Lattice tuning of charge and spin transport in $β_{12}$-borophene nanoribbons
Abstract
Lattice vibrations critically shape charge and spin transport by governing carrier scattering, spin-charge interactions and spectral redistribution in nanostructures. In this study, we investigate how electron-phonon coupling (EPC) and structural configurations intertwine in magnetic and nonmagnetic $\beta_{12}$-borophene nanoribbons (BNRs). Using a tight-binding framework with site-dependent hopping parameters extracted from ab initio calculations and incorporating phonons within the Holstein model, we compute phonon-renormalized Green's functions and transport currents via the Landauer-B\"{u}ttiker formalism. We find that spin-dependent EPC enhances spin-dependent current in magnetic zigzag (ZZ) nanoribbons, driven by phonon-induced inelastic scattering and spin-selective band renormalization. Additionally, we observe an enhancement of charge transport current in the nonmagnetic configurations of $\beta_{12}$-BNRs. Structural variations further induce anisotropic EPC effects, significantly reshaping charge and spin transport. These insights establish EPC as a powerful design lever for optimizing borophene-based logic devices through tailored edge engineering.