Reformulation of Loop gravity in progress, comment?

In summary, the May 2012 "discrete symmetries" paper arXiv 1205.0733 signals a reformulation getting under way, I think. I'm curious to know how other people read this.
  • #141
The idea of this thread is to keep track of the full spectrum of different ways QG is being reshaped in the runup to the main QG conference http://www.perimeterinstitute.ca/conferences/loops-13 (Loops 13 at Perimeter Institute in July 2013).

Now with only 6 months left before conference there has appeared what I think is maybe the MOST ambitious reformulation initiative. This is via GAUGE NETWORK and GAUGE FOAM analogs by Marcolli and van Suijlekom (at Caltech and Nijmegen). These are analogous to the spin networks and spin foams that are already used in the current LQG formulation, except now the chunks of space are equipped with noncommutative geometry.

http://arxiv.org/abs/1301.3480
Gauge networks in noncommutative geometry
Matilde Marcolli, Walter D. van Suijlekom
(Submitted on 15 Jan 2013)
We introduce gauge networks as generalizations of spin networks and lattice gauge fields to almost-commutative manifolds. The configuration space of quiver representations (modulo equivalence) in the category of finite spectral triples is studied; gauge networks appear as an orthonormal basis in a corresponding Hilbert space. We give many examples of gauge networks, also beyond the well-known spin network examples. We find a Hamiltonian operator on this Hilbert space, inducing a time evolution on the C*-algebra of gauge network correspondences...
...
The people:
http://www.its.caltech.edu/~matilde/
http://www.math.ru.nl/~waltervs/index.php?page=home [Broken]
(Walter Daniel van Suijlekom b. 1978, dual career as professional musician, interesting. PhD 2005 at SISSA Trieste. Since 2007 postdoc at Nijmegen, same place as Renate Loll. Has taught some interesting courses at Nijmegen including NCG, i.e. spectral geometry.)

I think this Marcolli van Suijlekom initiative could lead to a C* algebra formulation of LQG. Already they have a Hamiltonian and time evolution of gauge networks (at least in some case they are considering). At the end of the paper there is a proposal for how to do gauge FOAMS and what the PARTITION FUNCTION should look like, i.e. a PATH INTEGRAL approach coming out. And it looks in a very general way rather like what you see in Zakopane Lectures (2011)

The idea is to have chunks of ALMOST COMMUTATIVE space (represented by finite dimensional spectral triples, spectral polyhedra?) at the vertices of the network, and have the links be morphisms somehow joining the vertices. Almost commutative spectral geometry is how Connes and friends realized the Standard Model. So in spirit very much like current LQG except chunks of almost commutative space at the vertices instead of chunks of ordinary commutative space.

I think these things are all related and am not sure what to call this development. Perhaps "C*-quantum gravity, T-time, entanglement entropy, gauge networks".
I should recall that work towards general covariant (GC) analysis such as GC-thermo, GC statistical (quantum) mechanics seems to motivate a star algebra (M,ω) formulation because this finally solves the time problem. One gets an observer-independent (Tomita) flow on the observables algebra. Then how do we recover the regional STRUCTURE of space in the (M,ω) context? I see Bianchi Myers paper in this light. The key word "architecture" in the title is a signal. Also Kiefer Schell paper leans in that direction.
======================
C*-quantum gravity, T-time, entanglement, gauge networks
Marcolli van Suijlekom—Gauge networks in noncommutative geometry (http://arxiv.org/abs/1301.3480)
Rovelli—General relativistic statistical mechanics (http://arxiv.org/abs/1209.0065)
Bianchi—Horizon entanglement entropy and universality of the graviton coupling (ILQGS talk and http://arxiv.org/abs/1211.0522)
Bianchi Myers—On the Architecture of Spacetime Geometry (http://arxiv.org/abs/1212.5183)
Kiefer Schell—Interpretation of the triad orientations in loop quantum cosmology (http://arxiv.org/abs/1210.0418)

===================
The LQG-LQC bridge, hybrid LQC, matter bounce
Alesci and Cianfrani have established a clear derivation of LQC from the full LQG theory--canonically quantizing first and then reducing to the cosmo case. Loop cosmology is getting into inhomogeneous regimes with multiple degrees of freedom and exploring "pre-inflationary" dynamics in more detail. Provisionally I'm calling that "hybrid loop cosmology" because several recent papers join existing LQC bounce with Fock space in a kind of hybrid. I can't list all the papers developing inhomogeneous LQC, so will just mention a small sample.
Alesci Cianfrani—Quantum-Reduced Loop Gravity: Cosmology (http://arxiv.org/abs/1301.2245)
Agullo Ashtekar Nelson—An Extension of the Quantum Theory of Cosmological Perturbations to the Planck Era (http://arxiv.org/abs/1211.1354)
The pre-inflationary dynamics of loop quantum cosmology: Confronting quantum gravity with observations (in prep)
Wilson-Ewing—The Matter Bounce Scenario in Loop Quantum Cosmology (http://arxiv.org/abs/1211.6269)
====================

Besides the above there are several other clear reformulation initiatives under way.
twistorLQG (Speziale's ILQGS talk and http://arxiv.org/abs/1207.6348)
tensorialGFT (Carrozza's ILQGS talk and http://arxiv.org/abs/1207.6734)
holonomySF (Hellmann's ILQGS talk and http://arxiv.org/abs/1208.3388)
dust (Wise's ILQGS talk and http://arxiv.org/abs/1210.0019)
 
Last edited by a moderator:
Physics news on Phys.org
  • #142
The twistorial reformulation of LQG has taken a big step forward with:
http://arxiv.org/abs/1301.5859
Hamiltonian spinfoam gravity
Wolfgang M. Wieland
(Submitted on 24 Jan 2013)
This paper presents a Hamiltonian formulation of spinfoam-gravity, which leads to a straight-forward canonical quantisation. To begin with, we derive a continuum action adapted to the simplicial decomposition. The equations of motion admit a Hamiltonian formulation, allowing us to perform the constraint analysis. We do not find any secondary constraints, but only get restrictions on the Lagrange multipliers enforcing the reality conditions. This comes as a surprise. In the continuum theory, the reality conditions are preserved in time, only if the torsionless condition (a secondary constraint) holds true. Studying an additional conservation law for each spinfoam vertex, we discuss the issue of torsion and argue that spinfoam gravity may indeed miss an additional constraint. Next, we canonically quantise. Transition amplitudes match the EPRL (Engle--Pereira--Rovelli--Livine) model, the only difference being the additional torsional constraint affecting the vertex amplitude.
28 pages, 2 figures

To get a sense of Wieland you could watch some of this Perimeter talk (February 2012):
http://pirsa.org/12020129/
 
Last edited:
  • #143
In 3 days, Bianchi's ILQGS talk: Entanglement entropy in LQG
The slides PDF may be posted beforehand (this has happened with ILQGS) and the URL will probably be: http://relativity.phys.lsu.edu/ilqgs/bianchi012913.pdf
After the talk the audio URL will probably be http://relativity.phys.lsu.edu/ilqgs/bianchi012913.wav
He has shown that the BH horizon entropy and the CEH (cosmic event horizon) entropy can both be understood as entanglement.
The state on the accessible side must be MIXED because entangled with the state on the other side. This gives a simple handle on the entropy, as he shows.

The talk will necessarily take as its point of departure his November paper. http://arxiv.org/abs/1211.0522 This is a classic: a major landmark, very short (4 pages), simply worded, and effecting a radical change of perspective.
The November paper was not set in anyone theory---e.g. not specifically a LQG paper. It was quite general.
So now we will see what's new since then, what specifically QG development can have grown out of it.

