Hamiltonian constraint of loop quantum cosmology

We consider the loop quantization of the (diagonal) Bianchi type IX cosmological model. We explore different quantization prescriptions that extend the work of Wilson-Ewing and Singh. In particular, we study two different ways of implementing the so-called inverse triad corrections. We construct the corresponding Hamiltonian constraint operators and show that the singularity is formally resolved. We find the effective equations associated with the different quantization prescriptions, and study the relation with the isotropic [Formula: see text] model that, classically, is contained within the Bianchi IX model. Somewhat surprisingly, we find the most natural quantization does not reduce to the [Formula: see text] model. We use geometrically defined scalar observables to explore the physical implications of each of these theories. This is the first part in a series of papers analyzing different aspects of the Bianchi IX model, with inverse corrections, within loop quantum cosmology (LQC).

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Separate universes in loop quantum cosmology: Framework and applications

International Journal of Modern Physics D ◽

10.1142/s0218271816420025 ◽

2016 ◽

Vol 25 (08) ◽

pp. 1642002 ◽

Cited By ~ 13

Author(s):

Edward Wilson-Ewing

Keyword(s):

Perturbation Theory ◽

Equation Of State ◽

Quantum Cosmology ◽

Matter Field ◽

Loop Quantum Cosmology ◽

Hamiltonian Constraint ◽

Cosmological Perturbation ◽

Cosmological Perturbation Theory ◽

Long Wavelength ◽

Gravity Effects

I present a streamlined review of how the separate universe approach to cosmological perturbation theory can be used to study the dynamics of long-wavelength scalar perturbations in loop quantum cosmology (LQC), and then use it to calculate how long-wavelength curvature perturbations evolve across the LQC bounce assuming a constant equation of state. A similar calculation is possible for tensor modes using results from a complementary approach to cosmological perturbation theory in LQC based on an effective Hamiltonian constraint. An interesting result is that the tensor-to-scalar ratio can be suppressed or amplified by quantum gravity effects during the bounce, depending on the equation of state of the matter field dominating the dynamics. In particular, if the equation of state lies between [Formula: see text] and [Formula: see text], the value of the tensor-to-scalar ratio will be suppressed during the bounce, in some cases significantly.

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COHERENT STATE FUNCTIONAL INTEGRAL IN LOOP QUANTUM COSMOLOGY: ALTERNATIVE DYNAMICS

Modern Physics Letters A ◽

10.1142/s0217732312500782 ◽

2012 ◽

Vol 27 (15) ◽

pp. 1250078 ◽

Cited By ~ 16

Author(s):

LI QIN ◽

YONGGE MA

Keyword(s):

Coherent State ◽

Quantum Cosmology ◽

Quantum Dynamics ◽

Large Scale ◽

Friedmann Equation ◽

Transition Amplitude ◽

Functional Integral ◽

Effective Theory ◽

Loop Quantum Cosmology ◽

Hamiltonian Constraint

Coherent state functional integral for the minisuperspace model of loop quantum cosmology is studied. By the well-established canonical theory, the transition amplitude in the path integral representation of loop quantum cosmology with alternative dynamics can be formulated through group averaging. The effective action and Hamiltonian with higher-order quantum corrections are thus obtained. It turns out that for a nonsymmetric Hamiltonian constraint operator, the Moyal (star)-product emerges naturally in the effective Hamiltonian. For the corresponding symmetric Hamiltonian operator, the resulted effective theory implies a possible quantum cosmological effect in large scale limit in the alternative dynamical scenario, which coincides with the result in canonical approach. Moreover, the first-order modified Friedmann equation still contains the particular information of alternative dynamics and hence admits the possible phenomenological distinction between the different proposals of quantum dynamics.

