Related papers: Physical interpretation of non-normalizable harmonic oscillator states and relaxation to pilot-wave equilibrium

Physical interpretation of non-normalizable harmonic oscillator states and relaxation to pilot-wave equilibrium

URL: http://arxiv.org/abs/2208.08945v4
Date: Sat, 13 Jan 2024 11:30:19 GMT
Title: Physical interpretation of non-normalizable harmonic oscillator states and relaxation to pilot-wave equilibrium
Authors: Indrajit Sen
Abstract summary: We argue that pilot-wave theory gives a straightforward physical interpretation of non-normalizable quantum states. We show that the non-normalizable eigenstates and their superpositions are bound states in the sense that the velocity field $v_y to 0$ at large. We give an explanation of the emergence of quantization in pilot-wave theory in terms of instability of non-normalizable states due to perturbations and environmental interactions.
Score: 0.0
License: http://creativecommons.org/licenses/by-nc-sa/4.0/
Abstract: Non-normalizable states are difficult to interpret in the orthodox quantum formalism but often occur as solutions to physical constraints in quantum gravity. We argue that pilot-wave theory gives a straightforward physical interpretation of non-normalizable quantum states, as the theory requires only a normalized density of configurations to generate statistical predictions. In order to better understand such states, we conduct the first study of non-normalizable solutions of the harmonic oscillator from a pilot-wave perspective. We show that, contrary to intuitions from orthodox quantum mechanics, the non-normalizable eigenstates and their superpositions are bound states in the sense that the velocity field $v_y \to 0$ at large $\pm y$. We argue that defining a physically meaningful equilibrium density for such states requires a new notion of equilibrium, named pilot-wave equilibrium, which is a generalisation of the notion of quantum equilibrium. We define a new $H$-function $H_{pw}$, and prove that a density in pilot-wave equilibrium minimises $H_{pw}$, is equivariant, and remains in equilibrium with time. We prove an $H$-theorem for the coarse-grained $H_{pw}$, under assumptions similar to those for relaxation to quantum equilibrium. We give an explanation of the emergence of quantization in pilot-wave theory in terms of instability of non-normalizable states due to perturbations and environmental interactions. Lastly, we discuss applications in quantum field theory and quantum gravity, and implications for pilot-wave theory and quantum foundations in general.

Related papers

What is "quantum" about quantum gravity? [0.0]
We argue that if both the equivalence principle and quantum mechanics continue to survive experimental tests, that this favors epistemic'' interpretations of quantum mechanics.
arXiv Detail & Related papers (2024-05-13T21:19:50Z)
Generalized Einstein-Podolsky-Rosen Steering Paradox [18.5699135339787]
We present a generalized EPR steering paradox, which predicts a contradictory equality $2_Q=left( 1+deltaright)_C$. We test the paradox through a two-setting steering protocol, and find that the state is steerable if some specific measurement requirements are satisfied. Our construction also enlightens the building of EPR steering inequality, which may contribute to some schemes for typical quantum teleportation and quantum key distributions.
arXiv Detail & Related papers (2024-05-06T01:25:11Z)
Testing Quantum Gravity using Pulsed Optomechanical Systems [13.650870855008112]
We consider the Schr"odinger-Newton (SN) theory and the Correlated Worldline (CWL) theory, and show that they can be distinguished from conventional quantum mechanics. We find that discriminating between the theories will be very difficult until experimental control over low frequency quantum optomechanical systems is pushed further.
arXiv Detail & Related papers (2023-11-03T17:06:57Z)
A Realist Interpretation of Unitarity in Quantum Gravity [0.0]
Unitarity is a difficult concept to implement in canonical quantum gravity because of state non-normalizability and the problem of time. We use the postulate of a definite configuration in the theory to define a global time for the gravitational-fermionic system. We find unitary states in mini-superspace by finding an approximate solution to the Hamiltonian constraint.
arXiv Detail & Related papers (2023-10-23T17:56:28Z)
Real-time dynamics of false vacuum decay [49.1574468325115]
We investigate false vacuum decay of a relativistic scalar field in the metastable minimum of an asymmetric double-well potential. We employ the non-perturbative framework of the two-particle irreducible (2PI) quantum effective action at next-to-leading order in a large-N expansion.
arXiv Detail & Related papers (2023-10-06T12:44:48Z)
Quantum Instability [30.674987397533997]
We show how a time-independent, finite-dimensional quantum system can give rise to a linear instability corresponding to that in the classical system. An unstable quantum system has a richer spectrum and a much longer recurrence time than a stable quantum system.
arXiv Detail & Related papers (2022-08-05T19:53:46Z)
Canonically consistent quantum master equation [68.8204255655161]
We put forth a new class of quantum master equations that correctly reproduce the state of an open quantum system beyond the infinitesimally weak system-bath coupling limit. Our method is based on incorporating the knowledge of the reduced steady state into its dynamics.
arXiv Detail & Related papers (2022-05-25T15:22:52Z)
Quantum dynamics corresponding to chaotic BKL scenario [62.997667081978825]
Quantization smears the gravitational singularity avoiding its localization in the configuration space. Results suggest that the generic singularity of general relativity can be avoided at quantum level.
arXiv Detail & Related papers (2022-04-24T13:32:45Z)
Quantum fluctuation theorem for initial near-equilibrium system [0.0]
Quantum work fluctuation theorem (FT) commonly requires the system initially prepared in an equilibrium state. Here, I initialize the system in a near-equilibrium state, and derive the corresponding modified Jarzynski equality by using the perturbation theory. I also verify my theoretical results by considering a concrete many-body system, and reveal a fundamental connection between quantum critical phenomenon and near-equilibrium state at really high temperature.
arXiv Detail & Related papers (2022-02-15T13:59:42Z)
Quantum Theory of Measurement [0.0]
We describe a quantum mechanical measurement as a variational principle including interaction between the system under measurement and the measurement apparatus. Because the theory is nonlocal, the resulting wave equation is an integrodifferential equation (IDE)
arXiv Detail & Related papers (2021-04-06T01:18:45Z)
Subdiffusive dynamics and critical quantum correlations in a disorder-free localized Kitaev honeycomb model out of equilibrium [0.0]
Disorder-free localization has recently emerged as a mechanism for ergodicity breaking in homogeneous lattice gauge theories. In this work we show that this mechanism can lead to unconventional states of quantum matter as the absence of thermalization lifts constraints imposed by equilibrium statistical physics.
arXiv Detail & Related papers (2020-12-10T15:39:17Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.