A gravitationally induced decoherence model using Ashtekar variables

It is shown that the non-unitary Newtonian gravity (NNG) model admits a simple interpretation in terms of the Feynman path integral, in which the sum over all possible histories is replaced by a summation over pairs of paths. Correlations between different paths are allowed by a fundamental decoherence mechanism of gravitational origin and can be interpreted as a kind of communication between different branches of the wave function. The ensuing formulation could be used in turn as a motivation to introduce non-unitary gravity itself.

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“…See for instance the model in Ref. [30], inspired by loop quantum gravity and constructed in terms of Ashtekar variables.…”

Section: Introductionmentioning

confidence: 99%

Interaction between Everett Worlds and Fundamental Decoherence in Non-Unitary Newtonian Gravity

Maimone¹,

Naddeo

Scelza³

2023

Universe

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Hamiltonian Theory: Dynamics

Thiemann,

Giesel

2023

Handbook of Quantum Gravity

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Positivity and Entanglement of Polynomial Gaussian Integral Operators

Balka,

Csordás,

Homa

2024

Progress of Theoretical and Experimental Physics

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Positivity preservation is an important issue in the dynamics of open quantum systems: positivity violations always mark the border of validity of the model. We investigate the positivity of self-adjoint polynomial Gaussian integral operators $\widehat{\kappa }_{\operatorname{PG}}$, that is, the multivariable kernel $\kappa _{\operatorname{PG}}$ is a product of a polynomial P and a Gaussian kernel κG. These operators frequently appear in open quantum systems. We show that $\widehat{\kappa }_{\operatorname{PG}}$ can be only positive if the Gaussian part is positive, which yields a strong and quite easy test for positivity. This has an important corollary for the bipartite entanglement of the density operators $\widehat{\kappa }_{\operatorname{PG}}$: if the Gaussian density operator $\widehat{\kappa }_G$ fails the Peres–Horodecki criterion, then the corresponding polynomial Gaussian density operators $\widehat{\kappa }_{\operatorname{PG}}$ also fail the criterion for all P, hence they are all entangled. We prove that polynomial Gaussian operators with polynomials of odd degree cannot be positive semidefinite. We introduce a new preorder ≼ on Gaussian kernels such that if $\kappa _{G_0}\preceq \kappa _{G_1}$ then $\widehat{\kappa }_{\operatorname{PG}_0}\ge 0$ implies $\widehat{\kappa }_{\operatorname{PG}_1}\ge 0$ for all polynomials P. Therefore, deciding the positivity of a polynomial Gaussian operator determines the positivity of a lot of another polynomial Gaussian operators having the same polynomial factor, which might improve any given positivity test by carrying it out on a much larger set of operators. We will show an example that this really can make positivity tests much more sensitive and efficient. This preorder has implication for the entanglement problem, too.

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A gravitationally induced decoherence model using Ashtekar variables

Cited by 7 publications

References 119 publications

Interaction between Everett Worlds and Fundamental Decoherence in Non-Unitary Newtonian Gravity

Interaction between Everett Worlds and Fundamental Decoherence in Non-Unitary Newtonian Gravity

Hamiltonian Theory: Dynamics

Positivity and Entanglement of Polynomial Gaussian Integral Operators

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