Nonlinear unitary quantum collapse model with self-generated noise

TL;DR

This paper introduces a deterministic nonlinear quantum collapse model that explains measurement outcomes through self-generated noise, reproducing quantum statistics without external noise or environmental decoherence.

Contribution

The paper presents a novel nonlinear, noise-free quantum collapse model with deterministic dynamics, where randomness emerges from detector behavior, aligning with quantum statistical predictions.

Findings

Reproduces Born's rule through stochastic modeling

Shows collapse dynamics without external noise

Maintains non-signaling at the statistical level

Abstract

Collapse models including some external noise of unknown origin are routinely used to describe phenomena on the quantum-classical border; in particular, quantum measurement. Although containing nonlinear dynamics and thereby exposed to the possibility of superluminal signaling in individual events, such models are widely accepted on the basis of fully reproducing the non-signaling statistical predictions of quantum mechanics. Here we present a deterministic nonlinear model without any external noise, in which randomness - instead of being universally present - emerges in the measurement process, from deterministic irregular dynamics of the detectors. The treatment is based on a minimally nonlinear von Neumann equation for a Stern-Gerlach or Bell-type measuring setup, containing coordinate and momentum operators in a self-adjoint skew-symmetric, split scalar product structure over the configuration space. The microscopic states of the detectors act as a nonlocal set of hidden parameters, controlling individual outcomes. The model is shown to display pumping of weights between setup-defined basis states, with a single winner randomly selected and the rest collapsing to zero. Environmental decoherence has no role in the scenario. Through stochastic modelling, based on Pearle's "gambler's ruin" scheme, outcome probabilities are shown to obey Born's rule under a no-drift or "fair-game" condition. This fully reproduces quantum statistical predictions, implying that the proposed non-linear deterministic model satisfies the non-signaling requirement. Our treatment is still vulnerable to hidden signaling in individual events, which remains to be handled by future research.