Search

Your search keyword '"Chen, Xinzhong"' showing total 848 results
Start Over Author "Chen, Xinzhong"
848 results on '"Chen, Xinzhong"'

1. Nano-Imaging of Landau-Phonon Polaritons in Dirac Heterostructures

Author

Wehmeier, Lukas, Xu, Suheng, Mayer, Rafael A., Vermilyea, Brian, Tsuneto, Makoto, Dapolito, Michael, Pu, Rui, Du, Zengyi, Chen, Xinzhong, Zheng, Wenjun, Jing, Ran, Zhou, Zijian, Watanabe, Kenji, Taniguchi, Takashi, Gozar, Adrian, Li, Qiang, Kuzmenko, Alexey B., Carr, G. Lawrence, Du, Xu, Fogler, Michael M., Basov, D. N., and Liu, Mengkun

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Polaritons are light-matter quasiparticles that govern the optical response of quantum materials and enable their nanophotonic applications. We have studied a new type of polaritons arising in magnetized graphene encapsulated in hexagonal boron nitride (hBN). These polaritons stem from hybridization of Dirac magnetoexciton modes of graphene with waveguide phonon modes of hBN crystals. We refer to these quasiparticles as the Landau-phonon polaritons (LPPs). Using infrared magneto nanoscopy, we imaged LPPs and controlled their real-space propagation by varying the magnetic field. These LLPs have large in-plane momenta and are not bound by the conventional optical selection rules, granting us access to the "forbidden" inter-Landau level transitions (ILTs). We observed avoided crossings in the LPP dispersion - a hallmark of the strong coupling regime - occurring when the magnetoexciton and hBN phonon frequencies matched. Our LPP-based nanoscopy also enabled us to resolve two fundamental many-body effects: the graphene Fermi velocity renormalization and ILT-dependent magnetoexciton binding energies. These results indicate that magnetic-field-tuned Dirac heterostructures are promising platforms for precise nanoscale control and sensing of light-matter interaction.

Published
2023

2. Visualizing moir\'e ferroelectricity via plasmons and nano-photocurrent in graphene/twisted-WSe2 structures

Author

Zhang, Shuai, Liu, Yang, Sun, Zhiyuan, Chen, Xinzhong, Li, Baichang, Moore, S. L., Liu, Song, Wang, Zhiying, Rossi, S. E., Jing, Ran, Fonseca, Jordan, Yang, Birui, Shao, Yinming, Huang, Chun-Ying, Handa, Taketo, Xiong, Lin, Fu, Matthew, Pan, Tsai-Chun, Halbertal, Dorri, Xu, Xinyi, Zheng, Wenjun, Schuck, P. J., Pasupathy, A. N., Dean, C. R., Zhu, Xiaoyang, Cobden, David H., Xu, Xiaodong, Liu, Mengkun, Fogler, M. M., Hone, James C., and Basov, D. N.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Optics
Abstract

Ferroelectricity, a spontaneous and reversible electric polarization, is found in certain classes of van der Waals (vdW) material heterostructures. The discovery of ferroelectricity in twisted vdW layers provides new opportunities to engineer spatially dependent electric and optical properties associated with the configuration of moir\'e superlattice domains and the network of domain walls. Here, we employ near-field infrared nano-imaging and nano-photocurrent measurements to study ferroelectricity in minimally twisted WSe2. The ferroelectric domains are visualized through the imaging of the plasmonic response in a graphene monolayer adjacent to the moir\'e WSe2 bilayers. Specifically, we find that the ferroelectric polarization in moir\'e domains is imprinted on the plasmonic response of the graphene. Complementary nano-photocurrent measurements demonstrate that the optoelectronic properties of graphene are also modulated by the proximal ferroelectric domains. Our approach represents an alternative strategy for studying moir\'e ferroelectricity at native length scales and opens promising prospects for (opto)electronic devices., Comment: 19 pages, 3 figures

