Kinematical Hilbert spaces for fermionic and Higgs quantum field theories

Fermions play a special role in homogeneous models of quantum cosmology because the exclusion principle prevents them from forming sizable matter contributions. They can thus describe the matter ingredients only truly microscopically and it is not possible to avoid strong quantum regimes by positing a large matter content. Moreover, possible parity violating effects are important especially in loop quantum cosmology whose basic object is a difference equation for the wave function of the universe defined on a discrete space of triads. The two orientations of a triad are interchanged by a parity transformation, which leaves the difference equation invariant for ordinary matter. Here, we revisit and extend loop quantum cosmology by introducing fermions and the gravitational torsion they imply, which renders the parity issue non-trivial. A treatable locally rotationally symmetric Bianchi model is introduced which clearly shows the role of parity. General wave functions cannot be parity-even or odd, and parity violating effects in matter influence the microscopic big bang transition which replaces the classical singularity in loop quantum cosmology.

Section: B Torsion Effectssupporting

confidence: 88%

Fermions in loop quantum cosmology and the role of parity

Bojowald

Das

2008

“…Consider, for example, the coupling of fermion fields in the LQG setting [119,125]. The starting point is the classical continuum action of a Dirac fermion coupled to gravity…”

Section: Coupling To Matter Fieldsmentioning

confidence: 99%

Loop quantum gravity: an outside view

Nicolai

Peeters

Zamaklar

2005

215

319

Abstract:We review aspects of loop quantum gravity in a pedagogical manner, with the aim of enabling a precise but critical assessment of its achievements so far. We emphasise that the off-shell ('strong') closure of the constraint algebra is a crucial test of quantum space-time covariance, and thereby of the consistency, of the theory. Special attention is paid to the appearance of a large number of ambiguities, in particular in the formulation of the Hamiltonian constraint. Developing suitable approximation methods to establish a connection with classical gravity on the one hand, and with the physics of elementary particles on the other, remains a major challenge.

“…This technique can be applied, in particular, to the standard model coupled to gravity [24,25] and to the Poincaré generators at spatial infinity [26]. In particular, it works for Lorentzian gravity while all earlier proposals could at best work in the Euclidean context only (see, e.g.…”

Section: Iii) Regularization-and Renormalization Techniquesmentioning

confidence: 99%

Gauge field theory coherent states (GCS): III. Ehrenfest theorems

Thiemann¹,

Winkler²

2001

Self Cite

139

274

In the preceding paper of this series of articles we established peakedness properties of a family of coherent states that were introduced by Hall for any compact gauge group and were later generalized to gauge field theory by Ashtekar, Lewandowski, Marolf, Mourão and Thiemann.In this paper we establish the "Ehrenfest Property" of these states which are labelled by a point (A, E), a connection and an electric field, in the classical phase space. By this we mean that i) The expectation value of all elementary quantum operatorsÔ with respect to the coherent state with label (A, E) is given to zeroth order inh by the value of the corresponding classical function O evaluated at the phase space point (A, E) and ii) The expectation value of the commutator between two elementary quantum operators [Ô 1 ,Ô 2 ]/(ih) divided by ih with respect to the coherent state with label (A, E) is given to zeroth order inh by the value of the Poisson bracket between the corresponding classical functions {O 1 , O 2 } evaluated at the phase space point (A, E).These results can be extended to all polynomials of elementary operators and to a certain non-polynomial function of the elementary operators associated with the volume operator of quantum general relativity. It follows that the infinitesimal quantum dynamics of quantum general relativity is to zeroth order inh indeed given by classical general relativity.