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(2+1)-dimensional loop quantum cosmology of Bianchi I models

International Journal of Modern Physics A ◽

10.1142/s0217751x20501857 ◽

2020 ◽

Vol 35 (29) ◽

pp. 2050185

Author(s):

You Ding ◽

Xiangdong Zhang

Keyword(s):

Quantum Cosmology ◽

Friedmann Equation ◽

Internal Clock ◽

Massless Scalar ◽

Loop Quantum Cosmology ◽

Hamiltonian Constraint ◽

Massless Scalar Field ◽

Four Dimensions ◽

Bianchi I ◽

Time Variables

We study the anisotropic Bianchi I loop quantum cosmology in [Formula: see text] dimensions. The [Formula: see text] scheme is considered in the present paper and the following expected results are established: (i) the massless scalar field again play the role of emergent time variables and serves as an internal clock; (ii) by imposing the fundamental discreteness of length operator, the total Hamiltonian constraint is obtained and gives rise the evolution as a difference equation; and (iii) the exact solutions of Friedmann equation are constructed rigorously for both classical and effective level. The investigation extends the domain of validity of loop quantum cosmology to beyond the four dimensions.

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Hybrid models in loop quantum cosmology

International Journal of Modern Physics D ◽

10.1142/s0218271816420074 ◽

2016 ◽

Vol 25 (08) ◽

pp. 1642007 ◽

Cited By ~ 21

Author(s):

Beatriz Elizaga Navascués ◽

Mercedes Martín-Benito ◽

Guillermo A. Mena Marugán

Keyword(s):

Quantum Cosmology ◽

Degrees Of Freedom ◽

Hybrid Approach ◽

Loop Quantum Cosmology ◽

Hamiltonian Constraint ◽

Hybrid Strategy ◽

Fock Representation ◽

Zero Modes ◽

Inhomogeneous Models ◽

Global Zero

In the framework of Loop Quantum Cosmology (LQC), inhomogeneous models are usually quantized by means of a hybrid approach that combines loop quantization techniques with standard quantum field theory methods. This approach is based on a splitting of the phase space in a homogeneous sector, formed by global, zero-modes and an inhomogeneous sector, formed by the remaining, infinite number of modes, that describe the local degrees of freedom. Then, the hybrid quantization is attained by adopting a loop representation for the homogeneous gravitational sector, while a Fock representation is used for the inhomogeneities. The zero-mode of the Hamiltonian constraint operator couples the homogeneous and inhomogeneous sectors. The hybrid approach, therefore, is expected to provide a suitable quantum theory in regimes where the main quantum effects of the geometry are those affecting the zero-modes, while the inhomogeneities, still being quantum, can be treated in a more conventional way. This hybrid strategy was first proposed for the simplest cosmological midisuperspaces: the Gowdy models, and it has been later applied to the case of cosmological perturbations. This paper reviews the construction and main applications of hybrid LQC.

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Supersymmetric minisuperspace models in self-dual loop quantum cosmology

Journal of High Energy Physics ◽

10.1007/jhep03(2021)064 ◽

2021 ◽

Vol 2021 (3) ◽

Author(s):

K. Eder ◽

H. Sahlmann

Keyword(s):

Quantum Theory ◽

Quantum Cosmology ◽

Natural State ◽

Loop Quantum Cosmology ◽

Hamiltonian Constraint ◽

Dual Variables ◽

Left And Right ◽

Constraint Algebra ◽

Gravitino Field ◽

Supersymmetric Approach

Abstract In this paper, we study a class of symmetry reduced models of $$ \mathcal{N} $$ N = 1 super- gravity using self-dual variables. It is based on a particular Ansatz for the gravitino field as proposed by D’Eath et al. We show that the essential part of the constraint algebra in the classical theory closes. In particular, the (graded) Poisson bracket between the left and right supersymmetry constraint reproduces the Hamiltonian constraint.For the quantum theory, we apply techniques from the manifestly supersymmetric approach to loop quantum supergravity, which yields a graded analog of the holonomy-flux algebra and a natural state space.We implement the remaining constraints in the quantum theory. For a certain subclass of these models, we show explicitly that the (graded) commutator of the supersymmetry constraints exactly reproduces the classical Poisson relations. In particular, the trace of the commutator of left and right supersymmetry constraints reproduces the Hamilton constraint operator. Finally, we consider the dynamics of the theory and compare it to a quantization using standard variables and standard minisuperspace techniques.

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