Published
2023
Full Text
View/download PDF

3. Infrared nano-imaging of Dirac magnetoexcitons in graphene

Author

Dapolito, Michael, Tsuneto, Makoto, Zheng, Wenjun, Wehmeier, Lukas, Xu, Suheng, Chen, Xinzhong, Sun, Jiacheng, Du, Zengyi, Shao, Yinming, Jing, Ran, Zhang, Shuai, Bercher, Adrien, Dong, Yinan, Halbertal, Dorri, Ravindran, Vibhu, Zhou, Zijian, Petrovic, Mila, Gozar, Adrian, Carr, GL, Li, Qiang, Kuzmenko, Alexey B, Fogler, Michael M, Basov, DN, Du, Xu, and Liu, Mengkun

Subjects
Physical Sciences, Engineering, Nanotechnology, Condensed Matter Physics, Nanoscience & Nanotechnology
Abstract

Magnetic fields can have profound effects on the motion of electrons in quantum materials. Two-dimensional electron systems subject to strong magnetic fields are expected to exhibit quantized Hall conductivity, chiral edge currents and distinctive collective modes referred to as magnetoplasmons and magnetoexcitons. Generating these propagating collective modes in charge-neutral samples and imaging them at their native nanometre length scales have thus far been experimentally elusive. Here we visualize propagating magnetoexciton polaritons at their native length scales and report their magnetic-field-tunable dispersion in near-charge-neutral graphene. Imaging these collective modes and their associated nano-electro-optical responses allows us to identify polariton-modulated optical and photo-thermal electric effects at the sample edges, which are the most pronounced near charge neutrality. Our work is enabled by innovations in cryogenic near-field optical microscopy techniques that allow for the nano-imaging of the near-field responses of two-dimensional materials under magnetic fields up to 7 T. This nano-magneto-optics approach allows us to explore and manipulate magnetopolaritons in specimens with low carrier doping via harnessing high magnetic fields.

Published
2023

4. Machine Learning for Optical Scanning Probe Nanoscopy

Author

Chen, Xinzhong, Xu, Suheng, Shabani, Sara, Zhao, Yueqi, Fu, Matthew, Millis, Andrew J, Fogler, Michael M, Pasupathy, Abhay N, Liu, Mengkun, and Basov, DN

Subjects
Quantum Physics, Physical Sciences, artificial intelligence, machine learning, scanning near-field microscopy, scattering-type scanning near-field optical microscopy, Chemical Sciences, Engineering, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences
Abstract

The ability to perform nanometer-scale optical imaging and spectroscopy is key to deciphering the low-energy effects in quantum materials, as well as vibrational fingerprints in planetary and extraterrestrial particles, catalytic substances, and aqueous biological samples. These tasks can be accomplished by the scattering-type scanning near-field optical microscopy (s-SNOM) technique that has recently spread to many research fields and enabled notable discoveries. Herein, it is shown that the s-SNOM, together with scanning probe research in general, can benefit in many ways from artificial-intelligence (AI) and machine-learning (ML) algorithms. Augmented with AI- and ML-enhanced data acquisition and analysis, scanning probe optical nanoscopy is poised to become more efficient, accurate, and intelligent.

Published
2023

6. Phase-resolved terahertz nanoimaging of WTe2 microcrystals

Author

Jing, Ran, Vitalone, Rocco A, Xu, Suheng, Lo, Chiu Fan Bowen, Fei, Zaiyao, Runburg, Elliott, Shao, Yinming, Chen, Xinzhong, Mooshammer, Fabian, Mcleod, Alexander S, Liu, Mengkun, Fogler, Michael M, Cobden, David H, Xu, Xiaodong, and Basov, DN

Subjects
Quantum Physics, Physical Sciences, Chemical sciences, Engineering, Physical sciences
Published
2023

7. Machine Learning for Optical Scanning Probe Nanoscopy

Author

Chen, Xinzhong, Xu, Suheng, Shabani, Sara, Zhao, Yueqi, Fu, Matthew, Millis, Andrew J., Fogler, Michael M., Pasupathy, Abhay N., Liu, Mengkun, and Basov, D. N.

