Giant room-temperature spin caloritronics in spin-semiconducting graphene nanoribbons

Abstract

Spin caloritronics refers to generating spin current by thermal gradient. Here we report a theoretical study demonstrating giant spin caloritronic effects in a new class of materials, called spin semiconductors, which are characterized with a ``spin gap,'' the energy gap between spin-up and -down channels. Generally, spin Seebeck coefficient (${S}_{s}$) is shown to increase linearly with the spin gap. Specifically, unprecedented large ${S}_{s}\ensuremath{\sim}3.4$ mV/K and spin figure of merit ${Z}_{s}T\ensuremath{\sim}119$ were found in spin-semiconducting graphene nanoribbons (GNRs) with sawtooth (ST) zigzag edges, based on first-principles calculations. Such giant spin caloritronic effects are shown to originate from a large spin gap of ST GNRs, in addition to two other spin-independent features of large band gap and narrow bandwidth which are commonly known for good thermoelectric materials. Our studies suggest that spin-semiconducting nanostructures, such as ST GNRs, are promising candidates for room-temperature spin caloritronics with high efficiency.