Is Our Understanding of the Space of Einstein Metrics Limited?

In summary, the paper discusses the Hartle-Hawking wave function for spacetimes with a negative cosmological constant and how it develops sharp peaks at certain calculable geometries for various spatial topologies. The statement on page 2 mentions that our understanding of the space of Einstein metrics is limited, leading to a lack of complete understanding of this phenomenon. It is suggested that this analysis could potentially make testable predictions about the geometry and topology of the Universe. This limitation is more relevant to quantum gravity rather than classical gravity. Additionally, the conversation briefly explores the possibility of a relationship between the Hawking-Hartle wave function and quantum uncertainty.
  • #1
Naty1
5,606
40
http://arxiv.org/PS_cache/gr-qc/pdf/0310/0310002v3.pdf
...we show that for many spatial topologies, the Hartle-Hawking wave function for a spacetime with a negative cosmological constant develops sharp peaks at certain calculable geometries.

Can someone explain the following statement on page 2 of the paper regarding "our limited understanding of the space of Einstein metrics"...

...for a wide class of manifolds, the sum over topologies produces sharp peaks in the Hartle-Hawking wave function that could not have been guessed by looking at any single contribution. Because of limits to our present understanding of the space of Einstein metrics, a complete, systematic understanding of this phenomenon is still lacking, but ultimately it may be possible to use this sort of analysis to make testable predictions about the geometry and topology of the Universe.

I'm just asking in general, not specifically related to the paper...Is this general statement relative to our universe as well...one a positive cosmological constant?? How is our knowledge limited?? Does this imply a weakness in relativity?


Separately, anyone aware of any papers looking at a possible relationship between the Hawking-Hartle wave function and uncertainty?? Seems like, maybe, if there were wave function peaks [with a positive cosmological constant] they could be related to virtual particles and maybe quantum uncertainty?

Thanks
 
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  • #2
Naty1 said:
I'm just asking in general, not s...fold"]http://en.wikipedia.org/wiki/4-manifold
 
  • #3
More a weakness of a quantum gravity than classical gravity...

ok, that makes sense!
 

1. What is the space of Einstein metrics?

The space of Einstein metrics is a mathematical concept that refers to the set of all possible metrics on a given space that satisfy the Einstein field equations in general relativity. These equations describe the relationship between the curvature of space-time and the distribution of matter and energy within it.

2. What is the significance of the space of Einstein metrics?

The space of Einstein metrics is important in understanding the geometry and physics of our universe. It allows us to study the possible shapes and structures of space-time and how they are affected by the presence of matter and energy. It also has applications in other fields such as differential geometry and mathematical physics.

3. How is the space of Einstein metrics related to the theory of general relativity?

The space of Einstein metrics is directly related to the theory of general relativity, as it is defined by the Einstein field equations. These equations are the cornerstone of general relativity and describe how the curvature of space-time is determined by the distribution of matter and energy within it.

4. Can the space of Einstein metrics be visualized or understood intuitively?

The space of Einstein metrics is a high-dimensional mathematical concept and therefore cannot be easily visualized or understood intuitively. However, certain examples and special cases can be visualized, such as the Schwarzschild metric which describes the geometry around a non-rotating black hole.

5. How is the space of Einstein metrics studied and researched?

The space of Einstein metrics is a topic of interest in both mathematics and physics, and therefore is studied and researched using various methods and techniques from these fields. This includes using differential geometry, topology, and numerical simulations to analyze and understand the properties of these metrics and their implications in general relativity and other areas of study.

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