用于超快光电自旋电子学的ε-近零体系

C. S. Davies, A. Kirilyuk
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摘要

在过去的二十年里,非线性声子学领域的突破性工作揭示出,高频晶格振动在中远红外光脉冲的驱动下达到高振幅时,可以增强光与物质的相互作用,从而控制各种自发有序性。这种方法从根本上依赖于红外活性横向光学声子模式的共振激发,其特点是介质介电常数的虚部达到最大值。在这篇 "视角 "文章中,我们讨论了另一种策略,即调整光脉冲以匹配介质介电常数实部归零的频率。这种所谓的ε接近于零状态,在超材料中被广泛研究,在某种程度上自然出现在红外光谱范围内的所有介电晶体中。我们发现,在声波ε-近零体系中,光与物质的相互作用得到了强烈的增强,甚至有可能永久切换自旋和偏振阶参数。我们从自己的视角探讨了如何在未来探索这一一直被忽视但富饶的研究领域,旨在概述和强调未来令人兴奋的挑战和机遇。
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Epsilon-near-zero regime for ultrafast opto-spintronics
Over the last two decades, breakthrough works in the field of non-linear phononics have revealed that high-frequency lattice vibrations, when driven to high amplitude by mid- to far-infrared optical pulses, can bolster the light-matter interaction and thereby lend control over a variety of spontaneous orderings. This approach fundamentally relies on the resonant excitation of infrared-active transverse optical phonon modes, which are characterized by a maximum in the imaginary part of the medium’s permittivity. Here, in this Perspective article, we discuss an alternative strategy where the light pulses are instead tailored to match the frequency at which the real part of the medium’s permittivity goes to zero. This so-called epsilon-near-zero regime, popularly studied in the context of metamaterials, naturally emerges to some extent in all dielectric crystals in the infrared spectral range. We find that the light-matter interaction in the phononic epsilon-near-zero regime becomes strongly enhanced, yielding even the possibility of permanently switching both spin and polarization order parameters. We provide our perspective on how this hitherto-neglected yet fertile research area can be explored in future, with the aim to outline and highlight the exciting challenges and opportunities ahead.
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