If one is rereading the papers in order to prepare to understand the online talk, there is also Bianchi's December paper with Rob Myers (http://arxiv.org/abs/1212.5183) which I mentioned two posts back.
 
Last edited:
  • #144
marcus said:
The twistorial reformulation of LQG has taken a big step forward with:

I think it should be remarked that this time time is only a dimension like in GR.
 
  • #145
  • #146
The audio for Bianchi's 29 Jan ILQGS talk has been posted:
http://relativity.phys.lsu.edu/ilqgs/bianchi012913.wav

Next up (12 February) is Hal Haggard's talk:
Dynamical chaos and the volume gap

http://relativity.phys.lsu.edu/ilqgs/
Interestingly, Haggard's research has already been "covered" (as they say in the music business) by a prominent particle theorist named Berndt Müller.
The existence of a smallest observable volume (a gap in the vol operator spectrum between zero and the smallest positive eigenvalue) is the key to the discreteness/finiteness feature of LQG. There is an analogy between "energy conserving" Hamiltonian dynamics and "volume preserving" shape-shifting of polyhedra that let's one treat it as a dynamical system. Classical chaos tends to go along with discrete spectrum at the quantum level. So the work here is supportive.
==============

Here are some of the more interesting papers that appeared this month, giving us an idea of directions the field will be going in 2013. I'll have to factor these into the reformulation themes already identified in this thread.

It is important that the relation between LQG and the cosmology application LQC has been clarified by the Alesci Cianfrani and the Engle papers. One can do the symmetry reduction AFTER quantization. So there is no obstacle to viewing LQC as a straightforward application of the full theory. In fact Engle shows that one can EMBED LQC in full theory without ever invoking the piecewise linear category, or fixing on some particular graph structure.
This opens the way to testing full LQG theory by confronting LQC predictions with early universe observation. So it's a 2013 milestone.

http://arxiv.org/abs/1301.1264
Inflation as a prediction of loop quantum cosmology
Linda Linsefors, Aurelien Barrau
(Submitted on 7 Jan 2013)

http://arxiv.org/abs/1301.2245
Quantum-Reduced Loop Gravity: Cosmology
Emanuele Alesci, Francesco Cianfrani
(Submitted on 10 Jan 2013)
We introduce a new framework for loop quantum gravity: mimicking the spinfoam quantization procedure we propose to study the symmetric sectors of the theory imposing the reduction weakly on the full kinematical Hilbert space of the canonical theory. As a first application of Quantum-Reduced Loop Gravity we study the inhomogeneous Bianchi I model. The emerging quantum cosmological model represents a simplified arena on which the complete canonical quantization program can be tested. The achievements of this analysis could elucidate the relationship between Loop Quantum Cosmology and the full theory.

http://arxiv.org/abs/1301.6210
Embedding loop quantum cosmology without piecewise linearity
Jonathan Engle
(Submitted on 26 Jan 2013)
An important goal is to understand better the relation between full loop quantum gravity (LQG) and the simplified, reduced theory known as loop quantum cosmology (LQC), directly at the quantum level. Such a firmer understanding would increase confidence in the reduced theory as a tool for formulating predictions of the full theory,...The present paper constructs an embedding of the usual state space of LQC into that of standard LQG, that is, LQG based on piecewise analytic paths. The embedding is well-defined even prior to solving the diffeomorphism constraint, at no point is a graph fixed, and at no point is the piecewise linear category used. ...

==========
The Marcolli Suijlekom paper opens a possible path to building the standard matter field model into LQG. It let's the NODES of the network be SPECTRAL GEOMETRY CHUNKS instead of ordinary geometry chunks. Alain Connes and others have shown that a version of the standard matter model lives in spectral geometry. It does not have to be laid on by hand. A LQG spin network is re-named a "gauge network" when the nodes are spectral.

http://arxiv.org/abs/1301.3480
Gauge networks in noncommutative geometry
Matilde Marcolli, Walter D. van Suijlekom
(Submitted on 15 Jan 2013)
We introduce gauge networks as generalizations of spin networks and lattice gauge fields to almost-commutative manifolds. ... beyond the well-known spin network examples. We find a Hamiltonian operator on this Hilbert space, inducing a time evolution on the C*-algebra of gauge network correspondences...

=============
Wolfgang Wieland's paper puts the whole business of secondary constraints, reality conditions etc on a new footing. We should recognize that it changes the terms of the discussion. So it is a major paper.

http://arxiv.org/abs/1301.5859
Hamiltonian spinfoam gravity
Wolfgang M. Wieland
(Submitted on 24 Jan 2013)
This paper presents a Hamiltonian formulation of spinfoam-gravity, which leads to a straight-forward canonical quantisation. To begin with, we derive a continuum action adapted to the simplicial decomposition. The equations of motion admit a Hamiltonian formulation, allowing us to perform the constraint analysis. We do not find any secondary constraints, but only get restrictions on the Lagrange multipliers enforcing the reality conditions. This comes as a surprise. In the continuum theory, the reality conditions are preserved in time, only if the torsionless condition (a secondary constraint) holds true. Studying an additional conservation law for each spinfoam vertex, we discuss the issue of torsion and argue that spinfoam gravity may indeed miss an additional constraint. Next, we canonically quantise. Transition amplitudes match the EPRL (Engle--Pereira--Rovelli--Livine) model, the only difference being the additional torsional constraint affecting the vertex amplitude.
28 pages, 2 figures
 
Last edited:
  • #147
The papers of Engle and by Alesci Cianfrani mentioned in above post indicate that Loop cosmology can be embedded in the full LQG theory, or derived from it. Reductions to the interesting cases for cosmology can be done AFTER the quantum theory is constructed. It has been pointed out that this opens the way for testing the full LQG theory. It has to give the right answers about the early universe.

Hence the relevance of this paper by Agullo Ashtekar Nelson that appeared today:
http://arxiv.org/abs/1302.0254
The pre-inflationary dynamics of loop quantum cosmology: Confronting quantum gravity with observations
Ivan Agullo, Abhay Ashtekar, William Nelson
(Submitted on 1 Feb 2013)
Using techniques from loop quantum gravity, the standard theory of cosmological perturbations was recently generalized to encompass the Planck era. We now apply this framework to explore pre-inflationary dynamics. The framework enables us to isolate and resolve the true trans-Planckian difficulties, with interesting lessons both for theory and observations. Specifically, for a large class of initial conditions at the bounce, we are led to a self consistent extension of the inflationary paradigm over the 11 orders of magnitude in density and curvature, from the big bounce to the onset of slow roll. In addition, for a narrow window of initial conditions, there are departures from the standard paradigm, with novel effects ---such as a modification of the consistency relation between the ratio of the tensor to scalar power spectrum and the tensor spectral index, as well as a new source for non-Gaussianities--- which could extend the reach of cosmological observations to the deep Planck regime of the early universe.
64 pages, 15 figures

The main actively researched QG rival to LQG in modeling the early universe has been the Asymptotic Safe QG program. String and Causal Dynamical Triangulations don't seem to have much to say about the start of expansion---or at least not much is being written from those perspectives.
However, the AS program may have experienced a severe setback with the appearance of Hamber's result that a QG theory in which the cosmological constant runs cannot be general covariant. For some discussion:
https://www.physicsforums.com/showthread.php?t=668612
 
Last edited:
  • #148
Marcus, what about some kind of "status report" of LQG?

We have several new ideas in the field:
- non-interacting dust defining field of physical observers and physical Hamiltonian
- spinor / twistor variables and changes in the constraint structure
- some relations (but still no proof of equivalence) for canonical and spin foam models

What do you think? Where are the main results and what are the key issues?
 
