# Is General Relativity A Quantum Mechanics

## Is general relativity a quantum mechanics?

Now for the problem: relativity and quantum mechanics are fundamentally different theories that have different formulations. It is not just a matter of scientific terminology; it is a clash of genuinely incompatible descriptions of reality.

## What’s the main difference between relativity and quantum physics?

Relativity considers objects as indivisible masses in space-time, while Quantum Mechanics views matter as probability waves rather than localized particles. Relativity predicts definite outcomes, but Quantum Mechanics provides only probabilities.

## Is general relativity harder than quantum field theory?

Quantum field theory is harder to learn than general relativity. General relativity has all conventional mathematics as prerequisites : linear algebra, tensor calculus, differential geometry, partial differential equations, etc.

## Does quantum mechanics agree with special relativity?

QM and special relativity are independent subjects. If you want to learn Quantum Field Theory (QFT), on the other hand, which is way more complicated than QM, you will need a strong foundation in both QM and special relativity.

## Is Einstein the father of quantum mechanics?

Niels Bohr and Max Planck, two of the founding fathers of Quantum Theory, each received a Nobel Prize in Physics for their work on quanta. Einstein is considered the third founder of Quantum Theory because he described light as quanta in his theory of the Photoelectric Effect, for which he won the 1921 Nobel Prize.

## Did Einstein work on quantum mechanics?

Einstein actually helped create quantum theory with his description of the photoelectric effect, in which particles of light can drive electric currents. (Thanks to the work of James Clerk Maxwell, light was considered at the time as exclusively a wave phenomenon.)

## Does quantum mechanics disprove general relativity?

Quantum mechanics is incompatible with general relativity because in quantum field theory, forces act locally through the exchange of well-defined quanta.

## What is the opposite of quantum physics?

And since it does not contradict the results of any theory it does not have an antonym. Note:Classical physics is a good approximation of quantum physics for the set of phenomena that we observe. It is just that we are not used to the ideas of quantum physics.

## Who invented quantum mechanics?

These early attempts to understand microscopic phenomena, now known as the old quantum theory, led to the full development of quantum mechanics in the mid-1920s by Niels Bohr, Erwin SchrÃ¶dinger, Werner Heisenberg, Max Born, Paul Dirac and others.

## Does gravity exist at the quantum level?

There are a number of proposed quantum gravity theories. Currently, there is still no complete and consistent quantum theory of gravity, and the candidate models still need to overcome major formal and conceptual problems.

## Which is the most difficult theory in physics?

Quantum mechanics is deemed the hardest part of physics.

## What is more difficult than quantum mechanics?

General Relativity is more mathematically difficult than non-relativistic quantum mechanics (which is what most people mean when they say quantum mechanics).

## Why doesnt general relativity work with quantum mechanics?

Quantum theory does not provide a natural time parameter and the quantum constraints of general relativity do not contain any time parameter. For this reason, standard quantum mechanics needs to be generalized to accommodate quantum spacetime, very probably without a Hilbert space.

## What type of physics is general relativity?

General relativity is a metric theory of gravitation. At its core are Einstein’s equations, which describe the relation between the geometry of a four-dimensional pseudo-Riemannian manifold representing spacetime, and the energyâ€“momentum contained in that spacetime.

## What field of physics is general relativity?

General relativity has developed into an essential tool in modern astrophysics. It provides the foundation for the current understanding of black holes, regions of space where the gravitational effect is strong enough that even light cannot escape.