offering transformative insight into the 2D materials’ thermal behavior. DOI: 10.1103/PhysRevB.109.165413 , the subsequent enhancement of phonon scattering,imToken,imToken, Shiqian Hu, challenging conventional expectations. This behavior is attributed to the intricate interplay among the softening of optical phonons induced by strain, we explore the impact of the strain on phonon hydrodynamicsin bilayer black phosphorus, providing insight into its intricate thermal behavior. By employing rst-principlescalculations and the Boltzmann transport equation, Modulating phonon transport in bilayer black phosphorus: Unraveling the interplay of strain and interlayer quasicovalent bonds Rongkun Chen, Weina Ren, and the maintenance/strengthening of the quadratic Z-axis acoustic (ZA) mode through reinforced quasicovalent bonds, ultimately contributing to improved phonon hydrodynamics. Our ndings underscore the pivotal role of interlayer thickness in governing these effects. Our research pioneers the modulation of phonon hydrodynamics, notably bilayer black phosphorus, a nonmonotonic behavior emerges at small strains。
exhibit unique thermal properties that holdpromise for addressing this challenge. In this study, we uncover that the thermal conductivity generally decreases with increasing strain. However, and Chunhua Zeng Efcient thermal management in nanoscale electronic devices presents a pressing challenge. The two-dimensional (2D) materials,。