  • #149
tom.stoer said:
Marcus, what about some kind of "status report" of LQG?

We have several new ideas in the field:
- non-interacting dust defining field of physical observers and physical Hamiltonian
- spinor / twistor variables and changes in the constraint structure
- some relations (but still no proof of equivalence) for canonical and spin foam models

What do you think? Where are the main results and what are the key issues?

That's a nice question. I will have to respond in several stages. First, a general introduction, the overall context, how LQG fits into the picture, where I think it's going.

The overall program is Quantum Cosmology (QC). Humans should understand particle theory in dynamic geometry because our historic big job now is to accurately model the start of expansion. We have an enormous amount of data resulting from the start of expansion---a "big bounce" I expect but that remains to be seen.

That is the top of the mountain that the LQG climbers and other teams are working towards. So locating their current "status" means (for me) locating relative to that goal. Where are they relative to that goal?

Part of the goal, also, is to understand where Dark Matter comes from, and if possible to explain the size of the classical Cosmological Constant (part of understanding dynamic geometry.)

The path up the mountain is zig-zag. So I am always watching out for these surprise changes, that we have seen the Quantum Relativists make several times over the years.

Besides the particle theory of the "big bounce" (or whatever was the Beginning-of-Expansion) there is also the thermodynamics and statistical mechanics of the "big bounce" (or whatever was the Beginning-of-Expansion). Maybe that has tended to be overlooked, but it is a persistent interesting problem. I will set it aside for the moment and just think about the quantum particle relativist side.

This is why I think it is so important to review Marciano's May 2012 talk, and to hear Alexander's talk tomorrow (26 February 2013).
 
  • #150
As I see it, LQG is a subfield of LQC. Much (perhaps most) Loop community work is now Cosmo-related. Papers by Engle and by Alesci show a good bridge, symmetry reduction can be done at the quantum level. And symmetry restrictions are gradually being relaxed--eg the work on Bianchi-One cosmologies.

If you think of this as "the tail wagging the dog" then as an aggregate research effort the tail is now bigger than the dog.

We tend to think of the main Loop research centers as Marseille, Perimeter, PennState, Erlangen, Warsaw...

But Agullo and Nelson are very important in cosmology and Agullo is at Cambridge and Nelson is at Nijmegen. And now suddenly I have realized that Dartmouth is an important place on the Loop map. That is where Marciano is--currently postdoc working with Alexander.

The Dartmouth people seem to start with particle theory and cosmology, and with unification at a classical level, and then move naturally into a spin foam quantization!

That makes me think that what Loop is depends on what you start with. It is a bunch of background-free lattice gauge theory techniques that have so far been explored using classic GR as a starting point. But the Dartmouth people show me that you do not have to be limited to starting with GR---you can start with more.

That is what tomorrow's talk by Alexander is about, and what the 7 May talk by Marciano will be about.

So this probably is a major revolution in Loop---another turning point in the zig-zag climb up the mountain.

Also it is a very necessary revolution, because to understand the Big Bounce one has to understand matter fields behavior in extreme dynamic geometry conditions. So one probably needs some BF-like extension of Plebanski action, and a background-free lattice quantization. Spinfoam in other words. This understanding is the mountain top that people are working towards, and we can think of Spinfoam work so far as practice for that ascent.

Anyway that is my two cents. It is how I see the general overall context: where LQG fits in.
I will try to assemble some kind of "progress report" for you on a more detailed level, although I'm no expert in the business.

EDIT: BTW Marciano's May 2012 talk is http://pirsa.org/12050079/
also BTW it would help me, if you have any comments on the above, to know your reactions.
It may be a while before I get to the job of assembling details of the picture and responses to this much, from you, could I think be very helpful.

EDIT: Reminder, the link to get slides PDF and audio for tomorrow's talk by Alexander is
http://relativity.phys.lsu.edu/ilqgs/
The title of the talk is Gravity Electroweak Unification
 
Last edited:
  • #151
Although not well enough informed to give a professional level "progress report" for Loop research, in view of Tom's question I'll give some opinions and impressions. The following two papers tend to EMBED Loop cosmology in the full theory, thus making the full theory astrophysically testable.
I think these two represent some of the most important recent progress.

http://arxiv.org/abs/1301.2245
Quantum-Reduced Loop Gravity: Cosmology
Emanuele Alesci, Francesco Cianfrani
(Submitted on 10 Jan 2013)
We introduce a new framework for loop quantum gravity: mimicking the spinfoam quantization procedure we propose to study the symmetric sectors of the theory imposing the reduction weakly on the full kinematical Hilbert space of the canonical theory. As a first application of Quantum-Reduced Loop Gravity we study the inhomogeneous Bianchi I model. The emerging quantum cosmological model represents a simplified arena on which the complete canonical quantization program can be tested. The achievements of this analysis could elucidate the relationship between Loop Quantum Cosmology and the full theory.

http://arxiv.org/abs/1301.6210
Embedding loop quantum cosmology without piecewise linearity
Jonathan Engle
(Submitted on 26 Jan 2013)
An important goal is to understand better the relation between full loop quantum gravity (LQG) and the simplified, reduced theory known as loop quantum cosmology (LQC), directly at the quantum level. Such a firmer understanding would increase confidence in the reduced theory as a tool for formulating predictions of the full theory,...The present paper constructs an embedding of the usual state space of LQC into that of standard LQG, that is, LQG based on piecewise analytic paths. The embedding is well-defined even prior to solving the diffeomorphism constraint, at no point is a graph fixed, and at no point is the piecewise linear category used. ...

The most important progress any QG theory can make is progress towards testability and this can be of two kinds, IMHO:
1) Observable consequences in early universe astrophysics.
2) LHC-testable consequences of unification of gravity with particle physics.

As to point 1), there has been substantial progress towards deriving observable consequences of Loop cosmology--more than I can readily list or outline. Here is a recent example. See also papers by Barrau, Grain, and co-authors.

http://arxiv.org/abs/1302.0254
The pre-inflationary dynamics of loop quantum cosmology: Confronting quantum gravity with observations
Ivan Agullo, Abhay Ashtekar, William Nelson
(Submitted on 1 Feb 2013)
Using techniques from loop quantum gravity, the standard theory of cosmological perturbations was recently generalized to encompass the Planck era. We now apply this framework to explore pre-inflationary dynamics. The framework enables us to isolate and resolve the true trans-Planckian difficulties, with interesting lessons both for theory and observations. Specifically, for a large class of initial conditions at the bounce, we are led to a self consistent extension of the inflationary paradigm over the 11 orders of magnitude in density and curvature, from the big bounce to the onset of slow roll. In addition, for a narrow window of initial conditions, there are departures from the standard paradigm, with novel effects ---such as a modification of the consistency relation between the ratio of the tensor to scalar power spectrum and the tensor spectral index, as well as a new source for non-Gaussianities--- which could extend the reach of cosmological observations to the deep Planck regime of the early universe.
64 pages, 15 figures

Here are the quantum cosmology papers that the INSPIRE search engine identifies (appeared since 2009, ranked by cite count.) This includes Loop AND all the other kinds of quantum cosmology. So one can compare and get a sense of the relative importance.
http://inspirehep.net/search?ln=en&...2y=2013&sf=&so=a&rm=citation&rg=50&sc=0&of=hb

As to point 2) there has, to my knowledge, been slight progress thus far. A beginning was made last year in the work of Alexander, Marciano, and Smolin. We'll have to see how that goes.

