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Stronger Interlayer Interactions Contribute to Faster Hot Carrier Cooling of Bilayer Graphene under Pressure

Kun Ni, Jinxiang Du, Jin Yang, Shujuan Xu, Xin Cong, Na Shu, Kai Zhang, Aolei Wang, Fei Wang, Liangbing Ge, Jin Zhao, Yan Qu, Kostya S. Novoselov, Ping‐Heng Tan, Fuhai Su, Yanwu Zhu

2021Physical Review Letters40 citationsDOI

Abstract

We perform femtosecond pump-probe spectroscopy to in situ investigate the ultrafast photocarrier dynamics in bilayer graphene and observe an acceleration of energy relaxation under pressure. In combination with in situ Raman spectroscopy and ab initio molecular dynamics simulations, we reveal that interlayer shear and breathing modes have significant contributions to the faster hot-carrier relaxations by coupling with the in-plane vibration modes under pressure. Our work suggests that further understanding the effect of interlayer interaction on the behaviors of electrons and phonons would be critical to tailor the photocarrier dynamic properties of bilayer graphene.

Topics & Concepts

Materials scienceRaman spectroscopyGrapheneFemtosecondPhononBilayer grapheneBilayerRelaxation (psychology)SpectroscopyElectronMolecular dynamicsCondensed matter physicsChemical physicsMolecular physicsLaserNanotechnologyOpticsChemistryPhysicsComputational chemistrySocial psychologyPsychologyQuantum mechanicsBiochemistryMembraneGraphene research and applicationsNanowire Synthesis and ApplicationsThermal properties of materials
Stronger Interlayer Interactions Contribute to Faster Hot Carrier Cooling of Bilayer Graphene under Pressure | Litcius