Subjects
Physics - Optics, Condensed Matter - Materials Science, Physics - Data Analysis, Statistics and Probability
Abstract

The ability to perform nanometer-scale optical imaging and spectroscopy is key to deciphering the low-energy effects in quantum materials, as well as vibrational fingerprints in planetary and extraterrestrial particles, catalytic substances, and aqueous biological samples. The scattering-type scanning near-field optical microscopy (s-SNOM) technique has recently spread to many research fields and enabled notable discoveries. In this brief perspective, we show that the s-SNOM, together with scanning probe research in general, can benefit in many ways from artificial intelligence (AI) and machine learning (ML) algorithms. We show that, with the help of AI- and ML-enhanced data acquisition and analysis, scanning probe optical nanoscopy is poised to become more efficient, accurate, and intelligent.

Published
2022

8. Deep-Learning-Aided Extraction of Optical Constants in Scanning Near-Field Optical Microscopy

Author

Zhao, Yueqi, Chen, Xinzhong, Yao, Ziheng, Liu, Mengkun, and Fogler, Michael M.

Subjects
Physics - Optics
Abstract

Scanning near-field optical microscopy is one of the most effective techniques for spectroscopy of nanoscale systems. However, inferring optical constants from the measured near-field signal can be challenging because of a complicated and highly nonlinear interaction between the scanned probe and the sample. Conventional fitting methods applied to this problem often suffer from the lack of convergence or require human intervention. Here we develop an alternative approach where the optical parameter extraction is automated by a deep learning network. Compared to its traditional counterparts, our method demonstrates superior accuracy, stability against noise, and computational speed when applied to simulated near-field spectra., Comment: 9 pages, 5 figures

Published
2022
Full Text
View/download PDF

13. Deep learning analysis of polaritonic waves images

Author

Xu, Suheng, McLeod, Alexander S., Chen, Xinzhong, Rizzo, Daniel J., Jessen, Bjarke S., Yao, Ziheng, Sun, Zhiyuan, Shabani, Sara, Pasupathy, Abhay N., Millis, Andrew J., Dean, Cory R., Hone, James C., Liu, Mengkun, and Basov, D. N.

Subjects
Condensed Matter - Materials Science, Physics - Data Analysis, Statistics and Probability, Physics - Optics
Abstract

Deep learning (DL) is an emerging analysis tool across sciences and engineering. Encouraged by the successes of DL in revealing quantitative trends in massive imaging data, we applied this approach to nano-scale deeply sub-diffractional images of propagating polaritonic waves in complex materials. We developed a practical protocol for the rapid regression of images that quantifies the wavelength and the quality factor of polaritonic waves utilizing the convolutional neural network (CNN). Using simulated near-field images as training data, the CNN can be made to simultaneously extract polaritonic characteristics and materials parameters in a timescale that is at least three orders of magnitude faster than common fitting/processing procedures. The CNN-based analysis was validated by examining the experimental near-field images of charge-transfer plasmon polaritons at Graphene/{\alpha}-RuCl3 interfaces. Our work provides a general framework for extracting quantitative information from images generated with a variety of scanning probe methods.

Published
2021
Full Text
View/download PDF

15. Hybrid Machine Learning for Scanning Near-field Optical Spectroscopy

Author

Chen, Xinzhong, Yao, Ziheng, Xu, Suheng, McLeod, A. S., Corder, Stephanie N. Gilbert, Zhao, Yueqi, Tsuneto, Makoto, Bechtel, Hans A., Martin, Michael C., Carr, G. L., Fogler, M. M., Stanciu, Stefan G., Basov, D. N., and Liu, Mengkun

Subjects
Physics - Optics, Physics - Data Analysis, Statistics and Probability, Physics - Instrumentation and Detectors
Abstract

The underlying physics behind an experimental observation often lacks a simple analytical description. This is especially the case for scanning probe microscopy techniques, where the interaction between the probe and the sample is nontrivial. Realistic modeling to include the details of the probe is always exponentially more difficult than its "spherical cow" counterparts. On the other hand, a well-trained artificial neural network based on real data can grasp the hidden correlation between the signal and sample properties. In this work, we show that, via a combination of model calculation and experimental data acquisition, a physics-infused hybrid neural network can predict the tip-sample interaction in the widely used scattering-type scanning near-field optical microscope. This hybrid network provides a long-sought solution for accurate extraction of material properties from tip-specific raw data. The methodology can be extended to other scanning probe microscopy techniques as well as other data-oriented physical problems in general.

