http://physics.stackexchange.com/questions/116608/how-exactly-does-gravity-work: "How do space and time appear? Big Bang". This, he posted in response to a question asked by a high-school student. However, I am sorry to you all for my incapability to enhance precision in this question. – abstract Jun 08 '14 at 11:24

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I will address the part of the question which discusses gravitational singularities.

There are many types of singularities on manifolds, and more generally topological spaces. In general relativity, you are likely to encounter:

  • Coordinate Singularity: These arise because we have used inappropriate coordinates; for example the Schwarzschild black hole metric may be singular at $r=2GM$. However, these are not true physical singularities, and may be removed with diffeomorphisms.
  • Curvature Singularity: A true physical singularity which arises when a curvature scalar (as it is invariant under diffeomorphisms) is singular. For example, at the center of a black hole.
  • Conical Singularity: A singularity which occurs, for example, when we encounter a point at the tip of a cone, which is taken to be infinitesimally small. To understand why it is problematic, consider a geodesic at that point; when you arrive at the tip which way do you continue?

At curvature singularities, or regions of high curvature, we cannot resort only to general relativity; at this point quantum gravity becomes important. As Professor Tong states, the question of singularities is morally equivalent to high energy scattering. The short-distance (Planck scale) phenomena of spacetime, after Fourier transform, is governed by high energy gravitons.

Other Singularities:

Another example of a singularity arises when studying orbifolds. Given a smooth manifold $X$ and a discrete isometry group $G$, an orbifold is the quotient space, $X/G$ and a point in the orbifold corresponds to an orbit in $X$ consisting of a point and all its images under the $G$ group action.

If certain elements of $G$ leave a point in $X$ invariant, then the orbifold has an orbifold singularity, which is a type not really encountered in general relativity, but rather string theory. It may be removed with the use of algebraic geometry, for example by replacing certain regions with Eguchi-Hanson spaces for the case of $T^4/\mathbb{Z}_4$.

JamalS
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  • You are aware that the OP won't understand anything you wrote. I like high level answers to any type of question, so just saying. – jinawee Jun 08 '14 at 10:12
  • @jinawee: Yes, I know, but hopefully it will motivate him to continue learning. I often write answers aimed at the whole community, rather than the OP. – JamalS Jun 08 '14 at 10:19
  • @JamalS: A "bit" simpler--please...portion regarding "Other singularities" – abstract Jun 08 '14 at 11:28
  • @abstract: What part do you not understand, specifically? – JamalS Jun 08 '14 at 11:33
  • What are Eguchi-Hanson spaces? – abstract Jun 08 '14 at 12:23
  • @abstract: An Eguchi-Hanson space is a smooth, non-compact, Ricci-flat, Kahler manifold, with $S^3/\mathbb{Z}_2$ boundary. Essentially we fix the singularities (of which there are sixteen for the example I mentioned) by cutting out a ball and replacing it with the space. We then take a certain limit to ensure the final manifold is really Calabi-Yau. – JamalS Jun 08 '14 at 12:50
  • hmmm-------yeah – abstract Jun 08 '14 at 13:11
  • @abstract: Well, if you can't grasp the differential geometry, you do at least understand, visually, what blowing up a singularity is? In the case I mentioned, it's like you're scooping it out, and putting something back in its place. – JamalS Jun 08 '14 at 13:14
  • taking out a part of an object and replacing it with space, that exactly conforms to the bounded-curved surface of the object, and the interior---I get this much. – abstract Jun 08 '14 at 13:21
  • @JamalS: please also discuss about the other part (involving understanding). – abstract Jun 09 '14 at 07:02