What question did this study set out to answer?

The research aims to evaluate how annealing temperature and structural order influence the anomalous Nernst effect in Fe2CoSi alloys.

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April 10, 2026

Transverse magneto-thermoelectric properties of Fe2CoSi alloy and Fe2CoSi–Pt composite films

Key Points

The research aims to evaluate how annealing temperature and structural order influence the anomalous Nernst effect in Fe2CoSi alloys.
Systematically varied post-deposition annealing temperatures for Fe2CoSi films.
Compared structural order of amorphous and crystalline FCS films.
Explored (FCS)100−xPtx composite films by varying Pt concentration.
Amorphous FCS films showed a larger anomalous Nernst coefficient than crystalline films.
Contrary to Co-based Heusler alloys, higher order in FCS does not enhance the Nernst coefficient.
Enhancing Pt concentration in FCS composites improves transverse thermoelectric performance.

Abstract

We report a systematic evaluation of the effects of post-deposition annealing temperature and structural ordering on the anomalous Nernst effect (ANE) in Fe2CoSi (FCS) Heusler alloy thin films. The study reveals that amorphous/disordered FCS films exhibit a larger anomalous Nernst coefficient (SANE) compared to their crystalline counterparts, in stark contrast to conventional Co-based Heusler alloys, which typically show maximum SANE in highly ordered structures. Furthermore, as a strategy for enhancing transverse thermoelectric properties, we explore the (FCS)100−xPtx composite alloy films by systematically varying the Pt concentration and optimizing the composition. This method effectively enhances the transverse thermoelectric performance of the FCS-based alloys. Our findings offer valuable insights into the design and development of next-generation high-performance ANE materials.

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Transverse magneto-thermoelectric properties of Fe2CoSi alloy and Fe2CoSi–Pt composite films

Key Points

Abstract

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