Temperonic Crystal: a superlattice for temperature waves in graphene

TL;DR

This paper introduces the concept of a temperonic crystal, a superlattice structure in graphene that enables the control of ultrafast temperature waves, with tunable frequency gaps demonstrated through dispersion analysis.

Contribution

It presents the first theoretical framework for a temperonic crystal in graphene, extending superlattice concepts to temperature wave manipulation at ultrafast timescales.

Findings

Dispersion relation reveals tunable frequency gaps.

Graphene-based temperonic crystal supports temperature wave control.

Potential for ultrafast thermal management in hydrodynamic regime.

Abstract

The temperonic crystal, a periodic structure with a unit cell made of two slabs sustaining temperature wave-like oscillations on short time-scales, is introduced. The complex-valued dispersion relation for the temperature scalar field is investigated for the case of a localised temperature pulse. The dispersion discloses frequency gaps, tunable upon varying the slabs thermal properties. Results are shown for the paradigmatic case of a graphene-based temperonic crystal. The temperonic crystal extends the concept of superlattices to the realm of temperature waves, allowing for coherent control of ultrafast temperature pulses in the hydrodynamic regime at above liquid nitrogen temperatures.