Galfenol纳米结构中的超快磁声

IF 7.1 1区医学 Q1 ENGINEERING, BIOMEDICAL

Photoacoustics Pub Date : 2023-10-26 DOI:10.1016/j.pacs.2023.100565

A.V. Scherbakov , T.L. Linnik , S.M. Kukhtaruk , D.R. Yakovlev , A. Nadzeyka , A.W. Rushforth , A.V. Akimov , M. Bayer

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引用次数: 0

摘要

声子和磁振子是纳米级通信器件中替代电荷转移的有前景的信息载体。我们在纳米尺度和终极速度上操纵它们的能力通过超快声学和飞秒光磁来检验，它们使用超短激光脉冲来产生和检测相应的相干激发。超快磁声学融合了这些研究方向，重点研究光产生的相干声子和磁振子的相互作用。在这篇综述中，我们提出了基于Galfenol合金(Fe,Ga)的纳米结构的超快磁声实验。我们证明了通过控制产生的相干声子的光谱及其与磁振子的相互作用，我们可以在光激发上操纵多么广泛的磁响应。讨论了磁振子的共振声子抽运、磁振子极化子的形成、导声子波包驱动磁化波等问题。实验结果在现代纳米电子学新兴领域具有很大的应用潜力。

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Ultrafast magnetoacoustics in Galfenol nanostructures

Phonons and magnons are prospective information carriers to substitute the transfer of charge in nanoscale communication devices. Our ability to manipulate them at the nanoscale and with ultimate speed is examined by ultrafast acoustics and femtosecond optomagnetism, which use ultrashort laser pulses for generation and detection of the corresponding coherent excitations. Ultrafast magnetoacoustics merges these research directions and focuses on the interaction of optically generated coherent phonons and magnons. In this review, we present ultrafast magnetoacoustic experiments with nanostructures based on the alloy (Fe,Ga) known as Galfenol. We demonstrate how broad we can manipulate the magnetic response on an optical excitation by controlling the spectrum of generated coherent phonons and their interaction with magnons. Resonant phonon pumping of magnons, formation of magnon polarons, driving of a magnetization wave by a guided phonon wavepacket are demonstrated. The presented experimental results have great application potential in emerging areas of modern nanoelectronics.

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来源期刊

Photoacoustics Physics and Astronomy-Atomic and Molecular Physics, and Optics

CiteScore

11.40

自引率

16.50%

发文量

审稿时长

53 days

期刊介绍： The open access Photoacoustics journal (PACS) aims to publish original research and review contributions in the field of photoacoustics-optoacoustics-thermoacoustics. This field utilizes acoustical and ultrasonic phenomena excited by electromagnetic radiation for the detection, visualization, and characterization of various materials and biological tissues, including living organisms. Recent advancements in laser technologies, ultrasound detection approaches, inverse theory, and fast reconstruction algorithms have greatly supported the rapid progress in this field. The unique contrast provided by molecular absorption in photoacoustic-optoacoustic-thermoacoustic methods has allowed for addressing unmet biological and medical needs such as pre-clinical research, clinical imaging of vasculature, tissue and disease physiology, drug efficacy, surgery guidance, and therapy monitoring. Applications of this field encompass a wide range of medical imaging and sensing applications, including cancer, vascular diseases, brain neurophysiology, ophthalmology, and diabetes. Moreover, photoacoustics-optoacoustics-thermoacoustics is a multidisciplinary field, with contributions from chemistry and nanotechnology, where novel materials such as biodegradable nanoparticles, organic dyes, targeted agents, theranostic probes, and genetically expressed markers are being actively developed. These advanced materials have significantly improved the signal-to-noise ratio and tissue contrast in photoacoustic methods.