Kinetic Uncertainty Relations for Quantum Transport
Didrik Palmqvist, Ludovico Tesser, Janine Splettstoesser
Abstract
We analyze the precision of generic currents in a multiterminal quantum-transport setting. Employing scattering theory, we show that the precision of such currents is limited by a function of the particle-current noise that can be interpreted as the activity in the classical limit. We thereby establish a kinetic uncertainty relation for quantum transport. In the full quantum limit, we find precision bounds with modified activity constraints depending on whether the system is fermionic or bosonic. We expect these bounds to be suitable as guidelines for any transport process aiming at high precision.
Topics & Concepts
PhysicsQuantumStatistical physicsKinetic energyNoise (video)Function (biology)ScatteringQuantum fluctuationProcess (computing)Quantum mechanicsRelation (database)Quantum systemQuantum processQuantum operationUpper and lower boundsCurrent (fluid)Quantum algorithmClassical mechanicsQuantum metrologyScattering theoryMeasure (data warehouse)Quantum electrodynamicsUncertainty principleAdvanced Thermodynamics and Statistical MechanicsThermal properties of materialsQuantum Mechanics and Applications