Area Scaling of Dynamical Degrees of Freedom in Regularised Scalar Field Theory
- URL: http://arxiv.org/abs/2602.09100v1
- Date: Mon, 09 Feb 2026 19:00:03 GMT
- Title: Area Scaling of Dynamical Degrees of Freedom in Regularised Scalar Field Theory
- Authors: Oliver Friedrich, Kristina Giesel, Varun Kushwaha,
- Abstract summary: How many canonical degrees of freedom does a quantum field theory actually use during its Hamiltonian evolution?<n>We show that for the free scalar field this minimal dimension is controlled not by the volume-extensive number of field variables, but by the much smaller number of distinct normal-mode frequencies below the ultraviolet cutoff.<n>Our results provide a controlled field-theoretic setting in which area-type scaling and overlap phenomena can be studied prior to quantisation.
- Score: 0.025489046505746706
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: How many canonical degrees of freedom does a quantum field theory actually use during its Hamiltonian evolution? For a UV/IR-regularised classical scalar field, we address this question directly at the level of phase-space dynamics by identifying the minimal symplectic dimension required to reproduce a single trajectory by an autonomous Hamiltonian system. Using symplectic model order reduction as a structure-preserving diagnostic, we show that for the free scalar field this minimal dimension is controlled not by the volume-extensive number of discretised field variables, but by the much smaller number of distinct normal-mode frequencies below the ultraviolet cutoff. In flat space, this leads to an area-type scaling with the size of the region, up to slowly varying corrections. On geodesic balls in maximally symmetric curved spaces, positive curvature induces mild super-area growth, while negative curvature suppresses the scaling, with the flat result recovered smoothly in the small-curvature limit. Numerical experiments further indicate that this behaviour persists in weakly interacting $λφ^4$ theory over quasi-integrable time scales. Beyond counting, the reduced dynamics exhibits a distinctive internal structure: it decomposes into independent oscillator blocks, while linear combinations of these blocks generate a larger family of apparent field modes whose Poisson brackets are governed by a projector rather than the identity. This reveals a purely classical and dynamical mechanism by which overlapping degrees of freedom arise, without modifying canonical structures by hand. Our results provide a controlled field-theoretic setting in which area-type scaling and overlap phenomena can be studied prior to quantisation, helping to identify which aspects of such structures--often discussed in holographic contexts--can already arise from classical Hamiltonian dynamics.
Related papers
- Propagation of Chaos in One-hidden-layer Neural Networks beyond Logarithmic Time [46.15741640288809]
We study the approximation gap between the dynamics of a-width neural network and its infinite-width counterpart.<n>We demonstrate how to tightly bound this approximation gap through a differential equation governed by the mean-field dynamics.
arXiv Detail & Related papers (2025-04-17T17:24:38Z) - Long-time soliton dynamics via a coarse-grained space-time method [7.743463245493229]
We extend a coarse-graining method to spacetime using a dual-mesh construction based on the Minkowski-metric.<n>We uncover long-lived bound states - "Schwinger atoms" - in which a soliton is trapped by a fixed central charge.<n>Our results also suggest the possibility of quantum simulation of relativistic quantum field theories.
arXiv Detail & Related papers (2025-04-16T17:51:51Z) - Hilbert space fragmentation at the origin of disorder-free localization in the lattice Schwinger model [0.0]
Recent works have reported the possibility of disorder-free localization in the lattice Schwinger model.<n>We perform a detailed characterization of thermalization breakdown in the Schwinger model.<n>We identify the origin of this ultraslow growth of entanglement as due to approximate Hilbert space fragmentation.
arXiv Detail & Related papers (2024-09-12T18:00:00Z) - Anomalous localization in spin chains with tilted interactions [0.0]
lattice gauge theories involve dynamics of typically short-ranged interacting particles and dynamical fields.
We consider localization properties of a spin chain with interaction strength growing linearly along the chain as for the Schwinger model.
Our study is relevant for quantum simulators of lattice gauge theories implemented in state-of-the-art cold atom/ion devices.
arXiv Detail & Related papers (2024-01-25T18:16:52Z) - Hilbert space fragmentation and slow dynamics in particle-conserving
quantum East models [0.0]
We introduce a hitherto unexplored family of kinetically constrained models featuring a conserved particle number.
We reproduce the logarithmic dynamics observed in the quantum case using a classically simulable cellular automaton.
arXiv Detail & Related papers (2022-10-27T16:50:27Z) - Slow semiclassical dynamics of a two-dimensional Hubbard model in
disorder-free potentials [77.34726150561087]
We show that introduction of harmonic and spin-dependent linear potentials sufficiently validates fTWA for longer times.
In particular, we focus on a finite two-dimensional system and show that at intermediate linear potential strength, the addition of a harmonic potential and spin dependence of the tilt, results in subdiffusive dynamics.
arXiv Detail & Related papers (2022-10-03T16:51:25Z) - Decimation technique for open quantum systems: a case study with
driven-dissipative bosonic chains [62.997667081978825]
Unavoidable coupling of quantum systems to external degrees of freedom leads to dissipative (non-unitary) dynamics.
We introduce a method to deal with these systems based on the calculation of (dissipative) lattice Green's function.
We illustrate the power of this method with several examples of driven-dissipative bosonic chains of increasing complexity.
arXiv Detail & Related papers (2022-02-15T19:00:09Z) - Geometry of rare regions behind Griffiths singularities in random
quantum magnets [0.0]
We study the geometrical properties of rare regions in the transverse Ising model with dilution or with random couplings and transverse fields.
For the diluted model they are isotropic and tree-like, while for the random model they are quasi-one-dimensional.
arXiv Detail & Related papers (2022-01-18T15:58:52Z) - Rotating Majorana Zero Modes in a disk geometry [75.34254292381189]
We study the manipulation of Majorana zero modes in a thin disk made from a $p$-wave superconductor.
We analyze the second-order topological corner modes that arise when an in-plane magnetic field is applied.
We show that oscillations persist even in the adiabatic phase because of a frequency independent coupling between zero modes and excited states.
arXiv Detail & Related papers (2021-09-08T11:18:50Z) - Quantum anomalous Hall phase in synthetic bilayers via twistless
twistronics [58.720142291102135]
We propose quantum simulators of "twistronic-like" physics based on ultracold atoms and syntheticdimensions.
We show that our system exhibits topologicalband structures under appropriate conditions.
arXiv Detail & Related papers (2020-08-06T19:58:05Z) - The role of boundary conditions in quantum computations of scattering
observables [58.720142291102135]
Quantum computing may offer the opportunity to simulate strongly-interacting field theories, such as quantum chromodynamics, with physical time evolution.
As with present-day calculations, quantum computation strategies still require the restriction to a finite system size.
We quantify the volume effects for various $1+1$D Minkowski-signature quantities and show that these can be a significant source of systematic uncertainty.
arXiv Detail & Related papers (2020-07-01T17:43:11Z)
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.