QM derived or axiomatic ?

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The hope is that the theory would be derivable from more fundamental, as yet unrecognized, principles. In summary, the conversation discusses the claim that modern quantum mechanics is not derived from fundamental concepts but rather put forth in axiomatic form. Some participants agree with this idea and believe that the axioms are the same as fundamental concepts, while others argue that there may be even more fundamental principles yet to be discovered. The conversation also touches on the idea of quantum logic and its potential for providing a logical underpinning for quantum mechanics. Overall, the participants are interested in the possibility of finding a deeper understanding of quantum
  • #1
Rade
In another thread on the forum, a member (Doctordick) made the following statement:

...What you should take note of is the fact that modern quantum mechanics, as seen by the academy (the religious authority of modern physics) is not derived from fundamental concepts; but is rather put forth in axiomatic form and that derivation of the relationships from more fundamental analysis is really of no interest to them...

I am interested in knowing if this is in fact the modern view of those that work in quantum mechanics.
 
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  • #2
Rade said:
modern quantum mechanics... ...is not derived from fundamental concepts; but is rather put forth in axiomatic form

That sounds a strange claim. Aren't these axioms the same thing as the fundamental concepts? If they have different meaning, perhaps their meaning should be explained in more detail then by the one who is claiming this.

I my opinion the idea that we have some coordinate set [itex]\{q\}[/itex], whose members represent some classical states, and the wave mapping [itex]\Psi(t,q):\mathbb{R}\times\{q\}\to\mathbb{C}[/itex], whose time evolution is defined from a classical action by

[tex]
\Psi(t+T,q) = \textrm{sum}_{q'} e^{iS(q'\to q)/\hbar} \Psi(t,q') + O(T^2)
[/tex]

is the most fundamental idea behind the quantum mechanics. Or I mean, the most fundamental that I have encountered so far. I agree with the original claim to the extent that this is often not emphasized in the education of QM. Usually people are interested to know about QM precisely what is needed to know so that we could calculate stuff.

Now when I actually took a glance on the Doctordick's posts, I think this has nothing to do with his ideas. I'll put it this way: "Physicists are usually not interested in philosophy, they are interested in calculating." That is something that many will probably agree with, and if Doctordick is criticizing it, it is understandable, although I'm not convinced that he himself would be improving anything.
 
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  • #3
jostpuur said:
That sounds a strange claim. Aren't these axioms the same thing as the fundamental concepts? If they have different meaning, perhaps their meaning should be explained in more detail then by the one who is claiming this.

No! In fact, for example the axiom that says the we can make a substitution

[tex]
\boldsymbol{p} \mapsto -i\hbar\nabla
[/tex]

is way too abstract to be considered something fundamental. So on this matter I agree fully with Doctordick.

Rade, as you can see, now I'm already too much guessing what Doctordick has meant with this, and it results my responses getting confusing. Now I'll shut up, and continue only when the original claims have been made clearer.
 
  • #4
Rade said:
...the religious authority of modern physics...really of no interest to them...

This sounds a bit overly angry. Quantum Mechanics was originally worked out (derived?) to be self-consistent, to agree with Classical Mechanics, and to produce correct results. Once the rules were established they could be applied without thinking about where they came from. But every physicist I know is interested in the possibility that QM and other aspects of modern physics might be derivable from more fundamental, as yet unrecognized, principles.
 
  • #5
jostpuur said:
No! In fact, for example the axiom that says the we can make a substitution

[tex]
\boldsymbol{p} \mapsto -i\hbar\nabla
[/tex]

is way too abstract to be considered something fundamental. So on this matter I agree fully with Doctordick.
Well, what do you mean by "fundamental"? If you mean those things that provide a starting point for further study -- e.g. axioms -- then being fundamental is not an inherent property of anything; it depends on your choice of presentation.

I'm not sure upon what grounds you label this particular statement as "abstract"; it's an explicit, constructive definition of the momentum operator! You can't get much more concrete than that. :tongue: While I certainly agree that there is merit to defining the momentum operator in terms of a list of properties that it should have, you run the risk of losing some of your audience if they have to do a lot of theoretical work before they can actually compute anything.
 
  • #6
Rade said:
...What you should take note of is the fact that modern quantum mechanics, as seen by the academy (the religious authority of modern physics) is not derived from fundamental concepts; but is rather put forth in axiomatic form and that derivation of the relationships from more fundamental analysis is really of no interest to them...

