Context-Dependent Time-Energy Uncertainty Relations from Projective Quantum Measurements

TL;DR

This paper develops a measurement-dependent framework for defining time distributions in quantum systems, leading to new time-energy uncertainty relations applicable across various quantum platforms.

Contribution

It introduces a general framework for context-dependent quantum time distributions using projective measurements, unifying timing observables and deriving new uncertainty relations.

Findings

Derived a time-energy uncertainty relation involving population transfer

Applied the framework to a time-of-arrival and a driven three-level system

Demonstrated the measurement-dependent nature of quantum timing uncertainties

Abstract

We introduce a general framework for defining context-dependent time distributions in quantum systems using projective measurements. The time-of-flow (TF) distribution, derived from population transfer rates into a measurement subspace, yields a time--energy uncertainty relation of the form $\Delta \mathcal{T} \cdot \Delta H \geq \hbar / (6\sqrt{3}) \cdot \delta\theta$, where $\delta\theta$ quantifies net population transfer. This bound applies to arbitrary projectors under unitary dynamics and reveals that time uncertainty is inherently measurement-dependent. We demonstrate the framework with two applications: a general time-of-arrival (TOA)-energy uncertainty relation and a driven three-level system under detuned coherent driving. The TF framework unifies timing observables across spin, atomic, and matter-wave systems, and offers an experimentally accessible route to probing quantum timing in controlled measurements.