Maximizing bipolar sensitivity for anomalous Nernst thermopiles in heat flux sensing in amorphous GdCo alloys

A Heat Flux Sensor (HFS) facilitates the visualization of heat flow, unlike a temperature sensor, and is anticipated to be a key technology in managing waste heat. Recently, an HFS utilizing the Anomalous Nernst Effect (ANE) has been proposed garnering significant interest in enhancing the transverse Seebeck coefficient. However, ideal materials for HFS not only require a large transverse Seebeck coefficient but also meet several criteria including low thermal conductivity and a bipolar nature of the transverse Seebeck coefficient, especially a negative coefficient. In this study, we have investigated ANE in amorphous ferrimagnetic GdCo alloys, revealing their numerous advantages as HFS materials. These include a large transverse Seebeck coefficient, extremely low thermal conductivity, large negative sensitivity, unparalleled bipolar sensitivity, versatility for deposition on various substrates, and a small longitudinal Seebeck coefficient. These qualities position GdCo films as promising candidates for the advancement of HFS technology.