Loop Quantum Gravity: A Themed Issue in Honor of Prof. Abhay Ashtekar

A special issue of Universe (ISSN 2218-1997). This special issue belongs to the section "Foundations of Quantum Mechanics and Quantum Gravity".

Deadline for manuscript submissions: closed (31 July 2023) | Viewed by 15047

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Department of Physics and Astronomy, Louisiana State University, Baton Rouge, LA 70803, USA
Interests: quantum gravity; quantum cosmology; early universe cosmology
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Dear Colleagues,

Unification of gravity and quantum theory remains one of the most important outstanding problems of theoretical physics. In 1986, Ashtekar’s discovery of new variables led to a novel formulation of general relativity which overcame challenging problems in the canonical quantum gravity approach, leading to the birth of loop quantum gravity program. The reformulation of general relativity not only allowed gravity to be viewed on the lines of Yang-Mills theory, but it also had various applications in classical and quantum aspects of physics of black holes, numerical relativity, and cosmology. In the last three decades, both the canonical and covariant versions of loop quantum gravity have systematically addressed long-standing questions in quantum gravity. While research in the 1990s and the first half of the 2000s established a mathematically rigorous non-perturbative background independent treatment of quantum gravity, showing the way classical differential geometry of Einstein’s theory of general relativity is replaced by quantum geometry,  the last 15 years have seen many developments to understand the detailed structure of quantum Riemannian geometry, quantum dynamics, and the physical implications of quantum geometry for cosmology and black holes.

35 years have passed since Prof. Abhay Ashtekar's detailed paper on the "New Hamiltonian formulation of general relativity." This Special Issue is designed in honor of Prof. Abhay Ashtekar, to highlight developments in various sub-fields of loop quantum gravity and its covariant version of spinfoams. Articles from leading experts in the field, from different regions around the world, showcase the current state of the art.

Prof. Dr. Parampreet Singh
Guest Editor

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Keywords

  • loop quantum gravity
  • spinfoams
  • canonical quantum gravity
  • quantum cosmology
  • quantum aspects of black holes

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Published Papers (10 papers)