Published
2021
Full Text
View/download PDF

16. THz Near-Field Imaging of Extreme Subwavelength Metal Structures

Author

Chen, Xinzhong, Liu, Xiao, Guo, Xiangdong, Chen, Shu, Hu, Hai, Nikulina, Elizaveta, Ye, Xinlin, Yao, Ziheng, Bechtel, Hans A., Martin, Michael C., Carr, G. Lawrence, Dai, Qing, Zhuang, Songlin, Hu, Qing, Zhu, Yiming, Hillenbrand, Rainer, Liu, Mengkun, and You, Guanjun

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Modern scattering-type scanning near-field optical microscopy (s-SNOM) has become an indispensable tool in material research. However, as the s-SNOM technique marches into the far-infrared (IR) and terahertz (THz) regimes, emerging experiments sometimes produce puzzling results. For example, anomalies in the near-field optical contrast have been widely reported. In this Letter, we systematically investigate a series of extreme subwavelength metallic nanostructures via s-SNOM near-field imaging in the GHz to THz frequency range. We find that the near-field material contrast is greatly impacted by the lateral size of the nanostructure, while the spatial resolution is practically independent of it. The contrast is also strongly affected by the connectivity of the metallic structures to a larger metallic ground plane. The observed effect can be largely explained by a quasi-electrostatic analysis. We also compare the THz s-SNOM results to those of the mid-IR regime, where the size-dependence becomes significant only for smaller structures. Our results reveal that the quantitative analysis of the near-field optical material contrasts in the long-wavelength regime requires a careful assessment of the size and configuration of metallic (optically conductive) structures.

Published
2021
Full Text
View/download PDF

18. Strain control of the metal-insulator transition in epitaxial SrCrO$_{3}$ thin films

Author

Bertino, Giulia, Hsing, Hsiang-Chun, Gura, Anna, Chen, Xinzhong, Sauyet, Theodore, Liu, Mengkun, Nam, Chang-Yong, and Dawber, Matthew

Subjects
Condensed Matter - Materials Science
Abstract

In the perovskite oxide SrCrO$_{3}$ the interplay between crystal structure, strain and orbital ordering enables a transition from a metallic to an insulating electronic structure under certain conditions. We identified a narrow window of oxygen partial pressure in which highly strained SrCrO$_{3}$ thin films can be grown using radio-frequency (RF) off-axis magnetron sputtering on three different substrates, (LaAlO$_{3}$)$_{0.3}$-(Sr$_{2}$TaAlO$_{6}$)$_{0.7}$ (LSAT), SrTiO$_{3}$ (STO) and DyScO$_{3}$ (DSO). X-ray diffraction and atomic force microscopy confirmed the quality of the films and a metal-insulator transition driven by the substrate induced strain was demonstrated.

Published
2021

19. Probing subwavelength in-plane anisotropy with antenna-assisted infrared nano-spectroscopy.

Author

Yao, Ziheng, Chen, Xinzhong, Wehmeier, Lukas, Xu, Suheng, Shao, Yinming, Zeng, Zimeng, Liu, Fanwei, Mcleod, Alexander S, Gilbert Corder, Stephanie N, Tsuneto, Makoto, Shi, Wu, Wang, Zihang, Zheng, Wenjun, Bechtel, Hans A, Carr, GL, Martin, Michael C, Zettl, Alex, Basov, DN, Chen, Xi, Eng, Lukas M, Kehr, Susanne C, and Liu, Mengkun

