(No) phase transition in tensorial group field theory

Pithis, Andreas G. A.; Thürigen, Johannes

doi:10.48550/arxiv.2007.08982

Cited by 2 publications

(2 citation statements)

References 40 publications

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“…Because of their field theoretic nature, GFTs offer tools and techniques that may prove helpful to tackle the above challenges. For instance, renormalization group techniques can be employed to study the continuum limit of the theory and the possible presence of phase transitions [49][50][51][52]. Alternatively, one could also employ a mean-field approach [53] to effectively describe the macroscopic dynamics (and also the critical behavior [54,55]) of the microscopic quantum gravitational many-body system.…”

Section: Introductionmentioning

confidence: 99%

Effective dynamics of scalar cosmological perturbations from quantum gravity

Marchetti,

Oriti

2021

Preprint

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We derive an effective dynamics for scalar cosmological perturbations from quantum gravity, in the framework of group field theory (GFT) condensate cosmology. The emergent spacetime picture is obtained from the mean field hydrodynamic regime of the fundamental theory, and physical observables are defined using a relational strategy applied at the same level of approximation, in terms of suitable collective states of the GFT field. The dynamical equations we obtain for volume and matter perturbations lead to the same solutions as those of classical general relativity in the long-wavelength, superhorizon limit, but differ in other regimes. These differences could be of phenomenological interest and make contact between fundamental quantum gravity models and cosmological observations, indicating new physics or limitations of the fundamental models or of the approximations leading to the effective cosmological dynamics.

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Section: Introductionmentioning

confidence: 99%

Effective dynamics of scalar cosmological perturbations from quantum gravity

Marchetti,

Oriti

2021

Preprint

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“…New methods are then needed to understand the nonperturbative dynamics of a GFT. One proposal, related to the search for fixed points under renormalisation flow that describe continuum geometry [16], is that a physically relevant continuum phase can be described by a 'condensate' in which the group field acquires a nonvanishing expectation value [17][18][19]. GFT condensates have mostly been studied in a canonical approach in which one works with a Fock space generated by creation and annihilation operators obtained from the group field.…”

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confidence: 99%

Hamiltonian group field theory with multiple scalar matter fields

Gielen,

Polaczek

2020

Preprint

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One approach to defining dynamics for quantum gravity in a naturally timeless setting is to select a suitable matter degree of freedom as a 'clock' before quantisation. This idea of deparametrisation was recently introduced in group field theory leading to a Hamiltonian formulation in which states or operators evolve with respect to the clock given by a free massless scalar field, similar to what happens in deparametrised models in quantum cosmology.Here we extend the construction of Hamiltonian group field theory to models with multiple scalar matter fields, encountering new features and technical subtleties compared with the previously studied case. We show that the effective cosmological dynamics for these more general models reduce to the Friedmann dynamics of general relativity with multiple scalar fields in the limit of large volume, if suitable (non-generic) initial conditions are chosen. At high energy, we find corrections to the classical Friedmann equations whose form is similar to what is found in loop quantum cosmology. These corrections lead to generic singularity resolution by a bounce. The Hamiltonian theory breaks general covariance, specifically covariance under transformations that mix the 'clock' scalar with other scalar fields.

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(No) phase transition in tensorial group field theory

Cited by 2 publications

References 40 publications

Effective dynamics of scalar cosmological perturbations from quantum gravity

Effective dynamics of scalar cosmological perturbations from quantum gravity

Hamiltonian group field theory with multiple scalar matter fields

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