I suspect that any "progress report" for Loop should mention Wieland's recent paper. It addresses many issues---joining the Hamiltonian and Spinfoam approaches---understanding the various conditions and constraints. Basically learning how to put the theory in a nice form. Again we will have to see how this work continues.
http://arxiv.org/abs/1301.5859
Hamiltonian spinfoam gravity
Wolfgang M. Wieland
(Submitted on 24 Jan 2013)
This paper presents a Hamiltonian formulation of spinfoam-gravity, which leads to a straight-forward canonical quantisation. To begin with, we derive a continuum action adapted to the simplicial decomposition. The equations of motion admit a Hamiltonian formulation, allowing us to perform the constraint analysis. We do not find any secondary constraints, but only get restrictions on the Lagrange multipliers enforcing the reality conditions. This comes as a surprise. In the continuum theory, the reality conditions are preserved in time, only if the torsionless condition (a secondary constraint) holds true. Studying an additional conservation law for each spinfoam vertex, we discuss the issue of torsion and argue that spinfoam gravity may indeed miss an additional constraint. Next, we canonically quantise. Transition amplitudes match the EPRL (Engle--Pereira--Rovelli--Livine) model, the only difference being the additional torsional constraint affecting the vertex amplitude.
28 pages, 2 figures

In one point I find I can't cover all the topics! Just in the past year there has also been remarkable progress in studying the Loop black hole.

I will have to redo this and try to organize it better.
 
Last edited:
  • #152
Marcus, my question was about LQG as the general framework, not about LQC.
 
  • #153
tom.stoer said:
Marcus, my question was about LQG as the general framework, not about LQC.
I know. I don't think that is the best way to look at it.
I explained why in post #149

QC is the overall framework for quantum gravity.
It contains the big thing we want to understand.
It has a huge amount of relevant data.
It is the arena of testability.

So QC is the natural framework to consider.
 
  • #154
Marcus, I disagree. QG is the basis, QC is an application.

Cosmology is an application of GR which provides the fundamental framework - not the other way round.
 
  • #155
Progress in QG can only be understood in the larger QC context.
Cosmology is what gives scientific meaning and urgency to the study of geometry at Planck scale.

Cosmology is what gives us the questions:
dark matter
expansion of distances between stationary observers
the fact that geometry is dynamic
the fact that there is another gravitational constant Lambda which Newton didn't know about
how does matter behave in extreme dynamic geometry?
etc.

And Cosmology is where the great bulk of observational data is, that is relevant
to quantum gravity.

So to me it seems inevitable to conclude that QC provides the larger context in which LQG progress
must be assessed. If one is to make a meaningful assessment, that is.
 
Last edited:
  • #156
Cosmology is relevant as one application and as 'experimental setup'. But the develoment of a theory like QG focusses on a sound mathematical construction, of course to be tested in a larger context.

The development of GR was focussed on symmetry principles, field equations etc., not on expanding universes. The construction of QM was focussed on matrix and wave mechanics, not on spectroscopy.

Of course you have to apply a theory in larger context, and you have to have quantitative predictions and means to falsify the model. But first you have to have a model (or a class of models) passing basic tests like mathematical consistency, absence of anomalies, GR as semiclassical limit, ...

Looking at the current status of LQG most astrophysical data do not help much. They have to get the math right (and the latest spinor/twistor papers indicate that the celebrated Rovellian models are still incomplete). Assume we have a new deep space survey providing revolutionary results regarding CMB, galaxy superclusters or even the topology of our universe. This wouldn't change the status of LQG, unfortunately. They are not (yet) in the situation to select from a class of well-defined models based on experimental input. They are still in the construction phase.
 
  • #157
tom.stoer said:
Cosmology is relevant as one application and as 'experimental setup'. But the develoment of a theory like QG focusses on a sound mathematical construction, of course to be tested in a larger context.

The development of GR was focussed on symmetry principles, field equations etc., not on expanding universes. The construction of QM was focussed on matrix and wave mechanics, not on spectroscopy.

Of course you have to apply a theory in larger context, and you have to have quantitative predictions and means to falsify the model. But first you have to have a model (or a class of models) passing basic tests like mathematical consistency, absence of anomalies, GR as semiclassical limit, ...

Looking at the current status of LQG most astrophysical data do not help much. They have to get the math right (and the latest spinor/twistor papers indicate that the celebrated Rovellian models are still incomplete). Assume we have a new deep space survey providing revolutionary results regarding CMB, galaxy superclusters or even the topology of our universe. This wouldn't change the status of LQG, unfortunately. They are not (yet) in the situation to select from a class of well-defined models based on experimental input. They are still in the construction phase.

You have some good points here. Let me try to say my idea in a different way. LQG is thought of as a pure gravity program---the quantum dynamics of pure matterless geometry.
I watch the research closely (as closely as I, as non-expert, can) and I see a trend. You could think of it as the emergence of a new field of research called LQGM ("loop quantum geometry-and-matter").

I can try to make a general statement about this. Let's see if this is right: LQGM arises from the application of principles of loop quantum gravity (LQG) to general relativity and standard matter theory. The goal is to quantize Plebanskian action containing GR and the local symmetries of standard matter, by following the physical ideas and mathematical tools underlying LQG.

Basically this involves building a more general theory, of which some version of the old LQG might turn out to be a special case. The important thing is that the new theoretical program follows the physical ideas and applies the mathematical tools developed in the more specialized earlier program.

Does this make sense to you? Many of the leading people I can think of who used to be working on the more limited specialized LQG program I now see to be working on combining geometry with matter in one way or another---creating, in effect, a broader more general program (undoubtably with some new mathematical tools and possibly with some new principles besides those developed in the earlier program.)

If you would like, I will try to enumerate the people involved in this move, and some of the papers. Let me know what you think, and what (if any) additional information you require.
 
Last edited:
  • #158
I can't see this big move and I think that incorporating matter has something to do with the key issues like definition of Dirac-observables, physical observers, gauge fixing/unfixing etc. And I think it's a new line of research, but not a paradigm shift.

But besides these details, responding to your question whether it makes sense to me: yes, it does.
 
  • #159
tom.stoer said:
I can't see this big move and I think that incorporating matter has something to do with the key issues like definition of Dirac-observables, physical observers, gauge fixing/unfixing etc. And I think it's a new line of research, but not a paradigm shift.

But besides these details, responding to your question whether it makes sense to me: yes, it does.

Your question about progress of the purely QG part of the program also makes sense to me, although I take a broader view of the program. On the SPINORIAL formulation front, Etera Livine offers this as a review.
http://arxiv.org/abs/1201.2120
It's a paper by Dupuis Speziale Tambornino called
Spinors and Twistors in Loop Gravity and Spin Foams
"Spinorial tools have recently come back to fashion in loop gravity and spin foams. They provide an elegant tool relating the standard holonomy-flux algebra to the twisted geometry picture of the classical phase space on a fixed graph, and to twistors. In these lectures we provide a brief and technical introduction to the formalism and some of its applications."

Here's a recent paper by Livine himself:
http://arxiv.org/abs/1302.7142
Holonomy Operator and Quantization Ambiguities on Spinor Space
Etera R. Livine
(Submitted on 28 Feb 2013)
"We construct the holonomy-flux operator algebra in the recently developed spinor formulation of loop gravity. We show that, when restricting to SU(2)-gauge invariant operators, the familiar grasping and Wilson loop operators are written as composite operators built from the gauge-invariant 'generalized ladder operators' recently introduced in the U(N) approach to intertwiners and spin networks. We comment on quantization ambiguities that appear in the definition of the holonomy operator and use these ambiguities as a toy model to test a class of quantization ambiguities which is present in the standard regularization and definition of the Hamiltonian constraint operator in loop quantum gravity."