Abstract

Infrared nano-spectroscopy based on scattering-type scanning near-field optical microscopy (s-SNOM) is commonly employed to probe the vibrational fingerprints of materials at the nanometer length scale. However, due to the elongated and axisymmetric tip shank, s-SNOM is less sensitive to the in-plane sample anisotropy in general. In this article, we report an easy-to-implement method to probe the in-plane dielectric responses of materials with the assistance of a metallic disk micro-antenna. As a proof-of-concept demonstration, we investigate here the in-plane phonon responses of two prototypical samples, i.e. in (100) sapphire and x-cut lithium niobate (LiNbO3). In particular, the sapphire in-plane vibrations between 350 cm-1 to 800 cm-1 that correspond to LO phonon modes along the crystal b- and c-axis are determined with a spatial resolution of

Published
2021

25. Terahertz response of monolayer and few-layer WTe2 at the nanoscale

Author

Jing, Ran, Shao, Yinming, Fei, Zaiyao, Lo, Chiu Fan Bowen, Vitalone, Rocco A, Ruta, Francesco L, Staunton, John, Zheng, William J-C, Mcleod, Alexander S, Sun, Zhiyuan, Jiang, Bor-yuan, Chen, Xinzhong, Fogler, Michael M, Millis, Andrew J, Liu, Mengkun, Cobden, David H, Xu, Xiaodong, and Basov, DN

Subjects
Quantum Physics, Physical Sciences, Condensed Matter Physics
Abstract

Tungsten ditelluride (WTe2) is an atomically layered transition metal dichalcogenide whose physical properties change systematically from monolayer to bilayer and few-layer versions. In this report, we use apertureless scattering-type near-field optical microscopy operating at Terahertz (THz) frequencies and cryogenic temperatures to study the distinct THz range electromagnetic responses of mono-, bi- and trilayer WTe2 in the same multi-terraced micro-crystal. THz nano-images of monolayer terraces uncovered weakly insulating behavior that is consistent with transport measurements. The near-field signal on bilayer regions shows moderate metallicity with negligible temperature dependence. Subdiffractional THz imaging data together with theoretical calculations involving thermally activated carriers favor the semimetal scenario with [Formula: see text] over the semiconductor scenario for bilayer WTe2. Also, we observed clear metallic behavior of the near-field signal on trilayer regions. Our data are consistent with the existence of surface plasmon polaritons in the THz range confined to trilayer terraces in our specimens. Finally, data for microcrystals up to 12 layers thick reveal how the response of a few-layer WTe2 asymptotically approaches the bulk limit.

Published
2021

26. Effect of sample anisotropy on scanning near-field optical microscope images

Author

Chui, ST, Chen, Xinzhong, Yao, Ziheng, Bechtel, Hans A, Martin, Michael C, Carr, GL, and Liu, Mengkun

Subjects
Mathematical Sciences, Physical Sciences, Engineering, Applied Physics, Mathematical sciences, Physical sciences
Abstract

Scattering-type scanning near-field optical microscopy (s-SNOM) has been widely used to characterize strongly correlated electronic, two dimensional, and plasmonic materials, and it has enormous potential for biological applications. Many of these materials exhibit anisotropic responses that complicate the extraction of dielectric constants from s-SNOM measurements. Here, we generalize our recently developed approach for retrieving the near-field scattering signal from isotropic systems and apply it to anisotropic dielectrics. Specifically, we compare our theoretical results with experimental measurements on modestly anisotropic sapphire that exhibit strong resonances at the infrared frequency range. Good agreement with the experimental result is found. Our result is important for understanding the near-field response of low damping, anisotropic polaritonic states in dielectric media.

