fzero said:...
the fundamental issue that determines when QG is important is identifying the situations where classical GR is unreliable.
fzero said:Quantum gravity is important in two basic situations. The first is when the object being studied itself causes a curvature in spacetime that is of order the (Planck mass)^2. Generally this happens for a black hole or big bang-type singularity, where there is actually a point in spacetime where the curvature is infinite.
The second case would be where our probe of a system is energetic enough that we cannot ignore the fact that the probe itself changes the background geometry. This is again related to the momentum of a single probe or, in the case of multiple probes, that the sum of energies approaches the Planck mass.
There are probably many philosophical or foundational questions that address properties of quantum gravity, but the fundamental issue that determines when QG is important is identifying the situations where classical GR is unreliable.
rogerl said:Is the question of how matter is connected with spacetime independent of quantum gravity?? Or can we already answer now how matter made of quantum object is connected to spacetime? I mean, how does the interface work?
jal said:First ... we still don't know what happens inside the perfect liquid and what is in it.
Second ... if there are more than 3 space dimensions then Quantum Gravity will not related to Planck Scale.
jal
Quantum Gravity is a theoretical framework that aims to reconcile the theories of quantum mechanics and general relativity, which are the two main pillars of modern physics. It attempts to describe the behavior of matter and energy on a very small scale, where quantum effects become significant, while also explaining the effects of gravity on a large scale.
The Planck Scale, also known as the Planck length, is the scale at which quantum effects are believed to become significant in the fabric of space-time. Quantum Gravity is related to the Planck Scale because it is at this scale that the effects of both quantum mechanics and general relativity are expected to interact and become relevant.
No, Quantum Gravity is not the same as the Theory of Everything. While Quantum Gravity aims to unify quantum mechanics and general relativity, the Theory of Everything goes further and attempts to explain all fundamental forces and particles in the universe. Quantum Gravity is just one piece of the puzzle in the search for a complete theory of the universe.
Currently, there is no direct experimental evidence for Quantum Gravity. This is because the scale at which quantum effects and gravity interact is so small that it is beyond our current technological capabilities to observe. However, there are some ongoing experiments, such as the search for gravitational waves, that may provide indirect evidence for Quantum Gravity.
Studying Quantum Gravity is crucial for our understanding of the fundamental laws that govern the universe. It has the potential to bridge the gap between the theories of quantum mechanics and general relativity, which have been extremely successful in their respective domains but are fundamentally incompatible. Additionally, a better understanding of Quantum Gravity could lead to breakthroughs in fields such as cosmology and particle physics.