Livine is to be one of the invited speakers at Loops 2013 and my guess is he will summarize what is going on in this area. At this point I can't do better than simply refer to what he indicates is the review paper of choice (Dupuis, Speziale, Tambornino).
 
Last edited:
  • #160
The earlier interesting discussion with Tom helped me to clarify my view that the hallmark of any QG theory is how it deals with cosmology (and the start of expansion in particular.)
The robust identifying feature of Loop Quantum Geometry has been that it leads back to a bounce with a period of natural faster-than-exponential expansion ("superinflation") due to quantum effects at high density. To summarize:
marcus said:
Progress in QG can only be understood in the larger QC context.
Cosmology is what gives scientific meaning and urgency to the study of geometry at Planck scale.

Cosmology is what gives us the questions:
dark matter
expansion of distances between stationary observers
the fact that geometry is dynamic
the fact that there is another gravitational constant Lambda which Newton didn't know about
how does matter behave in extreme dynamic geometry?
etc.

And Cosmology is where the great bulk of observational data is, that is relevant
to quantum gravity.

So to me it seems inevitable to conclude that QC provides the larger context in which LQG progress
must be assessed. If one is to make a meaningful assessment, that is.

Now something I did not expect has happened. The Group Field Theory (GFT) program has come out with a way to do GFT cosmology. This could have a significant effect on the Loop program.

http://arxiv.org/abs/1303.3576
Cosmology from Group Field Theory
Steffen Gielen, Daniele Oriti, Lorenzo Sindoni
(Submitted on 14 Mar 2013)
We identify a class of condensate states in the group field theory (GFT) approach to quantum gravity that can be interpreted as macroscopic homogeneous spatial geometries. We then extract the dynamics of such condensate states directly from the fundamental quantum GFT dynamics, following the procedure used in ordinary quantum fluids. The effective dynamics is a non-linear and non-local extension of quantum cosmology. We also show that any GFT model with a kinetic term of Laplacian type gives rise, in a semi-classical (WKB) approximation and in the isotropic case, to a modified Friedmann equation. This is the first concrete, general procedure for extracting an effective cosmological dynamics directly from a fundamental theory of quantum geometry.
5 pages
 
  • #161
Since I last posted on this thread two important papers have come out, one by Ashtekar and the other by George Ellis, Reza Tavakol, Tim Clifton. Both have to do with cosmology which is pretty clearly turning out to be the main arena for QG theory. Early universe cosmology, in particular, is a kind of testing ground for Loop gravity. Several of the recent posts on this thread have been on the general them of LQG and cosmology.

What Ashtekar here calls "Planck regime" is in other papers he cites specified to be "pre-inflationary" expansion history arising from the LQG bounce.
The George Ellis paper is interesting because of the whole gravitational entropy issue.
there are conceptual difficulties with defining the entropy of the gravitational field---IOW geometric entropy. There is in fact no agreed on idea of gravitational entropy. So one cannot say what happens to the entropy during the LQG bounce. the concept (which is probably observer-dependent and scale-dependent) fails to be defined. So Ellis paper is much needed:it attacks this problem of defining entropy.

http://arxiv.org/abs/1303.5612
A Gravitational Entropy Proposal
Timothy Clifton, George F R Ellis, Reza Tavakol
(Submitted on 22 Mar 2013)
We propose a thermodynamically motivated measure of gravitational entropy based on the Bel-Robinson tensor, which has a natural interpretation as the effective super-energy-momentum tensor of free gravitational fields. The specific form of this measure differs depending on whether the gravitational field is Coulomb-like or wave-like, and reduces to the Bekenstein-Hawking value when integrated over the interior of a Schwarzschild black hole. For scalar perturbations of a Robertson-Walker geometry we find that the entropy goes like the Hubble weighted anisotropy of the gravitational field, and therefore increases as structure formation occurs. This is in keeping with our expectations for the behaviour of gravitational entropy in cosmology, and provides a thermodynamically motivated arrow of time for cosmological solutions of Einstein's field equations. It is also in keeping with Penrose's Weyl curvature hypothesis.
17 pages

Ashtekar's paper is more of a review of recent progress in pre-inflation LQG cosmology and consequent opportunities to make testable predictions about features of the cosmic microwave background.

http://arxiv.org/abs/1303.4989
Loop Quantum Gravity and the The Planck Regime of Cosmology
Abhay Ashtekar
(Submitted on 20 Mar 2013)
The very early universe provides the best arena we currently have to test quantum gravity theories. The success of the inflationary paradigm in accounting for the observed inhomogeneities in the cosmic microwave background already illustrates this point to a certain extent because the paradigm is based on quantum field theory on the curved cosmological space-times. However, this analysis excludes the Planck era because the background space-time satisfies Einstein's equations all the way back to the big bang singularity. Using techniques from loop quantum gravity, the paradigm has now been extended to a self-consistent theory from the Planck regime to the onset of inflation, covering some 11 orders of magnitude in curvature. In addition, for a narrow window of initial conditions, there are departures from the standard paradigm, with novel effects, such as a modification of the consistency relation involving the scalar and tensor power spectra and a new source for non-Gaussianities. Thus, the genesis of the large scale structure of the universe can be traced back to quantum gravity fluctuations in the Planck regime. This report provides a bird's eye view of these developments for the general relativity community.
23 pages, 4 figures. Plenary talk at the Conference: Relativity and Gravitation: 100 Years after Einstein in Prague. To appear in the Proceedings to be published by Edition Open Access. Summarizes results that appeared in journal articles [2-13]
 
Last edited:
  • #162
Yes, I totally agree that the falsification of a quantum gravity theory can be done by using cosmology. But also I agree with Tom that the grounded principles are not based on experimental results. During the birth of quantum mechanics, there was a close relationship between teory and experiment. One part of interpretational problems are caused by this history. Another part is reflected in the trial to define quantum geometry. Simple questions like: does the quantum geometrical state (for instance the superposition of spin networks) actually exists? are not answered. But an aswer would be important to go on.
But back to this topic...
In particular, a quantum gravity theory should explain the exponential increase of inflation. But I don't say any really good result in this direction (which satisfied me).
BTW, we formulated an inflation scenario (which purely geometrical roots) which is able to explain the exponential increase. In particular, the factor can be explicitly calculated using topological invaraints of the three manifold only. Maybe a beginning?
 
  • #163
torsten said:
BTW, we formulated an inflation scenario (which purely geometrical roots) which is able to explain the exponential increase. In particular, the factor can be explicitly calculated using topological invariants of the three manifold only. Maybe a beginning?

That sounds intriguing! Maybe you should give a link to the paper. I cannot remember all the papers and the interesting results that come out of your alternative smooth structures approach.

In particular, a quantum gravity theory should explain the exponential increase of inflation.

Just to review, Loop bounce cosmology does have a brief period of faster than exponential expansion, which happens inevitably as a consequence of the bounce. It naturally occurs and then naturally ends as the density declines. It is called "super-inflation" because the scale factor goes as eHt with H increasing.

In ordinary inflation the scale factor goes as eHt with H approximately constant or slowly decreasing.

But this period of super-inflation does not continue long enough, according to the LQC calculations. So the researchers have had to assume the existence of a scalar field which could take over from the naturally occurring super-inflation and serve as an "inflaton" field, to finish the job.

