On the Depth of Quantum Space by Daniele Oriti

Dear Daniele ,

A very clearly written account of an interesting topic. You set out what you would be considering and the proceeded to do so in a way that smoothly carries the reader along. I did like the recurrence of the theme "it depends". You are so right it does depend. I came to the same conclusion at the end of my essay but you said it so much more clearly. The repetition not only tied the essay together but drove home how important that is. It is not a black or white question at all and the answer does depend in part on what is intended by the question when it is asked.

I do hope you get lots of interested readers who can give you feedback on the physics content. I think you did well to make this topic so accessible and educational to a non specialist and therefore enjoyable too.

Good luck, Georgina.

Dear Daniele

My essay http://www.fqxi.org/community/forum/topic/946

contain some terahedron"s logic idea.Do you see something common with your triangles?

All the best

Yuri

Hi Georgina,

thanks a lot for your kind words and appreciation. I will try to read as many a possible of the other essays submitted, and especially yours, and hope to have something interesting to say about it.

Thanks again.

D

Dear Daniele,

I don't know of any physicist anymore in these days who would say that atoms are discrete ; isn't the main lesson of relativity that even the number of atoms is not well defined (and that the notion of particle itself is contextual)? Likewise, nobody would argue that a gas is somehow discrete and a fluid continuous merely because we can give such effective descriptions. Fact is that QFT is defined on a continuum (I know very well some version of it can be constructed on causal sets) and the whole rationale behind it comes from causality, locality, statistics, cluster decomposition and Poincare invariance. You adress none of these issues, neither do you indicate what group field theory can contribute to the status of them. Second, your comparison with condensed matter models is misleading since these are all background dependent; nobody knows how to recover a manifold structure in a background independent way since it requires local observables. The problem here is that you cannot define these in a canonical way. Moreover, you adress none of the philosophical problems of quantum spacetime (which actually make the whole idea rather unlikely).

So, I hope that you will say that the limitations of the contest format prohibited you from treating all these issues and that you can explain how you see them.

Kind regards,

Johan Noldus

Dear Danielle,

While reading your essay , I became very aware that I am not a professional scientist, but I understood very well your point of vieuw, which is very clear as you mention it in the end "IT DEPENDS".

In my simple vieuw it means that what you wrote does not yet give you a clear "yes" or "no" on the question, this of course is very understandable because I think that none of us has a ready, steady go explication of the fundamental questions of our existance and our universe. I even think you are very courageaous to admit that "it depends".

I am enjoying very much every essay in this contest, it means that our minds are looking for explications, the many vieuws distributed are for me like a rainbow , all promising coulours above a dark landscape, very encouraging.

We need the scientists and the cosmologists , the quantum physicians, the historians and the philosophers to make progress in our understanding, the danger however is that anyone who is a specialist forgets to stay in contact with other specialismes.

You mention in your essay singularities, for myself I wonder if these "ideas" are not only existing in our minds,and not in the "material reality" we are living in, what in fact is a point with no dimensions ? The Planck scale , is the ultimate border of our perceptance, the singularities you mention are also part of this area where all measurements are impossible, once accepting that singulairities only exist in our minds they no longer are subject of formula's and so we encounter less infinities, for that I like to mention my own contribution to this wonderfull thought process :

fqxi.org/community/forum/topic/913,

of course I have to admit that the consequences of my thoughts DEPEND on the basic assumptions but if we have no assumptions or beliefs we don't have to prove anything isn't it ?

I wish you also good luck with the contest.

kind regards

Wilhelmus de Wilde

Danielle

Thank you for a very well written and comprehendable essay, exploring important territory in a clear and innovative way.

This has some interesting parallels with mine, which I hope you will be interested in reading to give you a different and very reality based perspective of the same territory (the string is also rich).

If you are able to increase the number of moving variables our brains can normally deal with I hope you might find it rewarding. I'd be interested in your response.

Very best of luck in the competition.

Peter

Dear Wilhelmus,

thanks for your kind comments.

Let me briefly reply on just one point about the intended meaning of my 'it depends'. It is not meant to simply state that ''we will never know for sure'', or that ''we do not know''. I agree with the latter of course, and not so much with the former statement. But it is not what I meant. What I meant is that the answer to the discrete/continuous question for quantum space can be possibly given exactly theoretically, and possibly even tested experimentally (being very speculative), but it will depend on the specific circumstances in which one poses it, in the same sense in which a similar question asked regarding a condensed matter system does. I gave some arguments for this view, offered some speculations, and pointed out that some recent work in quantum gravity has the potential to make the above a bit more precise. The position based on an 'it depends' of a different type, i.e. in which the precise conditions on which 'it depends' are not specified to some extent, would be at risk of being sterile.

