There is a way do derive Hilbert space from scratch simply by imposing six axioms on the set of yes and no questions you can ask. This is the program of Von Neumann, later developped by the Brussels-Geneva group; so, one can derive these structures from very elementary (but sometimes wrong) considerations.Hurkyl said:The question "What is a Hilbert space physically?" really doesn't make sense -- what you are really asking is "What sort of physical thing can be described via Hilbert spaces?" Learning some answers to that question is the whole point of the class you're taking.
Careful said:
http://www.vub.ac.be/CLEA/aerts/publications/2004QuoVadisQM.pdf and references therein. The author is aware that standard QM falls short and tries to find more general axioms than those which merely derive QM and classical physics.micromass said:
Assuming that Careful is talking about quantum logic, the basic idea is to look for a mathematical structure that can represent the set of "experimentally verifiable statements" (e.g. "if I measure the energy, the result will be in the interval [a,b]"). What they end up with is a lattice that's isomorphic to the lattice of closed subspaces of a complex separable Hilbert space. So from a physicist's point of view, you might as well start right there. But you don't have to mention Hilbert spaces right away. You can start with an abstractly defined lattice, and specify its properties.micromass said:
Careful said:
I actually considered doing my PhD with him. His research area is very interesting...micromass said:
Ah, I know him quite (''very'') well personally. But as far as I know, nobody in Antwerp is doing something even close to this. What are you playing then with? Path integrals ? ...micromass said:Ah, Dirk Aerts
I studied at the VUB. But now I'm doing my PhD in Antwerp. But next year I'll probably go back to the VUB...
Yes, it is much more ambitious. Actually what he first discusses is a framework which originated by Piron in which as well classical as quantum physics is retrieved. But still this is not enough and (I discussed this with the author) in my opinion at least 4 out of 6 axioms are false while he only discussed two of them (at that time !).Fredrik said:
Careful said:
from a mathematical point of view of course...I don't know any string theorist in Antwerp... I am aware Lieven Lebruyn and Fred Van Ostayen have some tangential interests in these things, but that is at the mathematics departement. Actually, since you are mathematically inclined you might be interested in the draft of my book http://arxiv.org/abs/1101.5113 which I spoke about with Dirk (and the concrete quantum theory I develop suggests a logic in the generalized framework he is looking for, but we are not quite there yet).micromass said:Well, due to circumstances, I was involved in something completely different then I was wanting to do. Right now I'm playing with string theory and mirror symmetry
In that case, I'm a little confused. If at least 4/6 of the axioms are false (which I assume means that theories of physics based on them will make predictions that disagree with experiments), should we even bother to read the article?Careful said:
Careful said:
You don't understand. The axioms which are written there give standard QM + classical mechanics. But the author is smart enough to realize that standard QM doesn't work well enough and he has written dozens of papers about these ''failing axioms'' since the 1970 ties with amongst others Ingrid Daubechies (the president of the international mathematical society). Furthermore your reasoning is not very ''sophisticated'', saying that an assumption fails does not imply you get in contradiction to experiment !Fredrik said:
Ah so you are with Fred ? Well I had the luck to study mathematical physics first and then relativity and QFT in my PhD time. I did not suffer from the pressure to do strings ... but I guess you get a fairly unique perspective upon the matter in this way. I thought Antwerp had connections with IHES in Paris where Connes is doing his stuff.micromass said:Well, I am a mathematician, so I study at the math department. I don't study string theorists like the physicists, but I rather try to approach it from a mathematical point of view. It is rather hard, since I don't know much about physics
What?Careful said:
Then what did you mean when you said that the axioms are false? Mathematical axioms are always a part of a definition of something, and in this case, without having read the article, I can only assume that what's being defined is either a theory of physics or a mathematical structure that the authors would like to use in a theory of physics. The only problems that a bad choice of axioms can cause are logical inconsistencies or disagreement with experiments.With false we (Diederik, I and probably Ingrid too) mean that the logical structure of a theory which involves as well QM as relativity is going to be based on axioms which subtly contradict those in the paper and slightly extend them as well. This means we move away from Hilbert space; Piron's primary concern was to find axioms which would retrieve a slight extension of real, complex and quaternionic quantum mechanics.Fredrik said:What?
I don't doubt that the authors are smart guys. I skimmed one of those Aerts & Daubechies articles last year (the one that justifies the use of tensor product spaces in QM), and it looked very solid.
Hilbert Space is a mathematical concept that refers to a complete, infinite-dimensional vector space. It is named after the German mathematician David Hilbert and is used in many areas of mathematics, including quantum mechanics and functional analysis.
Hilbert Space is used in physics to describe the state of a quantum mechanical system. It provides a mathematical framework for representing the physical properties of particles and their interactions. It also allows for the calculation of probabilities and predictions of future states of a system.
One example of the use of Hilbert Space in physics is in the Schrödinger equation, which describes the time evolution of a quantum system. The equation is solved within Hilbert Space to determine the wave function, which represents the state of the system at any given time.
Hilbert Space is different from Euclidean Space in that it is infinite-dimensional, whereas Euclidean Space is finite-dimensional. This means that while Euclidean Space can be visualized in three dimensions, Hilbert Space cannot be fully visualized, and its dimensions are represented by mathematical objects.
While it is not strictly necessary to understand Hilbert Space to study physics, it provides a useful mathematical framework for understanding quantum mechanics and other areas of physics. Many concepts in physics, such as wave functions and operators, are best understood and described within Hilbert Space.