Please note that all physics is put in axiomatic form. Those principles are the fundamental concepts because we could analyze any phenomena just starting from it.
If you are thinking at something specific as "fundamental", explain what is.

Ll.
 
  • #7
The operator approach is intended to give humans tools to calculate. Perhaps it is fundamental in such mathematical sense. The path integral approach instead looks like fundamental in a sense, that nature could be working by some principles very similar to these path integrals.

At least my instinct tells me so.
 
  • #8
country boy said:
But every physicist I know is interested in the possibility that QM and other aspects of modern physics might be derivable from more fundamental, as yet unrecognized, principles.

Google for "quantum logic", "Mackey axioms", "Piron theorem" and you will find a beautiful axiomatic approach from which all Rules of Quantum Mechanics would follow, including the rule [itex] \mathbf{p} \to -i \hbar \nabla [/itex]

Eugene.
 
  • #9
meopemuk said:
Google for "quantum logic", "Mackey axioms", "Piron theorem" and you will find a beautiful axiomatic approach from which all Rules of Quantum Mechanics would follow, including the rule [itex] \mathbf{p} \to -i \hbar \nabla [/itex]

Eugene.

Thanks for the Google directions. Mackey's ideas are certainly valid and have apparently led to a search for the logical underpinning of QM. If the fundamental principles were discovered, however, it would be nice if they produced an understanding beyond just explaining QM. Something that included gravity, for instance, and maybe things we hadn't even thought about.
 
  • #10
country boy said:
Thanks for the Google directions. Mackey's ideas are certainly valid and have apparently led to a search for the logical underpinning of QM. If the fundamental principles were discovered, however, it would be nice if they produced an understanding beyond just explaining QM. Something that included gravity, for instance, and maybe things we hadn't even thought about.


As far as I know, Birkhoff - von Neumann - Mackey - Piron quantum logic didn't lead to any deeper insights. It simply provided a transparent and simple axiomatic foundation for the laws of quantum mechanics. This is a major thing, by itself!

It is very important to know that quantum mechanics lies on a very solid foundation, and if one decided to modify QM rules one should be aware that he would violate some fundamental rules of logic when doing that. For example, there are numerous proposals (e.g., Penrose) to change QM rules to make them "compatible" with general relativity. Quantum logic is a big roadblock on this path.

Eugene.
 
  • #11
country boy said:
If the fundamental principles were discovered, however, it would be nice if they produced an understanding beyond just explaining QM. Something that included gravity, for instance, and maybe things we hadn't even thought about.

I agree with this.

My major incentive to find a better line of reasoning behind QM, is so that the methodology can be more readily extrapolate to the new, harder, more general problems in reality.

If you do not have the next step in mind, the driving measure will be different. To rethink a working model, just for the fun of it, with no intention that this rethinking can provide a better stance is not my motivation.

Learning how to apply and do calculations, is not the same as finding a deeper understanding that give you a more fit stance to attack the unknown, and maybe even extend the theory to more general cases and do away with idealizations.

My impression is that different peoples views often boils down to different views of realism, and different views of the "scientific method". The way I was presented quantum mechanics at the university when I took those course was certainly enough to teach me a tool, but they didn't convince me with their handwaving argumentaion. It's clearly a lot of guessing and ad hoc reasoning, that is, formalized by axiomatising, and ultimately justified by noting that no matter how we arrived at this, it seems to work. But there are still fuzzy ends all over the place IMO.

/Fredrik
 
  • #12
Fra said:
and ultimately justified by noting that no matter how we arrived at this, it seems to work.
Of course! That's essentially the definition of science: the ultimate arbiter of truth is empirical evidence. Pure reason, no matter how clever, cannot justify a scientific theory.
 
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  • #13
Hurkyl said:
Of course! That's essentially the definition of science: the ultimate arbiter of truth is empirical evidence. Pure reason, no matter how clever, cannot justify a scientific theory.

That seems to suggest that at some level reality (i.e. QM) is not reasonable. I think that the basic premise of the scientific method is that everything is reasonable at EVERY level of existence. We just have to find out how it all stands to reason.

Whatever our theories about reality might be, they ultimately end up making statements about reality that we either decide are true or false. Therefore, the algebra of true and false, namely propositional logic, is relavant at every level of existence.

If science is only based on the contingencies of what we can measure, then we will always be asking how those contingencies are possible. Questions about reality will not end until we can show that existence is derivable from pure reason. The questions will stop when we answer that it is required by reason.
 