A recent paper about that:

http://arxiv.org/abs/1301.1264
Inflation as a prediction of loop quantum cosmology
Linda Linsefors, Aurelien Barrau
(Submitted on 7 Jan 2013)
Loop quantum cosmology is known to be closely linked with an inflationary phase. In this article, we study quantitatively the probability for a long enough stage of slow-roll inflation to occur, by assuming a minimalist massive scalar field as the main content of the universe. The phase of the field in its "pre-bounce" oscillatory state is taken as a natural random parameter. We find that the probability for a given number of inflationary e-folds is quite sharply peaked around 145, which is indeed more than enough to solve all the standard cosmological problems. In this precise sense, a satisfactory inflation is therefore a clear prediction of loop gravity. In addition, we derive an original and stringent upper limit on the Barbero-Immirzi parameter. The general picture about inflation, super-inflation, deflation and super-deflation is also much clarified in the framework of bouncing cosmologies.
6 pages, 4 figures
 
  • #164
Thanks for the paper. I understand the necessarity to introduce this scalar field but this field is not an output of the model.
That sounds intriguing! Maybe you should give a link to the paper. I cannot remember all the papers and the interesting results that come out of your alternative smooth structures approach.
Here is the link:
http://arxiv.org/abs/1301.3628
of the paper "On the origin of inflation by using exotic smoothness". It also explained the reason to introduce the scalar field.
 
  • #165
torsten said:
...
Here is the link:
http://arxiv.org/abs/1301.3628
of the paper "On the origin of inflation by using exotic smoothness". It also explained the reason to introduce the scalar field.

It is an intriguing paper. Can you give me the most basic intuition of how a transition to an alternative differential structure can cause inflation? Intuitively what causes the inflation and then what causes it to stop?
 
  • #166
It is an intriguing paper. Can you give me the most basic intuition of how a transition to an alternative differential structure can cause inflation? Intuitively what causes the inflation and then what causes it to stop?
In this paper we consider an exotic [itex]S^3 \times \mathbb{R}[/itex]. This differential structure is characterized by a topological transition from a 3-sphere to another homology 3-sphere (for instance Poincare sphere) and back. Here we choose a homology 3-sphere [itex]\Sigma[/itex] with a hyperbolic structure (i.e. negative scalar curvature). Then we have a change from a positive curvature (3-sphere) to a 3-manifold with negative curvature (looking like a 3-sphere).
This transition leads to an accelaerated expansion. But we were able to show more. The 4-manifold representing the transition also carries a hyperbolic structure leading to an exponential increase (two geodesics in a hyperbolic geometry diverge exponentially). This exponential increase can be also expressed explicitly: there is a tree with an exponential number of states.
We obtained also an effective picture for this transition: it can be described by a SU(2)-valued scalar field (inflanton).
Again: [itex]S^3 \rightarrow\Sigma \rightarrow S^3[/itex] are the transitions, the first transition leads to an accelerated expansion whereas the second transition stops it.
I hope it helps. My view is more geometrically.
 
  • #167
Thanks Torsten! That does help.

I should mention in connection with new developments in LQG that the ILQGS blog has a wide-audience article by Mano Alesci and Francesco Cianfrani about their (quantum) Reduced LQG
approach to cosmology.
http://ilqgs.blogspot.com/2013/03/reduced-loop-quantum-gravity.html

It makes a bridge between the full LQG theory and cosmology because the reduction to the homogeneous and isotropic case is done within LQG
In conventional LQC the reduction is done first, and then this is reduced model is quantized, so the connection with the full theory is not so direct.

As I recall Jon Engle also has some recent work along these lines. It is very important because cosmology is the main testing ground for QG. We have to know what the full LQG theory has to say about the CMB power spectrum, conditions around the start of expansion, and the subsequent inflation.

The blog post by Alesci Cianfrani gives motivation and intuitive understanding of their new (reduced) version of Loop gravity.
 
  • #168
In four days Wolfgang Wieland will give an ILQGS talk (available online) on a Hamiltonian approach to Spin Foam QG. This has been an important outstanding problem, how to unite the covariant Spin Foam approach with the older canonical LQG Hamiltonian approach.

Revised ILQGS Spring 2013 Schedule
http://relativity.phys.lsu.edu/ilqgs/
Code:
DATE	Seminar Title	                    Speaker 	     Institution
Jan 29 [B]Entanglement in loop quantum gravity[/B] Eugenio Bianchi  Perimeter Institute
Feb 12 [B]Dynamical chaos and the volume gap [/B]  Hal Haggard	     CPT Marseille
Feb 26 [B]Gravity electroweak unification[/B]	    Stephon Alexander Dartmouth College
Mar 12 [B]Quantum reduced loop gravity[/B]	    E.Alesci/F.Cianfrani Univ. Erlangen 
Mar 26 [B]Bianchi-I LQC,Kasner shift&inflation[/B] Brajesh Gupt     LSU
Apr  9 [B]Hamiltonian spinfoam gravity[/B]         Wolfgang Wieland CPT Marseille
Apr 23 TBA                                  Martin Bojowald  Penn State	
May  7 [B]Emergence of BF theories and gravi-weak Plebanski models from spinors[/B]
					    Antonino Marciano Dartmouth College

Wolfgang's paper of the same title, that the talk will be based on, is currently the leading paper on our first quarter 2013 MIP poll. https://www.physicsforums.com/showthread.php?t=681598

http://arxiv.org/abs/1301.5859
Hamiltonian spinfoam gravity
Wolfgang M. Wieland
(Submitted on 24 Jan 2013)
This paper presents a Hamiltonian formulation of spinfoam-gravity, which leads to a straight-forward canonical quantisation. To begin with, we derive a continuum action adapted to the simplicial decomposition. The equations of motion admit a Hamiltonian formulation, allowing us to perform the constraint analysis. We do not find any secondary constraints, but only get restrictions on the Lagrange multipliers enforcing the reality conditions. ... Transition amplitudes match the EPRL (Engle--Pereira--Rovelli--Livine) model, the only difference being the additional torsional constraint affecting the vertex amplitude.
28 pages, 2 figures
 
Last edited:
  • #169
Wolfgang Wieland's talk at ILQGS was given today and both the slides PDF and the audio are already online.
http://relativity.phys.lsu.edu/ilqgs/
I still do not see anyone single clear direction in how LQG+Spinfoam theory is developing. It seems necessary to keep alert to several possible directions. To me personally the line taken by Wieland and Speziale and others (see the short bibliography at the end of Wolfgang's talk) looks very promising. It is aimed directly at showing the CONSISTENCY of the theory and they seem to have made good progress.

On the other hand we saw in fourth quarter 2012 a lot of work being done with TENSOR models. Some ILQGS talks were given on tensorial QG. And today a relevant paper by Razvan Gurau appeared on arxiv. So I should post that as instance of either a closely related rival approach (GFT) or as a reformulation that is brewing.

http://arxiv.org/abs/1304.2666
The 1/N Expansion of Tensor Models Beyond Perturbation Theory
Razvan Gurau
(Submitted on 9 Apr 2013)
We analyze in full mathematical rigor the most general quartically perturbed invariant probability measure for a random tensor. Using a version of the Loop Vertex Expansion (which we call the mixed expansion) we show that the cumulants write as explicit series in 1/N plus bounded rest terms. The mixed expansion recasts the problem of determining the subleading corrections in 1/N into a simple combinatorial problem of counting trees decorated by a finite number of loop edges.
As an aside, we use the mixed expansion to show that the (divergent) perturbative expansion of the tensor models is Borel summable and to prove that the cumulants respect an uniform scaling bound. In particular the quartically perturbed measures fall, in the N to infinity limit, in the universality class of Gaussian tensor models.
45 pages

Gurau's paper is entirely technical. He refers to application in Quantum Gravity (e.g. via GFT) but does not give any detail. He proves many theorems. Past experience of both Gurau and Rivasseau work makes me expect that this may have significance for QG applications but I cannot foresee the specifics. Maybe some other people can.
 
