Sensor free, self regulating thermal switching via anomalous Ettingshausen effect and spin reorientation in DyCo5
Abstract: We propose a sensor free, self regulating thermal switch that combines the anomalous Ettingshausen effect (AEE) with a temperature driven spin reorientation transition (SRT) in the rare earth cobalt compound DyCo$5$. Using density functional theory and the Kubo linear-response formalism, we compute the anomalous Hall conductivity $σ{xy}(\varepsilon)$ and the finite temperature anomalous Nernst conductivity $α{xy}(T)$ for two magnetization directions, magnetization parallel and perpendicular to the crystallographic c axis. While the intrinsic $σ{xy}$ at the Fermi level remains sizable for both orientations, $α{xy}$ exhibits an about two orders of magnitude contrast in the SRT temperature window. This contrast is consistent with the low temperature Mott relation through the energy slope $\partial\varepsilon σ{xy}(\varepsilon)\rvert{E_{\mathrm F}}$ and is traced to strongly peaked Berry curvature hot spots generated by spin orbit coupling induced avoided crossings of Co $3d$ bands. Combining $α{xy}$ with longitudinal transport coefficients, we estimate device level metrics, namely the anomalous Nernst thermopower $S{\mathrm{ANE}}$ and the Ettingshausen coefficient $Π{\mathrm{AEE}}=T S{\mathrm{ANE}}$, and demonstrate robust orientation controlled switching under a fixed in plane bias current. These results establish a materials based route to compact thermal control without external sensors or feedback electronics and provide a concrete example that the proposed principle can be realized in an existing ferromagnet.
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