Published
2021

27. Author Correction: Infrared nano-imaging of Dirac magnetoexcitons in graphene

Author

Dapolito, Michael, Tsuneto, Makoto, Zheng, Wenjun, Wehmeier, Lukas, Xu, Suheng, Chen, Xinzhong, Sun, Jiacheng, Du, Zengyi, Shao, Yinming, Jing, Ran, Zhang, Shuai, Bercher, Adrien, Dong, Yinan, Halbertal, Dorri, Ravindran, Vibhu, Zhou, Zijian, Petrovic, Mila, Gozar, Adrian, Carr, G. L., Li, Qiang, Kuzmenko, Alexey B., Fogler, Michael M., Basov, D. N., Du, Xu, and Liu, Mengkun

Published
2023
Full Text
View/download PDF

29. Moir\'e Engineering of Electronic Phenomena in Correlated Oxides

Author

Chen, Xinzhong, Fan, Xiaodong, Li, Lin, Zhang, Nan, Niu, Zhijing, Guo, Tengfei, Xu, Suheng, Xu, Han, Wang, Dongli, Zhang, Huayang, McLeod, A. S., Luo, Zhenlin, Lu, Qingyou, Millis, Andrew J., Basov, D. N., Liu, Mengkun, and Zeng, Changgan

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

Moir\'e engineering has recently emerged as a capable approach to control quantum phenomena in condensed matter systems. In van der Waals heterostructures, moir\'e patterns can be formed by lattice misorientation between adjacent atomic layers, creating long range electronic order. To date, moir\'e engineering has been executed solely in stacked van der Waals multilayers. Herein, we describe our discovery of electronic moir\'e patterns in films of a prototypical magnetoresistive oxide La0.67Sr0.33MnO3 (LSMO) epitaxially grown on LaAlO3 (LAO) substrates. Using scanning probe nano-imaging, we observe microscopic moir\'e profiles attributed to the coexistence and interaction of two distinct incommensurate patterns of strain modulation within these films. The net effect is that both electronic conductivity and ferromagnetism of LSMO are modulated by periodic moir\'e textures extending over mesoscopic scales. Our work provides an entirely new route with potential to achieve spatially patterned electronic textures on demand in strained epitaxial materials.

Published
2019
Full Text
View/download PDF

30. THz Near-Field Imaging of Extreme Subwavelength Metal Structures

Author

Chen, Xinzhong, Liu, Xiao, Guo, Xiangdong, Chen, Shu, Hu, Hai, Nikulina, Elizaveta, Ye, Xinlin, Yao, Ziheng, Bechtel, Hans A, Martin, Michael C, Carr, G Lawrence, Dai, Qing, Zhuang, Songlin, Hu, Qing, Zhu, Yiming, Hillenbrand, Rainer, Liu, Mengkun, and You, Guanjun

Subjects
scattering-type scanning near-field optical microscopy, near-field, THz, nanoimaging, Schottky diodes, Optical Physics, Quantum Physics, Electrical and Electronic Engineering
Abstract

Modern scattering-type scanning near-field optical microscopy (s-SNOM) has become an indispensable tool in material research. However, as the s-SNOM technique marches into the far-infrared (IR) and terahertz (THz) regimes, emerging experiments sometimes produce puzzling results. For example, "anomalies" in the near-field optical contrast have been widely reported. In this Letter, we systematically investigate a series of extreme subwavelength metallic nanostructures via s-SNOM near-field imaging in the GHz to THz frequency range. We find that the near-field material contrast is greatly impacted by the lateral size of the nanostructure, while the spatial resolution is practically independent of it. The contrast is also strongly affected by the connectivity of the metallic structures to a larger metallic "ground plane". The observed effect can be largely explained by a quasi-electrostatic analysis. We also compare the THz s-SNOM results to those of the mid-IR regime, where the size-dependence becomes significant only for smaller structures. Our results reveal that the quantitative analysis of the near-field optical material contrasts in the long-wavelength regime requires a careful assessment of the size and configuration of metallic (optically conductive) structures.

