General Relativity is the name provided for Einstein's theory of gravity that was defined in Chapter 2 of my book. As the idea is usually shown, it explains gravity as a curvature in four-dimensional space-time. Now it is a concept far over and above the reach of common people. Just the concept of four-dimensional space-time causes the majority of us to shudder ... The answer in Quantum Field Theory is easy: Space is space and time is time, and there is no curvature. In QFT gravity is a quantum field in ordinary three-dimensional space, just like the other 3 force fields (EM, strong and weak).
This does not actually suggest that four-dimensional notation is not useful. It is a convenient way of handling the mathematical connection between space and time which is needed by special relativity. One could almost say that physicists couldn't live without having it. Still, spatial and temporal evolution are fundamentally different, and I say shame on people who aim to foist and push the four-dimensional concept onto the general public as vital to the understanding of theory of relativity.
The idea of space-time curvature likewise had its origin in mathematics. When seeking a mathematical approach that could embody his Principle of Equivalence, Einstein was led to the formulas of Riemannian geometry. And indeed, these formulas define four-dimensional curvature, for individuals who are able to imagine it. You see, mathematicians are not confined by physical constraints; equations that have a physical definition in 3 dimensions can possibly be generalized algebraically to any variety of dimensions. But when you do this, you are truly handling algebra (equations), not geometry (spatial configurations).
By expanding our minds, several of us are able to even make a faint mental image of what four-dimensional curvature might be like if it did exist. Nevertheless, claiming that the gravitational field equations are equal to curvature is definitely not the same as stating that there is curvature. In Quantum Field Theory, the gravitational field is just another force field, like the EM, strong and weak fields, though with a higher complication which is demonstrated in its higher spin value of 2.
While QFT resolves these paradoxical declarations, I really don't wish to leave you having the thought that the theory of quantum gravity is problem-free. While computational issues concerning the EM field were overcome with process referred to as renormalization, comparable challenges involving the quantum gravitational field have not been conquered. Fortunately they do not interfere with macroscopic computations, for which the QFT formulas become the same to Einstein's.
Your choice. Once again you the reader have an option, as you did in concern to the two methods to special relativity. The option is not about the formulas, it has to do with their perception. Einstein's equations can be deciphered as suggesting a curvature of space-time, unpicturable as it may be, or as detailing a quantum field in three-dimensional space, just like the other quantum force fields. To the physicist, it actually doesn't make much difference. Physicists are far more concerned with solving their formulas rather than with analyzing them. If you will permit me another Weinberg quote:
The important thing is to be able to make predictions about images on the astronomers photographic plates, frequencies of spectral lines, and so on, and it simply doesn't matter whether we ascribe these predictions to the physical effects of gravitational fields on the motion of planets and photons or to a curvature of space and time. (The reader should be warned that these views are heterodox and would meet with objections from many general relativists.)-- Steven Weinberg
Therefore in case you prefer, you can believe that gravitational effects are due to a curvature of space-time (despite the fact that you can't visualize it). Or, like Weinberg (and me), you can view gravity as a force field that, similar to the other force fields in Quantum Field Theory, exists in three-dimensional space and progresses in time according to the field equations.
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