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Research

27 pages, 662 KiB  
Article
Causal Structure in Spin Foams
by Eugenio Bianchi and Pierre Martin-Dussaud
Universe 2024, 10(4), 181; https://doi.org/10.3390/universe10040181 - 14 Apr 2024
Cited by 1 | Viewed by 1346
Abstract
The metric field of general relativity is almost fully determined by its causal structure. Yet, in spin foam models of quantum gravity, the role played by the causal structure is still largely unexplored. The goal of this paper is to clarify how causality [...] Read more.
The metric field of general relativity is almost fully determined by its causal structure. Yet, in spin foam models of quantum gravity, the role played by the causal structure is still largely unexplored. The goal of this paper is to clarify how causality is encoded in such models. The quest unveils the physical meaning of the orientation of the two-complex and its role as a dynamical variable. We propose a causal version of the EPRL spin foam model and discuss the role of the causal structure in the reconstruction of a semiclassical space–time geometry. Full article
(This article belongs to the Special Issue Loop Quantum Gravity: A Themed Issue in Honor of Prof. Abhay Ashtekar)
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22 pages, 359 KiB  
Article
Diffeomorphism Covariance and the Quantum Schwarzschild Interior
by I. W. Bornhoeft, R. G. Dias and J. S. Engle
Universe 2024, 10(2), 89; https://doi.org/10.3390/universe10020089 - 13 Feb 2024
Viewed by 1482
Abstract
We introduce a notion of residual diffeomorphism covariance in quantum Kantowski–Sachs (KS) describing the interior of a Schwarzschild black hole. We solve for the family of Hamiltonian constraint operators satisfying the associated covariance condition, as well as parity invariance, preservation of the Bohr [...] Read more.
We introduce a notion of residual diffeomorphism covariance in quantum Kantowski–Sachs (KS) describing the interior of a Schwarzschild black hole. We solve for the family of Hamiltonian constraint operators satisfying the associated covariance condition, as well as parity invariance, preservation of the Bohr Hilbert space of the Loop Quantum KS and a correct (naïve) classical limit. We further explore the imposition of minimality for the number of terms and compare the solution with those of other Hamiltonian constraints proposed for the Loop Quantum KS in the literature. In particular, we discuss a lapse that was recently commonly chosen due to the resulting decoupling of the evolution of the two degrees of freedom and the exact solubility of the model. We show that such a choice of lapse can indeed be quantized as an operator that is densely defined on the Bohr Hilbert space and that any such operator must include an infinite number of shift operators. Full article
(This article belongs to the Special Issue Loop Quantum Gravity: A Themed Issue in Honor of Prof. Abhay Ashtekar)
18 pages, 975 KiB  
Article
On Covariant and Canonical Hamiltonian Formalisms for Gauge Theories
by Alejandro Corichi, Juan D. Reyes and Tatjana Vukašinac
Universe 2024, 10(2), 60; https://doi.org/10.3390/universe10020060 - 29 Jan 2024
Cited by 1 | Viewed by 1259
Abstract
The Hamiltonian description of classical gauge theories is a very well studied subject. The two best known approaches, namely the covariant and canonical Hamiltonian formalisms, have received a lot of attention in the literature. However, a full understanding of the relation between them [...] Read more.
The Hamiltonian description of classical gauge theories is a very well studied subject. The two best known approaches, namely the covariant and canonical Hamiltonian formalisms, have received a lot of attention in the literature. However, a full understanding of the relation between them is not available, especially when the gauge theories are defined over regions with boundaries. Here, we consider this issue, by first making it precise what we mean by equivalence between the two formalisms. Then, we explore several first-order gauge theories and assess whether their corresponding descriptions satisfy the notion of equivalence. We shall show that, even when in several cases the two formalisms are indeed equivalent, there are counterexamples that signal that this is not always the case. Thus, non-equivalence is a generic feature of gauge field theories. These results call for a deeper understanding of the subject. Full article
(This article belongs to the Special Issue Loop Quantum Gravity: A Themed Issue in Honor of Prof. Abhay Ashtekar)
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13 pages, 338 KiB  
Article
Chiral Loop Quantum Supergravity and Black Hole Entropy
by Konstantin Eder and Hanno Sahlmann
Universe 2023, 9(7), 303; https://doi.org/10.3390/universe9070303 - 23 Jun 2023
Cited by 2 | Viewed by 887
Abstract
Recent work has shown that local supersymmetry on a spacetime boundary in N-extended AdS supergravity in chiral variables implies coupling to a boundary OSp(N|2)C super Chern–Simons theory. Consequently there has been a proposal to define and [...] Read more.
Recent work has shown that local supersymmetry on a spacetime boundary in N-extended AdS supergravity in chiral variables implies coupling to a boundary OSp(N|2)C super Chern–Simons theory. Consequently there has been a proposal to define and calculate the entropy S for the boundary, in the supersymmetric version of loop quantum gravity, for the minimal case N=1, via this super Chern–Simons theory. We give an overview of how supergravity can be treated in loop quantum gravity. We review the calculation of the dimensions of the quantum state spaces of UOSp(1|2) super Chern–Simons theory with punctures, and its analytical continuation, for the fixed quantum super area of the surface, to OSp(1|2)C. The result is S=aH/4 for large (super) areas. Lower order corrections can also be determined. We begin also a discussion of the statistical mechanics of the surface degrees of freedom by calculating the grand canonical partition function at zero chemical potential. This is a new result. Full article
