AI Article Synopsis
- The study explores the terahertz detection capabilities of the two-dimensional antiferromagnetic semimetal NbFeTe, highlighting its unique properties.
- The interaction of antiferromagnetic moments and electron spins leads to a nonlinear increase in the material's responsivity as temperatures drop, facilitated by the use of asymmetric electrodes.
- The NbFeTe₂/graphene heterojunction achieves impressive performance metrics, indicating its potential for high-speed imaging in terahertz applications.
Article Abstract
Effective detection is critical for terahertz applications, yet it remains hindered by the unclear mechanisms that necessitate a deeper understanding of photosensitive materials with exotic physical phenomena. Here, we investigate the terahertz detection capabilities of the two-dimensional antiferromagnetic semimetal NbFeTe. Our study reveals that the interaction between antiferromagnetic magnetic moments and electron spin induces disordered carriers to hop between localized states, resulting in a nonlinear increase in responsivity as temperature decreases. We integrate asymmetric electrodes to generate a sufficient Seebeck potential, enabling carriers to overcome the barrier of localized states and achieve reordering at room temperature. Additionally, the self-powered performance of the NbFeTe₂/graphene heterojunction is optimized by the built-in electric field, achieving peak responsivity of 220 V W and noise equivalent power of <20 pW Hz. These results shed light on the potential of antiferromagnetic semimetals in large-area, high-speed imaging applications, marking a significant advancement in terahertz photonics.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11696399 | PMC |
| http://dx.doi.org/10.1038/s41467-024-55426-0 | DOI Listing |
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