  • #14
Rade said:
In another thread on the forum, a member (Doctordick) made the following statement:

...What you should take note of is the fact that modern quantum mechanics, as seen by the academy (the religious authority of modern physics) is not derived from fundamental concepts; but is rather put forth in axiomatic form and that derivation of the relationships from more fundamental analysis is really of no interest to them...

It is not clear what you/ Doctordick/ jostpuur/ country boy/ Hurkyl/ Llewlyn/ meopemuk/ Fra/ Mike2 mean using term axiomatic. As usual each one tries to fit it according to his personal knowledge/understanding/experience/purpose. For example, one well known physicist wrote:

“Our streams of thought are constantly stimulated and redirected by interactions with the external world, and by internal drives, in ways that don’t seem to resemble at all the unfolding of mathematical algorithms.

Another argument derives from our experience with modern digital computers. For these are, in a sense, ideal mathematicians. They follow precise rules (axioms) with relentlessness, speed, and freedom from error that far surpasses what is possible for humans.”

No doubt that the axioms are the precise rules. However, I consider them as constraints that allow any structure that do not contradict these constraints.

So, the point is what we agree to use as a standard reference?

I suggest: J.S.Hadamard “Elementary Geometry” (Lecons de Geometrie Elementaire).

Regards, Dany.

P.S. By the way my quotation was selective and manipulative. The writer finally stated the opposite.
 
  • #15
Anonym said:
It is not clear what you/ Doctordick/ jostpuur/ country boy/ Hurkyl/ Llewlyn/ meopemuk/ Fra/ Mike2 mean using term axiomatic. As usual each one tries to fit it according to his personal knowledge/understanding/experience/purpose. ...

Thank you for clarifying/elucidating/defining/explaining the meaning of axiomatic/fundamental/basic/essential.:smile:

This is getting to be more of a philosophical thread, but here's one more thought. Scientific understanding involves an interplay between evidence and context (experiment and theory). A fact has no meaning without a framework that attempts to link it with other facts. Theory has no validity if it doesn't fit the evidence. Experiment drives theory and theory drives experiment. They develop together.

In the end, however, evidence is the arbiter. If the experimental result is valid and the theory is not consistent with it, then the theory must be changed. We are allowed to discard theory, but not experiment.
 
  • #16
country boy said:
Thank you for clarifying/elucidating/defining/explaining the meaning of axiomatic/fundamental/basic/essential.:smile:.

If you treat my post so, I was not successful. I do not consider fundamental /basic/ essential close synonyms of axioms.

country boy said:
This is getting to be more of a philosophical thread.

Then why discussion should be in QP of PF?
And you aren’t tired of philosophy?

Regards, Dany.
 
  • #17
Hurkyl said:
Of course! That's essentially the definition of science: the ultimate arbiter of truth is empirical evidence. Pure reason, no matter how clever, cannot justify a scientific theory.

I don't suggest that "pure reason" can replace real interactions and real observations.

However, human reason is bound to be a physical process, and can be thought of as self observation/interaction, and my self-interaction we can increase the effiency in our scientific method by improving it, and thus giving us better theories in shorter time. After all the human brain is one of the more fascinating information processing structures in nature IMO, so I still wouldn't underestimate reason, because it is in an indirect sense also "observations".

My own subjective conclusion has drawn my attention to the method itself, and the dynamics of evolving theories, and how this is related to the communication between observer and environment.

From this viewpoint, there is a lot to wish from most standard formulations. The lacking part is the line of reasoning that you'd expect if a more intelligent evolutionary strategy was used. Still, everything may have started with "random" trials, but I think it's sooner or later time for a review of our methods, for the benefit of increased fitness. This is my vision at least.

/Fredrik
 
  • #18
Dany, I know I come out as fuzzy and philosophical, and I don't get tired of philosophy, but I often get tired of "talking about it" because there is rarely any progress. These things are often best solved by self-communication.

Those who think that physics is _just_ math, is from another school of thinking than me, so I can't comment on what they are doing. To me I try to understand reality. Not mathematical models. In this quest mathematics is a significant and almsot dominating component but it's not, IMO, the only component. It also contains really fuzzy problems, that requires fuzzy thinking at times. That's my experience at least.

/Fredrik
 
  • #19
To anyone who has responded to this thread I started--if you have any interest in dialog with Doctordick about his comment that I presented in the OP--please see and respond at the end of this thread link (post #480):

https://www.physicsforums.com/showthread.php?p=1389412#post1389412


My motivation here is to link professional physicists/mathematicians with out-of-box and very creative philosophic ideas being presented by Doctordick.