Last edited:
  • #170
A propos the preceding post, Razvan Gurau is to be one of the invited plenary speakers at the upcoming Loops conference, as is also Vincent Rivasseau. Loops 2013 will be held at Perimeter in latter half of July, just three months off, and I still have only a very rough notion of what the current state of LQG is that will appear at the biennial conference. There seem to be an unusually large number of different currents. We can watch the seminar talks at Perimeter, and at the ILQGS, during the run-up to the conference, for hints as to what the main developments are. Here are a couple of April talks scheduled at Perimeter:

The first of these seems unusual. An imaginary part of the action?
April 18, Yasha Neiman:
http://www.perimeterinstitute.ca/seminar/imaginary-part-gravitational-action-and-black-hole-entropy
THE IMAGINARY PART OF THE GRAVITATIONAL ACTION AND BLACK HOLE ENTROPY
I present a candidate for a new derivation of black hole entropy. The key observation is that the action of General Relativity in bounded regions has an imaginary part, arising from the boundary term. The formula for this imaginary part is closely related to the Bekenstein-Hawking entropy formula, and coincides with it for certain classes of regions. This remains true in the presence of matter, and generalizes appropriately to Lovelock gravity. The imaginary part of the action is a versatile notion, requiring neither stationarity nor any knowledge about asymptotic infinity. Thus, it may provide a handle on quantum gravity in finite and dynamical regions. I derive the above results, make connections with standard approaches to black hole entropy, and speculate on the meaning of it all. Implications for loop quantum gravity are also discussed.

April 25, Casey Tomlin:
http://www.perimeterinstitute.ca/seminar/loop-quantization-weak-coupling-limit-euclidean-gravity
LOOP QUANTIZATION OF A WEAK-COUPLING LIMIT OF EUCLIDEAN GRAVITY
I will describe recent work in collaboration with Adam Henderson, Alok Laddha, and Madhavan Varadarajan on the loop quantization of a certain GN→ 0 limit of Euclidean gravity, introduced by Smolin. The model allows one to test various quantization choices one is faced with in loop quantum gravity, but in a simplified setting. The main results are the construction of finite-triangulation Hamiltonian and diffeomorphism constraint operators whose continuum limits can be evaluated in a precise sense, such that the quantum Dirac algebra of constraints closes nontrivially and free of anomalies. The construction relies heavily on techniques of Thiemann's QSD treatment, and lessons learned applying such techniques to the loop quantization of parameterized scalar field theory and the diffeomorphism constraint in loop quantum gravity. I will also briefly discuss the status of the quantum constraint algebra in full LQG, and how some of the lessons learned from the present model may guide us in that setting.

http://www.perimeterinstitute.ca/events/scientific-events

The Yasha Neiman talk relates to this March 2013 paper:
http://arxiv.org/abs/1303.4752
Imaginary action, spinfoam asymptotics and the 'transplanckian' regime of loop quantum gravity
Norbert Bodendorfer, Yasha Neiman
(Both authors recently took postdocs at Penn State.)

The Casey Tomlin talk relates to several recent papers:
http://arxiv.org/abs/1204.0211
Constraint algebra in LQG reloaded : Toy model of a U(1)^{3} Gauge Theory I
Adam Henderson, Alok Laddha, Casey Tomlin

http://arxiv.org/abs/1210.3960
Constraint algebra in LQG reloaded : Toy model of an Abelian gauge theory - II Spatial Diffeomorphisms
Adam Henderson, Alok Laddha, Casey Tomlin

http://arxiv.org/abs/1210.6869
Towards an Anomaly-Free Quantum Dynamics for a Weak Coupling Limit of Euclidean Gravity
Casey Tomlin, Madhavan Varadarajan
(Again for the most part the authors are full or part-time connected with Ashtekar's institute at Penn State, but also have ties with MPI-Potsdam, RRI-Bangalore, CMI-Chennai.)
 
Last edited:
  • #171
Smolin is a relativist and i love him, and i love quantizing space, and time, yes! But gravitons? Please! Show me one!
.
As far as I'm concerned it's a toss up as to whether gravity is a feature of vacuum energy or some kind of boson that goes between masses.
.
After all, inertia inherited from inflation powered the early bang. That's a feature of spacetime, and some say, the vacuum energy. The Casimir effect is also a feature of spacetime [some would say it's exclusively electromagnetic], and vacuum energy. Another expansionary feature of spacetime is referred to as "dark energy." It seems entirely reasonable that gravity is a feature of vacuum energy too. You might call it, the "anti-expansion force."
.
In such a case there would still be quantum descriptions but it would amount to a superposition of forces created by the vacuum resulting in a "vapor pressure" on masses. This would simultaneously empty out voids and create galaxy clusters.
.
i'm reminded of Occam's razor. Why use 4 forces when you can use 3?
.
i've never understood why relativity somehow assumes the graviton. It's just an assumption as far as i can tell.
.
If the LQG folks are trying to quantize "defacto" gravitons, fine. Bless them!
.
But I'm betting my mana that there is no single unique boson identifiable as a graviton.
.
Yes, i know Friedman and Einstein early on looked to see if gravity was caused by vacuum energy and calculated something like 10^128 times TOO MUCH energy and essentially shelved the idea. My understanding of today's thinking is that the existence of other energy from different places "cancels" this enormous vacuum energy, as a result of superposition. That just means the subject is still open.
.
-0
 
Last edited:
  • #172
negativzero said:
...
If the LQG folks are trying to quantize "defacto" gravitons, fine. Bless them!
...
That's a good word for it. The graviton arises in quantizing perturbations of flat geometry, so to get their hands on gravitons the LQG folks restrict the boundary of a spacetime region in such a way as to approximate flatness.

You could say that gravitons are more native to a fixed background approach and not native to fully dynamic geometry. So a background independent non-perturbative approach like LQG has to use some arbitrary restrictions just to make them "exist". They are, one could say, only "de facto"

Registration for Loops 2013 (late July, still 3 months off) has been remarkable.
The website now has announced:
Due to overwhelming response, registration for this conference will close on Wednesday, May 1, 2013.
http://www.perimeterinstitute.ca/conferences/loops-13

The conference organizers have taken an interesting tack: mixing with other approaches, bringing together all kinds of background independent QG. It is worth reading their statement of purpose/philosophy. I do not remember seeing any Loop conference organizer statement quite this open-to-all-QG, and I've been watching since 2004 when Rovelli hosted one at Marseille.
==quote Loops 3013==

Quantum gravity aims at unifying Einstein's vision of space-time as a dynamical object with the realization that fundamental physics and hence space-time has to be quantum. This opens up a large variety of research questions and directions, which range from foundational physical issues having to do with the nature of space and time, to current searches for experimental signatures of quantum spacetime.

This conference, which is part of the series of Loops conferences, will present and review recent progress and highlights in loop quantum gravity and other quantum gravity approaches. We will focus mainly on background independent approaches which are approaches that do not depend on perturbation theory formulated in a classical background.

Plenary talks will highlight the most important recent developments in quantum gravity research. Afternoon (parallel) sessions are open to contributed talks and will be focussed on particular topics or subfields and give room for discussions, exchange of ideas and a critical assessment of open questions.