(This article belongs to the Special Issue Loop Quantum Gravity: A Themed Issue in Honor of Prof. Abhay Ashtekar)
24 pages, 389 KiB  
Article
Dynamically Implementing the μ¯-Scheme in Cosmological and Spherically Symmetric Models in an Extended Phase Space Model
by Kristina Giesel and Hongguang Liu
Universe 2023, 9(4), 176; https://doi.org/10.3390/universe9040176 - 3 Apr 2023
Cited by 1 | Viewed by 1283
Abstract
We consider an extended phase space formulation for cosmological and spherically symmetric models in which the choice of a given μ¯-scheme can be implemented dynamically. These models are constructed in the context of the relational formalism by using a canonical transformation [...] Read more.
We consider an extended phase space formulation for cosmological and spherically symmetric models in which the choice of a given μ¯-scheme can be implemented dynamically. These models are constructed in the context of the relational formalism by using a canonical transformation on the extended phase space, which provides a Kuchař decomposition of the extended phase space. The resulting model can be understood as a gauge-unfixed model of a given μ¯-scheme. We use this formalism to investigate the restrictions to the allowed μ¯-scheme from this perspective and discuss the differences in the cosmological and spherically symmetric case. This method can be useful, for example, to obtain a μ¯-scheme in a top-down derivation from full LQG to symmetry-reduced effective models, where, for some models, only the μ0-scheme has been obtained thus far. Full article
(This article belongs to the Special Issue Loop Quantum Gravity: A Themed Issue in Honor of Prof. Abhay Ashtekar)
23 pages, 561 KiB  
Article
Modeling Quantum Particles Falling into a Black Hole: The Deep Interior Limit
by Alejandro Perez, Salvatore Ribisi and Sami Viollet
Universe 2023, 9(2), 75; https://doi.org/10.3390/universe9020075 - 31 Jan 2023
Cited by 2 | Viewed by 1201
Abstract
In this paper, we construct a solvable toy model of the quantum dynamics of the interior of a spherical black hole with falling spherical scalar field excitations. We first argue about how some aspects of the quantum gravity dynamics of realistic black holes [...] Read more.
In this paper, we construct a solvable toy model of the quantum dynamics of the interior of a spherical black hole with falling spherical scalar field excitations. We first argue about how some aspects of the quantum gravity dynamics of realistic black holes emitting Hawking radiation can be modeled using Kantowski–Sachs solutions with a massless scalar field when one focuses on the deep interior region rM (including the singularity). Further, we show that in the rM regime, and in suitable variables, the KS model becomes exactly solvable at both the classical and quantum levels. The quantum dynamics inspired by loop quantum gravity is revisited. We propose a natural polymer quantization where the area a of the orbits of the rotation group is quantized. The polymer (or loop) dynamics is closely related to the Schroedinger dynamics away from the singularity with a form of continuum limit naturally emerging from the polymer treatment. The Dirac observable associated with the mass is quantized and shown to have an infinite degeneracy associated with the so-called ϵ-sectors. Suitable continuum superpositions of these are well-defined distributions in the fundamental Hilbert space and satisfy the continuum Schroedinger dynamics. Full article
(This article belongs to the Special Issue Loop Quantum Gravity: A Themed Issue in Honor of Prof. Abhay Ashtekar)
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36 pages, 871 KiB  
Article
On Propagation in Loop Quantum Gravity
by Thomas Thiemann and Madhavan Varadarajan
Universe 2022, 8(12), 615; https://doi.org/10.3390/universe8120615 - 23 Nov 2022
Cited by 6 | Viewed by 1491
Abstract
A rigorous implementation of the Wheeler–Dewitt equations was derived in the context of Loop Quantum Gravity (LQG) and was coined Quantum Spin Dynamics (QSD). The Hamiltonian constraint of QSD was criticised as being too local and to prevent “propagation” in canonical LQG. That [...] Read more.
A rigorous implementation of the Wheeler–Dewitt equations was derived in the context of Loop Quantum Gravity (LQG) and was coined Quantum Spin Dynamics (QSD). The Hamiltonian constraint of QSD was criticised as being too local and to prevent “propagation” in canonical LQG. That criticism was based on an algorithm developed for QSD for generating solutions to the Wheeler–DeWitt equations. The fine details of that algorithm could not be worked out because the QSD Hamiltonian constraint makes crucial use of the volume operator, which cannot be diagonalised analytically. In this paper, we consider the U(1)3 model for Euclidean vacuum LQG which consists of replacing the structure group SU(2) by U(1)3 and otherwise keeps all properties of the SU(2) theory intact. This enables analytical calculations and the fine details of the algorithm ingto be worked out. By considering one of the simplest possible non-trivial classes of solutions based on very small graphs, we show that (1) an infinite number of solutions ingexist which are (2) generically not normalisable with respect to the inner product on the space of spatially diffeomorphism invariant distributions and (3) generically display propagation. Due to the closeness of the U(1)3 model to Euclidean LQG, it is extremely likely that all three properties hold also in the SU(2) case and even more so in physical Lorentzian LQG. These arguments can in principle be made water tight using modern numerical (e.g., ML or QC) methods combined with the techniques developed in this paper which we reserve for future work. Full article