As he often closes, have fun.
 
  • #20
Anonym said:
Then why discussion should be in QP of PF?
And you aren’t tired of philosophy?

Whoops!, I picked this thread up on the QP Forum and didn't notice that it had been moved.

Philosophy is fine, but it is best when it leads to a practical outcome. In this case, we should hope that there is a way to deal with axiomatic physical theory, but still be able to look beyond the axioms for more fundamental principles. The method for doing this probably can't be procedural, since that would be too confining. But are there at least guidelines that help us make progress past prevailing understanding?
 
  • #21
country boy said:
Philosophy is fine, but it is best when it leads to a practical outcome.

I agree. But I don't see why there shouldn't be an outcome, blame the incompetent philosopher, not philosophy.

I'll speak formyself and my current guidelines is to make a comparasion between

a) physical interactions where particles update their states until they reach equilibrium with their environment, and then the residual uncertainty is chaotic or random and

b) physicists interaction with reality where they update their theories until they reach an understand, and the residual uncertainty are what we think of as unresolvable.

This leads to a subjective probability view and a learning logic. I find this way of thinking to provide me with plenty of guidelines.

I think, as does the others thinkning along these lines that a fundamental understanding is to be found at information level. The reason for thinking so is that the very scientific method can be thought of as information processing. Science progresses, but processing data acquired from real interactions. If you believe in this ideas, you also expect a coherent line of reasoning explaining the process. And the fundamental conclusion I am tempted to make is that the _process of induction_ is more fundamental than the result. Because the result is always in motion, changing.

This is of course plain baloney and nonsense if you ask someone who refuse to make philosophical reflections. It's useless and does nto have any relevance to anything. But if you asks for suggestions and guidelines that might _lead_ to an answer this is my comment.

/Fredrik
 
  • #22
Fra said:
Dany, I know I come out as fuzzy and philosophical, and I don't get tired of philosophy, but I often get tired of "talking about it" because there is rarely any progress. These things are often best solved by self-communication.

Fredrik, sorry. I can’t continue. I do not understand a single word neither yours, nor the others. You use undefined for me notions.

Regards, Dany.
 
  • #23
Dany, I understand. I've seen some of your posts and you seem pretty knowledgeable, but we seem to think differently indeed. But I think that is also matter of personality. I am admittedly on the philosophical side of things, I don't think in numbers, I think in abstract therms, and sometimes saying it in plain english seems easier, but only if the received is on the same page to start with. But even from someone as "vague" as me, the goal IS a proper mathematical theory because that's the only thing that can qualify for quantitative predictions, so don't get me wrong. I see no contradiction in that we may still agree on any final effective theories. All the talking is just about exchanging ideas IMO.

/Fredrik
 
  • #24
The kind of "guidelines" I'm talking about are like:

1) Is there a drastically simpler picture that explains most of the phenomena? (Sun -centered solar system)
2) Is there a way to explain a variety of seemingly unrelated phenomena with the same rules? (universal gravity)
3) Can two separate theories that have to be used side-by-side be replaced by a single theory? (electricity and magnetism, electro-weak theory, hopefully quantum gravity)
4) Can an unexplained experimental result be taken as axiomatic in developing a new theory? (relativity)

The are lots of these, I'm sure.
 
  • #25
The mathematics of Quantum Mechanics have a comprehensible derivation from EM theory. Furthermore, Quantum Mechanics makes some of the most accurate predictions in all of science. The error bar is analogous to being able to measure the width of North America with the error bar of the width of a strain of hair (Feynman).
 
  • #26
I hear what you are saying countryboy, and that's exactly what I have in mind. Of course, I may be wrong, but more importantly if I'm right, it would anyhow be hard to convey the ideas until it's completed. I tried, but I don't know if I make myself understood.

Put abstractly, I picture all physical interactions as information processing. The guide is then to look at the mathematical tools for information processing. A particle beeing hit by another particle, have no choice but to respond to the impact. I am trying to understand, on general basis, how such responses look like. In this treatise, you are lead into memory concepts, and this bears interesting similarities to mass, as in a processing mechanics memory means intertia. So the mass/energy concept may have a deep interpretation in this view.

There is one guy, Ariel Caticha, who is trying to deduce general relativity from general principles of inference complemented with a principle of maxium entropy. I think he has not yet succeeded, and I think the issue is even more complex. But look up his paper (or click here: http://arxiv.org/abs/gr-qc/0301061), and you can at least get some "ideas". His reasoning is honest, with minimum ad hoc stuff.