Concerning singularities, indeed, several if not all practicing scientists believe the notion of singularity is but a label for a physical situation we do not understand yet, but not something physical in itself. However, the task is then to build up a theory of what happens in such situations, and unfortunately to simply deny their realities is not enough. We all have to be able to do better.

Thanks again and good luck to you as well!

Hi,

thanks for your kind words. Believe me, I would be indeed very happy if I was able to increase the number of variables my brain can deal with! :)

Best,

Daniele

Dear Johan,

thanks for you comments and interest, and sorry for the delay in my reply.

It is certainly true that the limitations of the essay format implied that I could not touch on all of the aspects of the problem that I would have like to, and that even those that I discussed could have been explained and treated in much more detail and more satisfactorily. However, it would not be honest to blame these limitations for any shortcoming of my essay. My own limitations in knowledge and expository skills are what I am more concerned with and what I, like everyone else, should try to improve on.

Let me try to clarify a bit more my thoughts on this matter by replying to your comments, which I am not sure I really understand though.

First, as a general comment on atoms, gas, fluids and condensed matter systems, I do not claim to have written anything original on any of this, in my essay. The parallel with atoms and condensed matter systems is indeed used only to exemplify, using familiar concepts, a certain picture of quantum space that cannot be as familiar, because of the more exotic nature of the subject, and the more limited comprehension of it we have.

So I agree with your comment that the limited, not absolute, purely effective nature of our description of atoms as discrete, of a gas as discrete or of a fluid as continuous is agreed upon by any physicist. Again, I am happy we agree on this because I was not trying to say anything original here. However, I also think that any physicist would agree that 'atoms are discrete' in the 'effective, limited' sense that there exists circumstances (e.g. relativistic effects should indeed by neglected to some extent) in which the physics of a system is well-described by a few discrete entities behaving like particles etc. Same for field theories around the Fock vacuum in flat space at low orders in perturbation theory etc. The fact that this effective description, valid in some circumstances, has to be replaced by another in which the same system is described by a continuous medium, for example, in other circumstances, is exactly the rationale behind my 'it depends' and, as I tried to explain, rests indeed on the characteristic properties of QFT.

Then you say something crucial: ''Fact is that QFT is defined on a continuum''. Indeed. This hints at the fact that it is this underlying continuum spacetime that one is considering as being 'fundamentally so' or, alternatively as 'fundamentally discrete' in nature, e.g. described by a causal set.

The main point of my essay is that one can 1) take the fundamentally discrete entities constituting spacetime at the quantum level in some approaches to quantum gravity (lattices, graphs, possibly also elements in a causal set, etc); 2) re-interpret them as 'particles', 'atoms' of space in analogy with the 'real' ones of condensed matter systems; 3) describe their dynamics in terms of a field theory that is not defined on any spacetime itself but rather on some internal, auxiliary, meta-space (call it as you like), the group manifold; 4) have as a result the same richness of different phases and effective descriptions (continuous, discrete etc) for spacetime that one has for condensed matter systems.

This means that the same limited validity of both the continuous and 'atomic' description of fields in QFT or of condensed matter systems will hold true for spacetime itself. Thus, the question of whether spacetime is discrete or continuous can only have answer 'it depends'. And the question whether it is either fundamentally one way or the other can only have answer 'no', because neither description would be fundamental, as you correctly say for atoms or gases or fluids.

To try to argue for the above point of view was the main goal of the essay.

You mention several important issues, related to the fundamental status of several features of QFT on flat space, like causality, locality, statistics, etc and ask whether GFT contributes to our understanding of them. For some of them it does, and I can only refer to the literature for all current work. The object of the essay, you would understand, could not be to address these issues. Certainly, GFT denies their validity at a more fundamental level, because they are very much tied to the background dependent description of ordinary QFT.

However, we are very far from being able to show how they emerge from a purely background independent description of space (e.g as the one of GFT). The theory is very incomplete, and indeed the main open problem, as far as I can tell, is to prove that a continuum description of spacetime and General Relativity (and thus special relativity) arises from GFT.

As you also say, nobody knows, at present, how to do this. However, I do not see why this inability should be mistaken for impossibility (either in principle or in practice) and thus invalidate the picture I tried to paint, beside the fact that obviously much more work is needed to validate it (and actually, also to refute it). Again, for all the current work on this issue, which I mentioned in the text, I refer to the literature (e.g. that on GFT renormalization, on the extraction of physics from spin foams, on the effective non-commutative field theories obtained as perturbations of GFT solutions, etc).

The comparison with condensed matter is indeed just an analogy, as I stressed in the text, possibly useful to guide us towards a better understanding of quantum space, but I agree it cannot be taken literally because our condensed matter theories are (as they should be, given that real condensed matter systems live in our labs) based on a fixed, flat spacetime.

