Why should it?SEYED2001 said:Should a theory of everything be deterministic to be a theory of everything?
Maybe because it must predict everything to be a theory for them? That's what theories do, to predict don't they?PeroK said:Why should it?
Maybe they predict probabilities.SEYED2001 said:Maybe because it must predict everything to be a theory for them? That's what theories do, to predict don't they?
Great. I see what you mean. If probabilities are the only things out there then a theory of everything is a theory for no more than probabilities. Thanks.PeroK said:Maybe they predict probabilities.
Thank you for your reply. Is any relation between the existence of hidden variables and existence of a theory of everything ever established?atyy said:A classical heuristic is that there is no fundamental difference between deterministic and probabilistic theories, in the sense that one could see the most fundamental theory as deterministic, with the probabilistic theories arising due to our inability to fully know the state of all variables in the fundamental deterministic theory. The variables whose state one does not know can be considered "hidden variables" of the probabilistic theory.
It is unclear at the moment whether hidden variables can be constructed for quantum theory. Bohmian mechanics is one well known proposal for hidden variables for non-relativistic quantum mechanics. It is not well understood whether hidden variable theories can be constructed for other types of quantum theory.
I asked this since I think I can establish one and so wondering if is worth spending time on.SEYED2001 said:Thank you for your reply. Is any relation between the existence of hidden variables and existence of a theory of everything ever established?
SEYED2001 said:Thank you for your reply. Is any relation between the existence of hidden variables and existence of a theory of everything ever established?
Thank you!atyy said:Usually, by a theory of everything, we mean a quantum theory of everything. Whether a quantum theory of everything is possible is a matter of research. String theory is a research area that attempts to construct a quantum theory of everything.
Deterministic hidden variables are usually discussed with respect to attempts to solve the "measurement problem" present in all quantum theories (including string theory, if it were to succeed). A good description of the "measurement problem" of quantum theory is John Bell's article Against 'measurement'.
Here you can reason from the opposite and refer to the next example. Suppose we have a theory of everything that describes the dynamics of a vector field on an infinite cylinder. Moreover, the dynamic laws of motion of the singularities of the vector field (prototypes of particles) are both deterministic, since they follow from some integral variational equation, and probabilistic, since the free motions of the singularities are arbitrary in the choice of speed and direction. Now imagine that the feature of the vector field, which serves as the prototype of the particle, is the streamline of the vector field, outlining the defining circle on the cylinder, and the observer can only see the linear coordinate of the cylinder (straight or helical line). Now what can we say about the dynamic behavior of "particles" on the line of the observer, is it deterministic or not?SEYED2001 said:I am aware that QM isn't deterministic. Should a theory of everything be deterministic to be a theory of everything, and if yes, then how can it be when QM as a part of it is not deterministic?
Similarly, the most fundamental theory may be probabilistic, and deterministic theories may appear on the large scale for averages.atyy said:A classical heuristic is that there is no fundamental difference between deterministic and probabilistic theories, in the sense that one could see the most fundamental theory as deterministic, with the probabilistic theories arising due to our inability to fully know the state of all variables in the fundamental deterministic theory. The variables whose state one does not know can be considered "hidden variables" of the probabilistic theory.
No, that's clear. De Broglie-Bohm theory works for relativistic field theory too. The classical reference for this is Bohm.D., Hiley, B.J., Kaloyerou, P.N. (1987). An ontological basis for the quantum theory, Phys. Reports 144(6), 321-375atyy said:It is unclear at the moment whether hidden variables can be constructed for quantum theory. Bohmian mechanics is one well known proposal for hidden variables for non-relativistic quantum mechanics. It is not well understood whether hidden variable theories can be constructed for other types of quantum theory.
1. The theory of everything does not necessarily need to be deterministic.SEYED2001 said:I am aware that QM isn't deterministic. Should a theory of everything be deterministic to be a theory of everything, and if yes, then how can it be when QM as a part of it is not deterministic?
Yes. A hint is given in Sec. 4.3 of http://de.arxiv.org/abs/1703.08341 and the idea is further elaborated in http://de.arxiv.org/abs/1811.11643 .SEYED2001 said:Is any relation between the existence of hidden variables and existence of a theory of everything ever established?
It's quite clear to me that Bohmian mechanics works for relativistic QFT as well. See e.g. my non-technical lecture http://thphys.irb.hr/wiki/main/images/3/3d/QFound5.pdfatyy said:It is unclear at the moment whether hidden variables can be constructed for quantum theory. Bohmian mechanics is one well known proposal for hidden variables for non-relativistic quantum mechanics. It is not well understood whether hidden variable theories can be constructed for other types of quantum theory.
And why is that necessarily a bad thing?SEYED2001 said:... a theory of everything is a theory for no more than probabilities. Thanks.
For a similar approach see also myMorbert said:As an aside: This is certainly outside my comfort zone, but this paper[1] discusses QFT without the insistence that we must be able to define a quantum state evolving unitarily through spacelike surfaces (which, sans some fancy theory like string theory, runs into problems if there is a topology change induced e.g. by a black hole). Hartle seems to be happy to drop that condition, and compute amplitudes via a sum-over-histories approach (see eq 4.2). He argues that even though information might appear lost on specific spacetime surfaces, it is still present throughout spacetime.
I.e. A unitarily evolving quantum state is desirable even if a probabilistic interpretation is adopted. But even this might not be necessary, or at least not enforced by the formalism.
There might be a million things wrong with this, or it might just be a project that has generated little scientific interest (only 8 citations)
[1] https://arxiv.org/abs/gr-qc/9808070
No, the Theory of Everything is still a theoretical concept and has not been proven to be true. It is a proposed framework that aims to explain all physical phenomena in the universe, including the laws of nature. Whether or not it is deterministic is still a topic of debate and has not been definitively answered.
Determinism is the philosophical concept that all events, including human actions, are ultimately determined by causes external to the will. In the context of the Theory of Everything, determinism refers to the idea that the laws of nature are fixed and predetermined, and that everything in the universe can be explained by these laws.
Yes, there are some arguments against the Theory of Everything being deterministic. Some scientists and philosophers argue that the uncertainty principle in quantum mechanics suggests that the behavior of particles is not completely predictable, making determinism impossible. Others argue that human consciousness and free will cannot be explained by deterministic laws.
If the Theory of Everything were proven to be deterministic, it would mean that every event in the universe, including human actions, is predetermined and can be explained by the laws of nature. This could have significant implications for our understanding of causality, free will, and the nature of reality.
It is currently impossible to definitively prove whether or not the Theory of Everything is deterministic. As our understanding of the universe and its laws continues to evolve, it is possible that new evidence or theories may shed light on this question. However, it may ultimately remain a philosophical and theoretical debate rather than a proven fact.