However, wether you like this approach or not, depends on where you come from and your prior ideas. Another thing coming from this ideas, is that one can suggest a universal measure, that could probably (ultimately) solve part of the problem of all the parameters in the standard model. This universal mesaure can also (I think - to be proved) from a profound way explain unification of space and time... there is a connection, that probably leads to relativisitc concepts by consistency.

/Fredrik
 
  • #27
Another way of putting it (my intuition, philosophy or whatever ou call iy - to be proved) is that there is a generalisation of the action principle which can be given a more proper foundation. Some of the classical stuff is a bit handwaving, but this too can be understood I think from a information theoretic view, in terms of generalized information divergences + some other stuff, operating on generalized specially deviced probability spaces. To each probability distribution is assigned something like a "mass" term. All this leads to interesting dynamics. By hypothesis, the correct one. The ideas is simple, but the application gets more complex. I couldn't do it, without intuition as I would be lost.

/Fredrik
 
  • #28
country boy said:
Whoops! I picked this thread up on the QP Forum and didn't notice that it had been moved… If the fundamental principles were discovered, however, it would be nice if they produced an understanding beyond just explaining QM. Something that included gravity.

One of the “axiomatic/fundamental/basic/essential” axioms in physics is the cause effect relation (there exist the upper bound for the velocity of interaction propagation; Principal Physical Postulate). The whoops effect, mentioned by you, is the consequence of the statement:” This is getting to be more of a philosophical thread”, made by you.

I also consider the original question “QM derived or axiomatic?” physical and not philosophical. The answer is in my view yes and related to formulation of a complete set of the principal physical postulates. It is the result of last 200 years of the development of the field theory.

Comparison with the history of Geometry clearly demonstrates that the formulation of the complete set of the principal postulates not only prevented the further development of science but led to the enormous progress.

Our discussion here so far is one sided. The philosophy is a close satellite of the physics but isn’t the only one. We should use history as well. It is similar to our “R-process” and “U-process”. The analog of history in physics are the equations of motion.

country boy said:
1)Is there a drastically simpler picture that explains most of the phenomena? (Sun -centered solar system)
2)Is there a way to explain a variety of seemingly unrelated phenomena with the same rules?
3)Can two separate theories that have to be used side-by-side be replaced by a single theory? (electricity and magnetism, electro-weak theory, hopefully quantum gravity)

You missed it. There is self-obvious statement that fit all developments in physics. It is the idea that everything is made using the elementary building blocks, Elementary Particles. That statement has empirical justification starting from the Greeks or perhaps even from the Egyptians and the Indians. It perhaps even connected with the monotheistic form of religion. No doubt that it is the central statement in the Bible (be Resheet).

If so, how the enormous diversity and complexity of the real world may be explained? It is the enormous diversity and complexity of the corresponding faithful mathematical representation assures that.

country boy said:
4) Can an unexplained experimental result be taken as axiomatic in developing a new theory?

Yes, it is the standard development procedure.

Regards, Dany.
 
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What is QM derived or axiomatic?

QM derived or axiomatic refers to the approach of deriving the principles and laws of quantum mechanics from a set of axioms or fundamental principles. This approach is based on the idea that the fundamental laws of nature can be described by a small set of simple and self-evident principles.

How does QM derived or axiomatic differ from other approaches to quantum mechanics?

QM derived or axiomatic differs from other approaches, such as the Copenhagen interpretation, in that it does not rely on additional assumptions or interpretations of quantum mechanics. Instead, it aims to derive the laws of quantum mechanics directly from a set of fundamental principles.

What are some of the key axioms of QM derived or axiomatic?

Some of the key axioms of QM derived or axiomatic include the superposition principle, the uncertainty principle, and the principle of quantum entanglement. These axioms serve as the building blocks for the mathematical framework of quantum mechanics.

What are the benefits of using QM derived or axiomatic?

One of the main benefits of using QM derived or axiomatic is that it provides a clear and concise framework for understanding the laws of quantum mechanics. It also allows for a deeper understanding of the fundamental principles underlying quantum phenomena.

Are there any challenges associated with QM derived or axiomatic?

One of the main challenges of QM derived or axiomatic is that it can be difficult to reconcile with experimental results. This is because the axioms may not always provide a complete description of all quantum phenomena, and additional assumptions or interpretations may be needed to fully explain the results of experiments.

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