What question did this study set out to answer?

The research aims to understand the thermal behavior of exchange stiffness and damping in Co2MnGa thin films.

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February 27, 2026

Thermal evolution of exchange stiffness and Gilbert damping in magnetic Weyl semimetal Co 2 MnGa thin films

Key Points

The research aims to understand the thermal behavior of exchange stiffness and damping in Co2MnGa thin films.
Utilized ferromagnetic resonance spectroscopy to analyze CMG thin films.
Investigated temperature effects on exchange stiffness and Gilbert damping.
Compared different thicknesses of thin films to assess damping behaviors.
Revealed that exchange stiffness is primarily influenced by electron-magnon interactions.
Demonstrated ultralow Gilbert damping at room temperature across all film thicknesses.
The thickest film exhibited temperature-independent damping down to 10 K.

Abstract

Magnetic Weyl semimetals such as Co2MnGa (CMG) are promising candidates for next-generation spintronic materials due to their exotic topological properties. Using ferromagnetic resonance spectroscopy, the authors investigate CMG thin films, revealing that the thermal evolution of the exchange stiffness is dominated by electron-magnon interactions. Furthermore, they demonstrate ultralow damping at room temperature in all the films, with the thickest film showing a temperature-independent damping behavior down to 10 K. These results highlight CMG's potential for efficient room-temperature and cryogenic magnonic circuits and provide critical parameters for micromagnetic modeling to support device engineering.

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