Published
2020

31. Ultrabroadband infrared near-field spectroscopy and imaging of local resonators in percolative gold films

Author

Chen, Xinzhong, Zhang, Jiawei, Yao, Ziheng, Bechtel, Hans A, Martin, Michael C, Carr, GL, and Liu, Mengkun

Subjects
Applied Mathematics, Optical Physics, Electrical and Electronic Engineering, Optics
Abstract

Percolation processes are ubiquitous in nature and are responsible for many critical phenomena such as first-order phase transitions and infectious epidemic networks. The optical properties of a percolative medium can generally be captured by the effective medium approximation (EMA) when the degree of percolation and the properties of the constituent materials are properly addressed. However, the important local collective responses of nanoclusters in the deep subwavelength regime are often only phenomenologically addressed in the standard EMA formalism. A comprehensive method that measures local light–matter interactions and registers how the local responses influence global optical properties has yet to be established on a firm basis. In this paper, we use infrared nanoimaging/spectroscopy to investigate percolative gold films in the vicinity of the critical percolation threshold. We demonstrate experimentally and theoretically that the near-field spectra yield quantitative information of the characteristic length scale of the local gold clusters and their relative oscillator strengths. As a result, EMA analysis can be augmented with near-field nano-spectroscopy to yield better predictability of the far-field reflection spectrum at the corresponding spectral range.

Published
2019

35. Scattering of electromagnetic waves from a cone with conformal mapping: application to scanning near-field optical microscope

Author

Chui, S. T., Liu, Mengkun, Chen, Xinzhong, Lin, Zhifang, and Zi, Jian

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We study the response of a conical metallic surface to an external electromagnetic (EM) field by representing the fields in basis functions containing integrable singularities at the tip of the cone. A fast analytical solution is obtained by the conformal mapping between the cone and a round disk. We apply our calculation to the scattering- based scanning near-field optical microscope (s-SNOM) and successfully quantify the elastic light scattering from a vibrating metallic tip over a uniform sample. We find that the field-induced charge distribution consists of localized terms at the tip and the base and an extended bulk term along the body of the cone far away from the tip. In recent s-SNOM experiments at the visible-IR range (600nm - 1$\mu m$) the fundamental is found to be much larger than the higher harmonics whereas at THz range ($100 \mu m-3mm$) the fundamental becomes comparable to the higher harmonics. We find that the localized tip charge dominates the contribution to the higher harmonics and becomes bigger for the THz experiments, thus providing an intuitive understanding of the origin of the near-field signals. We demonstrate the application of our method by extracting a two-dimensional effective dielectric constant map from the s-SNOM image of a finite metallic disk, where the variation comes from the charge density induced by the EM field.

Published
2018
Full Text
View/download PDF

37. Nano-Resolved Current-Induced Insulator-Metal Transition in the Mott Insulator Ca2RuO4

Author

Zhang, Jiawei, McLeod, Alexander S, Han, Qiang, Chen, Xinzhong, Bechtel, Hans A, Yao, Ziheng, Corder, SN Gilbert, Ciavatti, Thomas, Tao, Tiger H, Aronson, Meigan, Carr, GL, Martin, Michael C, Sow, Chanchal, Yonezawa, Shingo, Nakamura, Fumihiko, Terasaki, Ichiro, Basov, DN, Millis, Andrew J, Maeno, Yoshiteru, and Liu, Mengkun

Subjects
Quantum Physics, Physical Sciences, Bioengineering, Astronomical and Space Sciences, Condensed Matter Physics, Physical sciences
Abstract

The Mott insulator Ca2RuO4 is the subject of much recent attention following reports of emergent nonequilibrium steady states driven by applied electric fields or currents. In this paper, we carry out infrared nano-imaging and optical-microscopy measurements on bulk single crystal Ca2RuO4 under conditions of steady current flow to obtain insight into the current-driven insulator-to-metal transition. We observe macroscopic growth of the current-induced metallic phase, with nucleation regions for metal and insulator phases determined by the polarity of the current flow. A remarkable metal-insulator-metal microstripe pattern is observed at the phase front separating metal and insulator phases. The microstripes have orientations tied uniquely to the crystallographic axes, implying a strong coupling of the electronic transition to lattice degrees of freedom. Theoretical modeling further illustrates the importance of the current density and confirms a submicron-thick surface metallic layer at the phase front of the bulk metallic phase. Our work confirms that the electrically induced metallic phase is nonfilamentary and is not driven by Joule heating, revealing remarkable new characteristics of electrically induced insulator-metal transitions occurring in functional correlated oxides.

