Nano-optical imaging and spectroscopy of order, phases, and domains in complex solids

IF 35 1区 物理与天体物理 Q1 PHYSICS, CONDENSED MATTER
J. Atkin, S. Berweger, Andrew C. Jones, M. Raschke
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引用次数: 198

Abstract

The structure of our material world is characterized by a large hierarchy of length scales that determines material properties and functions. Increasing spatial resolution in optical imaging and spectroscopy has been a long standing desire, to provide access, in particular, to mesoscopic phenomena associated with phase separation, order, and intrinsic and extrinsic structural inhomogeneities. A general concept for the combination of optical spectroscopy with scanning probe microscopy emerged recently, extending the spatial resolution of optical imaging far beyond the diffraction limit. The optical antenna properties of a scanning probe tip and the local near-field coupling between its apex and a sample provide few-nanometer optical spatial resolution. With imaging mechanisms largely independent of wavelength, this concept is compatible with essentially any form of optical spectroscopy, including nonlinear and ultrafast techniques, over a wide frequency range from the terahertz to the extreme ultraviolet. The past 10 years have seen a rapid development of this nano-optical imaging technique, known as tip-enhanced or scattering-scanning near-field optical microscopy (s-SNOM). Its applicability has been demonstrated for the nano-scale investigation of a wide range of materials including biomolecular, polymer, plasmonic, semiconductor, and dielectric systems. We provide a general review of the development, fundamental imaging mechanisms, and different implementations of s-SNOM, and discuss its potential for providing nanoscale spectroscopic including femtosecond spatio-temporal information. We discuss possible near-field spectroscopic implementations, with contrast based on the metallic infrared Drude response, nano-scale impedance, infrared and Raman vibrational spectroscopy, phonon Raman nano-crystallography, and nonlinear optics to identify nanoscale phase separation (PS), strain, and ferroic order. With regard to applications, we focus on correlated and low-dimensional materials as examples that benefit, in particular, from the unique applicability of s-SNOM under variable and cryogenic temperatures, nearly arbitrary atmospheric conditions, controlled sample strain, and large electric and magnetic fields and currents. For example, in transition metal oxides, topological insulators, and graphene, unusual electronic, optical, magnetic, or mechanical properties emerge, such as colossal magneto-resistance (CMR), metal–insulator transitions (MITs), high-T C superconductivity, multiferroicity, and plasmon and phonon polaritons, with associated rich phase diagrams that are typically very sensitive to the above conditions. The interaction of charge, spin, orbital, and lattice degrees of freedom in correlated electron materials leads to frustration and degenerate ground states, with spatial PS over many orders of length scale. We discuss how the optical near-field response in s-SNOM allows for the systematic real space probing of multiple order parameters simultaneously under a wide range of internal and external stimuli (strain, magnetic field, photo-doping, etc.) by coupling directly to electronic, spin, phonon, optical, and polariton resonances in materials. In conclusion, we provide a perspective on the future extension of s-SNOM for multi-modal imaging with simultaneous nanometer spatial and femtosecond temporal resolution.
复杂固体中有序、相和畴的纳米光学成像和光谱学
我们物质世界的结构的特点是一个大层次的长度尺度,决定了材料的性质和功能。提高光学成像和光谱学的空间分辨率一直是人们长期以来的愿望,特别是提供与相分离,有序以及内在和外在结构不均匀性相关的介观现象的途径。近年来出现了光谱学与扫描探针显微镜相结合的一般概念,使光学成像的空间分辨率远远超出了衍射极限。扫描探针尖端的光学天线特性及其尖端与样品之间的局部近场耦合提供了几个纳米级的光学空间分辨率。由于成像机制在很大程度上与波长无关,这个概念基本上与任何形式的光谱学兼容,包括非线性和超快技术,在从太赫兹到极紫外的广泛频率范围内。在过去的十年里,这种纳米光学成像技术得到了快速发展,被称为尖端增强或散射扫描近场光学显微镜(s-SNOM)。它的适用性已被证明适用于广泛的材料的纳米级研究,包括生物分子、聚合物、等离子体、半导体和介电系统。我们对s-SNOM的发展、基本成像机制和不同实现进行了综述,并讨论了其在提供包括飞秒时空信息在内的纳米尺度光谱方面的潜力。我们讨论了可能的近场光谱实现,并基于金属红外德鲁德响应、纳米级阻抗、红外和拉曼振动光谱、声子拉曼纳米晶体学和非线性光学进行对比,以识别纳米级相分离(PS)、应变和铁有序。在应用方面,我们将重点放在相关和低维材料上,特别是s-SNOM在可变温度和低温、几乎任意大气条件、受控样品应变以及大电场和磁场和电流下的独特适用性。例如,在过渡金属氧化物、拓扑绝缘体和石墨烯中,出现了不寻常的电子、光学、磁性或机械性能,如巨磁电阻(CMR)、金属绝缘体跃迁(MITs)、高温度超导性、多铁性、等离子体和声子极化,以及对上述条件非常敏感的丰富相图。在相关电子材料中,电荷、自旋、轨道和晶格自由度的相互作用导致受挫和简并基态,具有多个数量级的空间PS。我们讨论了s-SNOM中的光学近场响应如何通过直接耦合材料中的电子、自旋、声子、光学和极化子共振,在广泛的内外刺激(应变、磁场、光掺杂等)下同时对多个阶参数进行系统的实空间探测。最后,我们展望了s-SNOM在纳米空间和飞秒时间分辨率下的多模态成像的未来扩展。
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
Advances in Physics
Advances in Physics 物理-物理:凝聚态物理
CiteScore
67.60
自引率
0.00%
发文量
1
期刊介绍: Advances in Physics publishes authoritative critical reviews by experts on topics of interest and importance to condensed matter physicists. It is intended for motivated readers with a basic knowledge of the journal’s field and aims to draw out the salient points of a reviewed subject from the perspective of the author. The journal''s scope includes condensed matter physics and statistical mechanics: broadly defined to include the overlap with quantum information, cold atoms, soft matter physics and biophysics. Readership: Physicists, materials scientists and physical chemists in universities, industry and research institutes.
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