Finally, I am well aware of the many philosophical issues raised by the very notion of quantum space, and of all those intertwined with every aspect of quantum gravity research (and even before that, with Genera Relativity and Quantum Mechanics themselves). However, first, I do not see how these issues (all currently and hotly debated among philosophers and physicists) make the 'whole idea' unlikely; second, to discuss these issues was not the scope of my essay, focused on a much more limited question and trying to achieve a a more limited goal: to present and argue for the general picture I outlined again above, in the hope that it could be stimulating and inspiring for further research of others as it is for mine.

Thanks again for you interest and comments and do not hesitate to put forward more of them or any specific doubt or question. I would be happy to discuss any such specific issue.

Best,

Daniele

Dear Daniele,

The problem of quantum gravity is to give a description of nature which is in principle valid on all scales (this is by no means in contradiction with renormalization). So your answer that it depends upon the scale or system is unfortunately not valid. You seem to take the point of view that the observer(s) are somehow living in ''meta space'' and that the theory should adapt to the ''glasses'' they are looking through. Of course, this is what you get when you naively combine quantum mechanics with general relativity which is what brings me to another point of yours where you say that you do not understand how these issues make the whole idea of ''quantum space'' unlikely. As I said, the main problem is how to define ''local observables'' in a ''canonical way'': there exist very good (read: almost conclusive) no go arguments against the mere possibility for even doing this. This issue is intertwined with an observer living inside or outside the universe and it would take pages to explain it in any detail. What surprises me however is that you deny that while this is an open problem for 80 years now (indeed, so long) it most likely implies that it does not work that way (and indeed, I know it doesn't).

Moreover, I guess you start from space and not space-time right? But even on a much simpler plane, you could insist that strict locality is a property of nature; this immediately rules out all the exotics you are willing to consider (so here you have a deep physical reason). The problems with the kind of models you are considering are legio and most importantly, they lack physical insight and motivation. Let me give you a few examples : free QFT on flat space-time is exactly correct without any doubt. For example, it almost canonically follows from: (a) locality (b) causality (c) isotropy and homogeneity of the vacuum (d) 4 dimensions (e) cluster decomposition (f) Hilbert space representations of the symmetry group (g) positive energies (h) statistics. If you think about it for a while, then you recognize that every single requirement is physically mandatory for the limit of zero interactions. Therefore, you have to think about how you are going to build an interacting theory but the latter should have many foundations in common with the free one. Just as plain Minkowski is the short scale limit of general relativity, the free theory should be the short scale limit of the interacting one - so we should have asymptotic freedom and not merely asymptotic safety. A first step in that direction would consist in giving interacting quantum theory itself an Einsteinian (meaning local and fully covariant) formulation. This is a necessary exercise in order to put both theories on the same level. You may imagine that the interacting theory will not be causal, have more exotic statistics and not satisfy the cluster decomposition, but all this should by dynamical: it should follow from the physical requirements of covariance, asymptotic freedom, locality the conditions on the free theory. GFT probably satisfies none of those requirements (including covariance!) and I haven't seen a good principled analysis nowhere in the literature.

So, what do people do? They go in defense mode. They even start to deny that the free theory is a physical limit. This of course is utter rubbish, why in principle should nature not be capable of playing around with the gravitational constant (or the Planck constant or the speed of light) ? You may think about c as a definition of a second starting from a meter, G as a conversion between mass and a meter and hbar as setting the scale for the meter itself. So again, it appears totally obvious to me that the limit of zero G in theory space should exist (as well as the limit of zero interactions) and it is the knowledge of that limit which should be a foundation of your theory just as special relativity is for general relativity in the Palatini formalism and just like classical mechanics is for quantum mechanics in the deformation quantization approach. This is actually also the case for the thermodynamic limit of absolute zero; there have been numerous attempts like stochastic vacuum field fluctuations as an alternative to QED and a big chunk of the physics is determined by the T = 0 limit. This is something which is fundamentally lacking in all approaches to quantum gravity (except one) and it is a big mistake.

Kind regards,

Johan

PS: I do not care about how you write things, expository skills are a matter of social convention and I have never cared too much about what others ''think''. What I do care about is what you write and as far as I can see, you repeat all the hopes and ''misconceptions'' I have heard for more than 10 years.