Published
2019

44. Nano-spectroscopy of excitons in atomically thin transition metal dichalcogenides

Author

Zhang, Shuai, Li, Baichang, Chen, Xinzhong, Ruta, Francesco L., Shao, Yinming, Sternbach, Aaron J., McLeod, A. S., Sun, Zhiyuan, Xiong, Lin, Moore, S. L., Xu, Xinyi, Wu, Wenjing, Shabani, Sara, Zhou, Lin, Wang, Zhiying, Mooshammer, Fabian, Ray, Essance, Wilson, Nathan, Schuck, P. J., Dean, C. R., Pasupathy, A. N., Lipson, Michal, Xu, Xiaodong, Zhu, Xiaoyang, Millis, A. J., Liu, Mengkun, Hone, James C., and Basov, D. N.

Published
2022
Full Text
View/download PDF

48. Multicolor T‐Ray Imaging Using Multispectral Metamaterials

Author

Zhou, Zhitao, Zhou, Tao, Zhang, Shaoqing, Shi, Zhifeng, Chen, Ying, Wan, Wenjian, Li, Xinxin, Chen, Xinzhong, Corder, Stephanie N Gilbert, Fu, Zhanglong, Chen, Liang, Mao, Ying, Cao, Juncheng, Omenetto, Fiorenzo G, Liu, Mengkun, Li, Hua, and Tao, Tiger H

Subjects
Engineering, Electronics, Sensors and Digital Hardware, Physical Sciences, Bioengineering, metamaterials, multicolor imaging, T-ray imaging, T‐ray imaging
Abstract

Recent progress in ultrafast spectroscopy and semiconductor technology is enabling unique applications in screening, detection, and diagnostics in the Terahertz (T-ray) regime. The promise of efficaciously operation in this spectral region is tempered by the lack of devices that can spectrally analyze samples at sufficient temporal and spatial resolution. Real-time, multispectral T-ray (Mul-T) imaging is reported by designing and demonstrating hyperspectral metamaterial focal plane array (MM-FPA) interfaces allowing multiband (and individually tunable) responses without compromising on the pixel size. These MM-FPAs are fully compatible with existing microfabrication technologies and have low noise when operating in the ambient environment. When tested with a set of frequency switchable quantum cascade lasers (QCLs) for multicolor illumination, both MM-FPAs and QCLs can be tuned to operate at multiple discrete THz frequencies to match analyte "fingerprints." Versatile imaging capabilities are presented, including unambiguous identification of concealed substances with intrinsic and/or human-engineered THz characteristics as well as effective diagnosis of cancerous tissues without notable spectral signatures in the THz range, underscoring the utility of applying multispectral approaches in this compelling wavelength range for sensing/identification and medical imaging.

Published
2018

49. Near-field spectroscopic investigation of dual-band heavy fermion metamaterials.

Author

Gilbert Corder, Stephanie N, Chen, Xinzhong, Zhang, Shaoqing, Hu, Fengrui, Zhang, Jiawei, Luan, Yilong, Logan, Jack A, Ciavatti, Thomas, Bechtel, Hans A, Martin, Michael C, Aronson, Meigan, Suzuki, Hiroyuki S, Kimura, Shin-Ichi, Iizuka, Takuya, Fei, Zhe, Imura, Keiichiro, Sato, Noriaki K, Tao, Tiger H, and Liu, Mengkun

Abstract

Broadband tunability is a central theme in contemporary nanophotonics and metamaterials research. Combining metamaterials with phase change media offers a promising approach to achieve such tunability, which requires a comprehensive investigation of the electromagnetic responses of novel materials at subwavelength scales. In this work, we demonstrate an innovative way to tailor band-selective electromagnetic responses at the surface of a heavy fermion compound, samarium sulfide (SmS). By utilizing the intrinsic, pressure sensitive, and multi-band electron responses of SmS, we create a proof-of-principle heavy fermion metamaterial, which is fabricated and characterized using scanning near-field microscopes with

Published
2017

Catalog

Books, media, physical & digital resources
See catalog results