High-Field Nonlinear Terahertz Conductivities of Iron Ultrathin Films.

IF 4.3 3区材料科学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Nanomaterials Pub Date : 2025-09-09 DOI:10.3390/nano15181386

Lewen Zhu, Zhiqiang Lan, Yingyu Guo, Danni Li, Lin Xi, Huiping Zhang, Zuanming Jin

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Abstract

The electronic transport behavior in ferromagnetic thin films critically dictates the functionality and efficiency of devices in spintronics and modern materials science. This work characterizes terahertz (THz) responses and nonlinear conductivities of Fe ultrathin films under high-field THz excitation. We demonstrated that different nonlinearities are present for two different thickness samples. For a 2 nm thick Fe film, as the peak THz electric field was increased to 369 kV/cm, the THz transmittance of Fe films generally decreased. However, for the 4 nm thick Fe film, the THz transmittance is almost field strength independent. This result is correlated with the conductivity variations induced by carrier transport processes. The real part of the complex conductivity for the 2 nm thick film increased significantly with the THz electric field, while the 4 nm thick film showed negligible dependence. In addition, we extracted the frequency-domain complex conductivity of the Fe thin films and used the Drude or Drude-Smith model to explain the distinct behaviors between the two thickness samples under intense THz fields, mainly associated with the surface morphology. This work aims to elucidate the transport properties of Fe films in the THz frequency range. Our findings lay a crucial foundation for the design and development of future high-performance THz spintronic functional devices.

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铁超薄膜的高场非线性太赫兹电导率。

铁磁薄膜中的电子输运行为决定了自旋电子学和现代材料科学中器件的功能和效率。本文研究了铁超薄膜在高场太赫兹激励下的太赫兹响应和非线性电导率。我们证明了两种不同厚度的样品存在不同的非线性。对于2 nm厚的Fe薄膜，当峰值太赫兹电场增大到369 kV/cm时，Fe薄膜的太赫兹透过率普遍降低。然而，对于4 nm厚的Fe薄膜，太赫兹透过率几乎与场强无关。这一结果与载流子输运过程引起的电导率变化有关。2 nm厚薄膜的复电导率实部随太赫兹电场的增大而显著增大，而4 nm厚薄膜的复电导率实部随太赫兹电场的增大而变化不大。此外，我们提取了Fe薄膜的频域复电导率，并使用Drude或Drude- smith模型解释了两种厚度样品在强太赫兹场下的不同行为，主要与表面形貌有关。本工作旨在阐明铁薄膜在太赫兹频率范围内的输运特性。我们的发现为未来高性能太赫兹自旋电子功能器件的设计和开发奠定了重要的基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Nanomaterials NANOSCIENCE & NANOTECHNOLOGY-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

8.50

自引率

9.40%

发文量

3841

审稿时长

14.22 days

期刊介绍： Nanomaterials (ISSN 2076-4991) is an international and interdisciplinary scholarly open access journal. It publishes reviews, regular research papers, communications, and short notes that are relevant to any field of study that involves nanomaterials, with respect to their science and application. Thus, theoretical and experimental articles will be accepted, along with articles that deal with the synthesis and use of nanomaterials. Articles that synthesize information from multiple fields, and which place discoveries within a broader context, will be preferred. There is no restriction on the length of the papers. Our aim is to encourage scientists to publish their experimental and theoretical research in as much detail as possible. Full experimental or methodical details, or both, must be provided for research articles. Computed data or files regarding the full details of the experimental procedure, if unable to be published in a normal way, can be deposited as supplementary material. Nanomaterials is dedicated to a high scientific standard. All manuscripts undergo a rigorous reviewing process and decisions are based on the recommendations of independent reviewers.