Modern Scattering‐Type Scanning Near‐Field Optical Microscopy for Advanced Material Research

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The development of electronics and photonics is entering a new era of ultrahigh speed sensing, data processing, and telecommunication. The carrier frequencies of the next‐generation electronic devices inevitably extend beyond radio frequencies, marching toward the nominally photonics‐dominated territories, e.g., terahertz and beyond. As a result, electronic and photonic techniques naturally merge and seek common ground. At the forefront of this technical trend is the field of polaritonics, where polaritons are half‐light, half‐matter quasiparticles that carry the properties of both “bare” photons and “bare” dipole‐carrying excitations. The Janus‐faced nature of polaritons renders the unique capability of operando control using photoexcitation or applied electric field. Here, state‐of‐the‐art ultrafast polaritonic phenomena probed by scattering‐type scanning near‐field optical microscope (s‐SNOM) techniques is reviewed. The ultrafast dynamical control and loss‐reduction of the polariton propagation are discussed with special emphasis on the creation and probing of the tip or edge induced plasmon– and phonon–polaritons in low‐dimensional systems. The detailed technical aspects of s‐SNOM and its possible future development are also presented.

Section: Experimental Technique and Polariton Detectionmentioning

confidence: 98%

Section: Experimental Technique and Polariton Detectionmentioning

confidence: 99%

Section: Experimental Technique and Polariton Detectionmentioning

confidence: 99%

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Nanoimaging and Nanospectroscopy of Polaritons with Time Resolved s‐SNOM

Yao

et al. 2019

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“…Recently, remarkable features of subdiffractional polaritons have been observed in van der Waals (vdW) crystals and in their corresponding 2D materials . Most of those observations stem from real‐space images of exciton‐polaritons in transition metal dichalcogenides, plasmon‐polaritons in graphene, phonon‐polaritons in polar vdW crystals, and hybrid plasmon‐phonon polaritons in vdW heterostructures . For these studies, the use of advanced optical methods such as scattering scanning near‐field optical microscopy (s‐SNOM), synchrotron infrared nanospectroscopy (SINS), and, more recently, photoinduced force microscopy (PiFM) have been paramount.…”

Section: Introductionmentioning

confidence: 99%

Probing Polaritons in 2D Materials with Synchrotron Infrared Nanospectroscopy

Barcelos

Bechtel

Matos

et al. 2019

Polaritons, which are quasiparticles composed of a photon coupled to an electric or magnetic dipole, are a major focus in nanophotonic research of van der Waals (vdW) crystals and their derived 2D materials. For the variety of existing vdW materials, polaritons can be active in a broad range of the electromagnetic spectrum (meVs to eVs) and exhibit momenta much higher than the corresponding free‐space radiation. Hence, the use of high momentum broadband sources or probes is imperative to excite those quasiparticles and measure the frequency‐momentum dispersion relations, which provide insights into polariton dynamics. Synchrotron infrared nanospectroscopy (SINS) is a technique that combines the nanoscale spatial resolution of scattering‐type scanning near‐field optical microscopy with ultrabroadband synchrotron infrared radiation, making it highly suitable to probe and characterize a variety of vdW polaritons. Here, the advances enabled by SINS on the study of key photonic attributes of far‐ and mid‐infrared plasmon‐ and phonon‐polaritons in vdW and 2D crystals are reviewed. In that context the SINS technique is comprehensively described and it is demonstrated how fundamental polaritonic properties are retrieved for a range of atomically thin systems including hBN, MoS2, graphene and 2D heterostructures.

“…The charge distributions and motions due to optical excitation of the sample modify the polarizability of the metallic AFM tip, leading to resonance‐dependent scattered signals . s‐SNOM can both excite polaritons with high momenta and detect them with high spatial resolution, thus it is suitable for studying polaritons in low dimensional materials . Polaritons in BN, MoSe 2 , MoO 3 were experimentally discovered and quantified by s‐SNOM.…”

mentioning

confidence: 99%

Revealing Phonon Polaritons in Hexagonal Boron Nitride by Multipulse Peak Force Infrared Microscopy

Wang

Wagner

Wang

et al. 2019

Probing of polaritons in 2D materials is facilitated by spectroscopic imaging with nanometer spatial resolution. The combination of atomic force microscopy and infrared laser sources provides access for in situ mappings of phonon polaritons. Here, it is demonstrated that the photothermal‐based peak force infrared microscopy is capable of revealing phonon polaritons with high spatial resolution in isotopically pure hexagonal boron nitride microstructures without damaging the sample. To further improve the sensitivity, peak force infrared microscopy is enhanced with a scheme of multiple laser pulse excitation. The resulting method of multipulse peak force infrared microscopy can detect phonon polaritons with high sensitivity, which is particularly useful for probing polaritons in 2D materials with high damping characteristics.