Dear Daniele,

Now that I see, I did not respond yet to a few points of yours. So, you admit the notion of a particle becomes superfluous in the context of relativity: therefore, why are you doing your best to reinstate this concept in a theory of quantum gravity?! Shouldn't you just do the opposite and move even further away (that is further weaken) from the concept of a particle than it is the case in QFT on Minkowski? Furthermore you imply that conditions like causality, positive energy and statistics are background dependent concepts... they are not by any means. You confuse the principle here with its implementation in QFT on Minkowski; actually, from the latter we know they are independent issues even in this weakened context. By this, I mean that, for example, one can drop positive energies and still get a causal QFT with the right statistics. If you think about it deeper, you will need a principle for having an arrow of time (positive energies) and independently you will need to specify the statistics (that is the very nature of quantum mechanics). Probably, you would need to specify the spin-statistics relation (all research to a spin statistics theorem in quantum gravity points in that direction) as well. So, you still need three independent principles and you haven't gained anything.

The problem is that you assume a priori that gravity has to be quantized like any ''particle'' does. You care to give a good physical motivation for this, apart from saying that ''quantum theory as we know it should be universally applicable?''.

Kind regards,

Johan

So, is quantum space continuous or discrete? If the above speculation is right, to

realize it concretely will be a revolutionary scientific and cultural experience. But it will not provide us with a better answer to this question than: "It depends".

Daniele,

I love the above. It is cagey but true. My argument for analogue does not have your authority.

Jim Hoover

Dear Jim,

thanks a lot for your comment.

I do not know, of course, if I am right or wrong, and only further work will tell. I am sure of one thing only, though, that on this interesting and difficult matter, and at this stage of development, I have no authority whatsoever (as probably nobody else).

Thanks again.

Best,

Daniele

Why do you assume that probably nobody has ''authority'' in this kind of question? Moreover, what would you consider to be a satisfying answer ? If I tell you that local realism cannot be excluded by any experiment, would you say (a) that this is false (b) it is true (c) it is true, but not reasonable? Now suppose I would say that there is no good reason to abandon the continuum and that there exist strong arguments for it such as locality and local Lorentz covariance. Would you say then that (a) this might be true, but it doesn't prove that space-time is continuous since there is an extremely tiny possibility that my assumptions fail (b) this is true and probably means that space-time is a continuum (c) I exaggerate (and you explain why). Moreover, take now into account the ''failure'' of discrete space-time after 30 years and the impossibility of defining local observables for the gravitational field (even in classical gravity), how would you balance these facts?

To make myself crystal clear; suppose you have to bake a chicken and someone would actually make a fire and bake it on a plate, or someone else would put it on a plate and leave it in the sun holding a magnifying glass over it. Would you encourage the second option, knowing the benefits of the first?

Best,

Johan

Dear Daniele,

I wanted to say hello and let you know how much I enjoyed reading your essay. I appreciated how it gave an understandable context for how a condensed matter system is analyzed starting from what is viewed at a macro level and nicely diving down into the details. I was uncertain if group field theory deals with the nucleus and the strong interaction. I thought your discussion was extremely relevant about what it might take to find a deeper explanation. Thanks for writing a very approachable and interesting essay.

Kind regards, Russell Jurgensen

Ciao Daniele,

Nice job! Indeed, one cannot even ponder a structure for space unless time (as in GR) is added. I like the way you get down to the nitty gritty of the topic. I have always admired Fotini Markopoulous's concept of geometrogenesis and I'm glad to see it getting more attention.

Thanks for this, and I hope you get a chance to visit my essay as well.

Best,

Tom

Dear Daniele Oriti

As generally it bother me at all contestants that Zeilinger-Brukner theory of atomization of information is not mentioned here. Feynman also mentioned similarly as they. So the essence is in discrete world. Almost obvious existence of Planck's space-time shows similarly. It would be well, that all contestants should mentioned this - I think on proponents and opponents of digital physical world. I have not read all essays, does anyone mentioned this?

It is a general argument (also yours) that quantum field theory is continuous, and that field is more important than particles. But we should not ignore that final version of QFT is in discrete Planck's space.

You mentioned richness of those models. But we should be aware that there is also richness of possibility of simple models. It is expected that quantum gravity should be a simple theory. You gave a comparison with condensed matter. This can be also a rich topic, but this is not necessary for foundations of this. And, foundations of condensed matter and quantum gravity are different.

You mentioned that you begin with quantization of space. It should be well to mention that space-time without matter does not exist, so this is a quantization of matter. (But from your graphs it seems, that this is your standpoint.)

You mentioned that wave function exists in a every node. It seem to me, that wave function is only a thing of continuous space. I speculate this after reading Brukner-Zeilinger interpretation (quant-ph/0212084).

I was late for this contest, so my ideas can be read here. http://vixra.org/pdf/1103.0025v1.pdf

I have also an article, which is not speculative and it is a base for the above article. http://vixra.org/pdf/1012.0006v3.pdf There are also additional claims about connections between matter and space-time. I need someone who will be the arxiv endorser for this article. So that I will get opportunity, that my theories will be discussed.

Best regards

Janko Kokosar