(This article belongs to the Special Issue Loop Quantum Gravity: A Themed Issue in Honor of Prof. Abhay Ashtekar)
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31 pages, 626 KiB  
Article
Dirac Observables in the 4-Dimensional Phase Space of Ashtekar’s Variables and Spherically Symmetric Loop Quantum Black Holes
by Geeth Ongole, Hongchao Zhang, Tao Zhu, Anzhong Wang and Bin Wang
Universe 2022, 8(10), 543; https://doi.org/10.3390/universe8100543 - 19 Oct 2022
Cited by 5 | Viewed by 1395
Abstract
In this paper, we study a proposal put forward recently by Bodendorfer, Mele and Münch and García-Quismondo and Marugán, in which the two polymerization parameters of spherically symmetric black hole spacetimes are the Dirac observables of the four-dimensional Ashtekar’s variables. In this model, [...] Read more.
In this paper, we study a proposal put forward recently by Bodendorfer, Mele and Münch and García-Quismondo and Marugán, in which the two polymerization parameters of spherically symmetric black hole spacetimes are the Dirac observables of the four-dimensional Ashtekar’s variables. In this model, black and white hole horizons in general exist and naturally divide the spacetime into the external and internal regions. In the external region, the spacetime can be made asymptotically flat by properly choosing the dependence of the two polymerization parameters on the Ashtekar variables. Then, we find that the asymptotical behavior of the spacetime is universal, and, to the leading order, the curvature invariants are independent of the mass parameter m. For example, the Kretschmann scalar approaches zero as KA0r4 asymptotically, where A0 is generally a non-zero constant and independent of m, and r the geometric radius of the two-spheres. In the internal region, all the physical quantities are finite, and the Schwarzschild black hole singularity is replaced by a transition surface whose radius is always finite and non-zero. The quantum gravitational effects are negligible near the black hole horizon for very massive black holes. However, the behavior of the spacetime across the transition surface is significantly different from all loop quantum black holes studied so far. In particular, the location of the maximum amplitude of the curvature scalars is displaced from the transition surface and depends on m; so does the maximum amplitude. In addition, the radius of the white hole is much smaller than that of the black hole, and its exact value sensitively depends on m, too. Full article
(This article belongs to the Special Issue Loop Quantum Gravity: A Themed Issue in Honor of Prof. Abhay Ashtekar)
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7 pages, 254 KiB  
Article
A Covariant Polymerized Scalar Field in Semi-Classical Loop Quantum Gravity
by Rodolfo Gambini, Florencia Benítez and Jorge Pullin
Universe 2022, 8(10), 526; https://doi.org/10.3390/universe8100526 - 10 Oct 2022
Cited by 12 | Viewed by 1295
Abstract
We propose a new polymerization scheme for scalar fields coupled to gravity. It has the advantage of being a (non-bijective) canonical transformation of the fields, and therefore ensures the covariance of the theory. We study it in detail in spherically symmetric situations and [...] Read more.
We propose a new polymerization scheme for scalar fields coupled to gravity. It has the advantage of being a (non-bijective) canonical transformation of the fields, and therefore ensures the covariance of the theory. We study it in detail in spherically symmetric situations and compare to other approaches. Full article
(This article belongs to the Special Issue Loop Quantum Gravity: A Themed Issue in Honor of Prof. Abhay Ashtekar)
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15 pages, 326 KiB  
Article
Mass of Cosmological Perturbations in the Hybrid and Dressed Metric Formalisms of Loop Quantum Cosmology for the Starobinsky and Exponential Potentials
by Simon Iteanu and Guillermo A. Mena Marugán
Universe 2022, 8(9), 463; https://doi.org/10.3390/universe8090463 - 7 Sep 2022
Cited by 6 | Viewed by 1486
Abstract
The hybrid and the dressed metric formalisms for the study of primordial perturbations in Loop Quantum Cosmology lead to dynamical equations for the modes of these perturbations that are of a generalized harmonic-oscillator type, with a mass that depends on the background but [...] Read more.
The hybrid and the dressed metric formalisms for the study of primordial perturbations in Loop Quantum Cosmology lead to dynamical equations for the modes of these perturbations that are of a generalized harmonic-oscillator type, with a mass that depends on the background but is the same for all modes. For quantum background states that are peaked on trajectories of the effective description of Loop Quantum Cosmology, the main difference between the two considered formalisms is found in the expression of this mass. The value of the mass at the bounce is especially important, since it is only in a short interval around this event that the quantum geometry effects on the perturbations are relevant. In a previous article, the properties of this mass were discussed for an inflaton potential of quadratic form, or with similar characteristics. In the present work, we extend this study to other interesting potentials in cosmology, namely the Starobinsky and the exponential potentials. We prove that there exists a finite interval of values of the potential (which includes the zero but typically goes beyond the sector of kinetically dominated inflaton energy density) for which the hybrid mass is positive at the bounce whereas the dressed metric mass is negative. Full article
(This article belongs to the Special Issue Loop Quantum Gravity: A Themed Issue in Honor of Prof. Abhay Ashtekar)
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