The conference will bring quantum gravity researchers from all over the world together and we also hope to share the excitement of quantum gravity research with participants from other research fields.
==endquote==
 
Last edited:
  • #173
Thx marcus. This is a fine thread. i may never catch up to you guys.
.
You wrote, in part: "...background independent non-perturbative approach like LQG has to use some arbitrary restrictions just to make them "exist"..."
.
So they need to constrain the edges of their space such that stuff propagates in a tidy parallel manner?
.
i assume the perspective of the point-like observer is not sufficient to constrain boundaries, because somebody else would have said so already. What about the particle sphere? A coordinate system where the surface of an expanding sphere is the "origin?" i guess the question I'm getting at would be whether simply changing coordinate systems makes any sense as an "arbitrary restriction?" Or do the restrictions have to act to describe event generation on an individual basis for each particle or bit of momentum?
.
Your comments are always welcome.
-0
 
  • #174
negativzero said:
...So they need to constrain the edges of their space such that stuff propagates in a tidy parallel manner?... i guess the question I'm getting at would be whether simply changing coordinate systems makes any sense as an "arbitrary restriction?"
...

"Graviton propagator" work was carried out in 2005-2007...
Here is a 2007 paper---not to read, it's too technical and has no diagrams. But it's a kind of landmark from which to work backwards in time. The more conceptual stuff (with diagrams) came a year or two earlier, and hit a technical snag. Then modifications in the "vertex" formula, which goes into calculating transition amplitudes, overcame that difficulty.

http://arxiv.org/abs/0711.1284
The complete LQG propagator: II. Asymptotic behavior of the vertex
Emanuele Alesci, Carlo Rovelli
(Submitted on 8 Nov 2007)
In a previous article we have show that there are difficulties in obtaining the correct graviton propagator from the loop-quantum-gravity dynamics defined by the Barrett-Crane vertex amplitude. Here we show that a vertex amplitude that depends nontrivially on the intertwiners can yield the correct propagator. We give an explicit example of asymptotic behavior of a vertex amplitude that gives the correct full graviton propagator in the large distance limit.
Comments: 16 pages

What I have to find are simpler more conceptual papers with diagrams that give an intuitive idea of how they are going after the graviton "two-point function" or propagator: the amplitude of going from point A (on the region's boundary) to point B(also on the boundary).
This should show an inverse-square dependence, in line with the Newtonian inverse square law.
I'll look.
EDIT: still no success
 
Last edited:
  • #175
marcus, I've only read:
http://arxiv.org/pdf/0711.1284v1.pdf

once, but i think i get the general picture.
.
We are talking about the "graph paper" of the micro reality, where time and space are parceled out into their smallest bits. This article is about the smallest bits of gravity. Vertices are like events or particle interactions, and edges of the geometry are called "propagators" and are like force carriers.
.
Forgive me if i sound impartial, but i have been a fan of a simple 3D tetrahedral structure for decades, perhaps because, well, it's simple!
Now the LQG gang are trying to force 5 simplex tetrahedons my down my brain! Okay, they seemed to have dumbed down the geometry with intertwining or something to 4 simplex with a slight asymmetry. And, "...That is, the spin-intertwiner correlations are just functions of the spin-spin correlations for a state with this symmetry! The intertwiner dependence drops out! This means that the propagator is completely unaffected from the correlations involving the intertwiners...," but they definitely lose me, anyway.
...
In this algebra gravitons are like phonons in a tuba?:
"...In doing so, we have also learned several lessons. The main lesson is that the non-commutativity
of the angles requires a semiclassical state to have an oscillatory behavior in the intertwiners. In
order to match this behavior, and approximate the semiclassical dynamics, the vertex must have a
similar oscillatory dependence on the intertwiners. (This should not affect with possible finitness
properties of the model [15].) The second lesson is that the symmetries of the boundary state must
be considered with care, if we do not want to loose relevant dynamical information. Symmetrizing
over the permutation of the vertices is a simple way of achieving a symmetric state without inserting
additional unwanted symmetries..."
.
Another thing, it's trivial, i suppose, "...Using this technique, we have found in a previous paper [4]
that the definition of the dynamics of loop quantum gravity (LQG) by means of the Barrett-Crane
(BC) spinfoam vertex [5] fails to give the correct tensorial structure of the graviton propagator in the
large-distance limit..." If it was MY pet theory, and i wanted some comment i might try to work the numbers and come up with dark energy coming out of the same math.
.
Thanks, and please feed me more. One day i'll get it.
-0
 
Last edited:
<h2>1. What is Loop gravity?</h2><p>Loop gravity is a theoretical framework that attempts to reconcile the principles of general relativity and quantum mechanics. It proposes that the fabric of space-time is made up of tiny loops, or networks, rather than being continuous.</p><h2>2. What is the purpose of reformulating Loop gravity?</h2><p>The reformulation of Loop gravity aims to address some of the limitations and challenges of the original theory, such as the inability to fully incorporate matter and the difficulty in making testable predictions.</p><h2>3. How is the reformulation of Loop gravity in progress?</h2><p>The reformulation of Loop gravity is an ongoing process, with researchers continuously working to refine and improve the theory. This involves developing new mathematical tools and techniques, as well as testing the theory through simulations and experiments.</p><h2>4. What are some potential implications of a successful reformulation of Loop gravity?</h2><p>If a successful reformulation of Loop gravity is achieved, it could have significant implications for our understanding of the fundamental laws of the universe. It could potentially lead to a more complete theory of quantum gravity and shed light on phenomena such as black holes and the Big Bang.</p><h2>5. What are some challenges in reformulating Loop gravity?</h2><p>One of the main challenges in reformulating Loop gravity is the complexity of the mathematics involved. It also requires a deep understanding of both general relativity and quantum mechanics, which are notoriously difficult to reconcile. Additionally, there is a lack of experimental data to test the predictions of the theory, making it difficult to validate or refine the reformulation.</p>

1. What is Loop gravity?

Loop gravity is a theoretical framework that attempts to reconcile the principles of general relativity and quantum mechanics. It proposes that the fabric of space-time is made up of tiny loops, or networks, rather than being continuous.

2. What is the purpose of reformulating Loop gravity?

The reformulation of Loop gravity aims to address some of the limitations and challenges of the original theory, such as the inability to fully incorporate matter and the difficulty in making testable predictions.

3. How is the reformulation of Loop gravity in progress?

The reformulation of Loop gravity is an ongoing process, with researchers continuously working to refine and improve the theory. This involves developing new mathematical tools and techniques, as well as testing the theory through simulations and experiments.

4. What are some potential implications of a successful reformulation of Loop gravity?

If a successful reformulation of Loop gravity is achieved, it could have significant implications for our understanding of the fundamental laws of the universe. It could potentially lead to a more complete theory of quantum gravity and shed light on phenomena such as black holes and the Big Bang.

5. What are some challenges in reformulating Loop gravity?

One of the main challenges in reformulating Loop gravity is the complexity of the mathematics involved. It also requires a deep understanding of both general relativity and quantum mechanics, which are notoriously difficult to reconcile. Additionally, there is a lack of experimental data to test the predictions of the theory, making it difficult to validate or refine the reformulation.

Similar threads

  • Beyond the Standard Models
Replies
7
Views
1K
  • Beyond the Standard Models
Replies
3
Views
2K
  • Beyond the Standard Models
Replies
2
Views
2K
Replies
2
Views
2K
  • Beyond the Standard Models
Replies
4
Views
2K
  • Beyond the Standard Models
Replies
7
Views
431
  • Beyond the Standard Models
Replies
19
Views
2K
  • Beyond the Standard Models
Replies
24
Views
4K
  • Beyond the Standard Models
Replies
4
Views
1K
  • Beyond the Standard Models
Replies
0
Views
408
Back
Top