Your search keyword '"Michael M. Fogler"' showing total 3 results

1. Fundamental limits to graphene plasmonics

Author

Zhiyuan Sun, Sai Sunku, Alexander McLeod, Kirk Post, Guangxin Ni, Michael M. Fogler, Lei Wang, Dimitri Basov, Cory Dean, Bor-Yuan Jiang, James Hone, and Lin Xiong

Subjects

Multidisciplinary, Materials science, Graphene, business.industry, Physics::Optics, Heterojunction, 02 engineering and technology, Electron, 021001 nanoscience & nanotechnology, 01 natural sciences, law.invention, law, 0103 physical sciences, Physics::Atomic and Molecular Clusters, Polariton, Quasiparticle, Optoelectronics, 010306 general physics, 0210 nano-technology, Absorption (electromagnetic radiation), business, Lasing threshold, Plasmon

Abstract

Plasmon polaritons are hybrid excitations of light and mobile electrons that can confine the energy of long-wavelength radiation at the nanoscale. Plasmon polaritons may enable many enigmatic quantum effects, including lasing 1 , topological protection2,3 and dipole-forbidden absorption 4 . A necessary condition for realizing such phenomena is a long plasmonic lifetime, which is notoriously difficult to achieve for highly confined modes 5 . Plasmon polaritons in graphene—hybrids of Dirac quasiparticles and infrared photons—provide a platform for exploring light–matter interaction at the nanoscale6,7. However, plasmonic dissipation in graphene is substantial 8 and its fundamental limits remain undetermined. Here we use nanometre-scale infrared imaging to investigate propagating plasmon polaritons in high-mobility encapsulated graphene at cryogenic temperatures. In this regime, the propagation of plasmon polaritons is primarily restricted by the dielectric losses of the encapsulated layers, with a minor contribution from electron–phonon interactions. At liquid-nitrogen temperatures, the intrinsic plasmonic propagation length can exceed 10 micrometres, or 50 plasmonic wavelengths, thus setting a record for highly confined and tunable polariton modes. Our nanoscale imaging results reveal the physics of plasmonic dissipation and will be instrumental in mitigating such losses in heterostructure engineering applications. The fundamental limits to plasmon damping in graphene are determined using nanoscale infrared imaging at cryogenic temperatures, and plasmon polaritons are observed to propagate over 10 micrometres in high-mobility encapsulated graphene.

Published

2018

2. Imaging viscous flow of the Dirac fluid in graphene

Author

Mark J H, Ku, Tony X, Zhou, Qing, Li, Young J, Shin, Jing K, Shi, Claire, Burch, Laurel E, Anderson, Andrew T, Pierce, Yonglong, Xie, Assaf, Hamo, Uri, Vool, Huiliang, Zhang, Francesco, Casola, Takashi, Taniguchi, Kenji, Watanabe, Michael M, Fogler, Philip, Kim, Amir, Yacoby, and Ronald L, Walsworth

Abstract

The electron-hole plasma in charge-neutral graphene is predicted to realize a quantum critical system in which electrical transport features a universal hydrodynamic description, even at room temperature

Published

2019

3. Gate-tuning of graphene plasmons revealed by infrared nano-imaging

Author

Aleksandr Rodin, Zeng Zhao, Fritz Keilmann, Mark H. Thiemens, A. H. Castro Neto, Zhe Fei, Martin Wagner, Gregory O. Andreev, Michael M. Fogler, L. M. Zhang, Wenzhong Bao, Chun Ning Lau, Alexander McLeod, Dimitri Basov, and Gerardo Dominguez

Subjects

Materials science, Infrared Rays, Surface Properties, Static Electricity, FOS: Physical sciences, Physics::Optics, Microscopy, Atomic Force, Electromagnetic radiation, law.invention, Standing wave, Optics, Electromagnetic Fields, law, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Physics::Atomic and Molecular Clusters, Figure of merit, Nanotechnology, Plasmon, Condensed Matter - Materials Science, Multidisciplinary, Condensed Matter - Mesoscale and Nanoscale Physics, business.industry, Graphene, Surface plasmon, Materials Science (cond-mat.mtrl-sci), Wavelength, Semiconductor, Optoelectronics, Graphite, business

Abstract

Surface plasmons are collective oscillations of electrons in metals or semiconductors enabling confinement and control of electromagnetic energy at subwavelength scales. Rapid progress in plasmonics has largely relied on advances in device nano-fabrication, whereas less attention has been paid to the tunable properties of plasmonic media. One such medium-graphene-is amenable to convenient tuning of its electronic and optical properties with gate voltage. Through infrared nano-imaging we explicitly show that common graphene/SiO2/Si back-gated structures support propagating surface plasmons. The wavelength of graphene plasmons is of the order of 200 nm at technologically relevant infrared frequencies, and they can propagate several times this distance. We have succeeded in altering both the amplitude and wavelength of these plasmons by gate voltage. We investigated losses in graphene using plasmon interferometry: by exploring real space profiles of plasmon standing waves formed between the tip of our nano-probe and edges of the samples. Plasmon dissipation quantified through this analysis is linked to the exotic electrodynamics of graphene. Standard plasmonic figures of merits of our tunable graphene devices surpass that of common metal-based structures., 15 pages, 3 figures

Published

2012