Author
Listed:
- Stephanie N. Gilbert Corder
(Stony Brook University)
- Xinzhong Chen
(Stony Brook University)
- Shaoqing Zhang
(University of Texas-Austin)
- Fengrui Hu
(Iowa State University)
- Jiawei Zhang
(Stony Brook University)
- Yilong Luan
(Iowa State University)
- Jack A. Logan
(Stony Brook University)
- Thomas Ciavatti
(Stony Brook University)
- Hans A. Bechtel
(Lawrence Berkeley National Laboratory)
- Michael C. Martin
(Lawrence Berkeley National Laboratory)
- Meigan Aronson
(Texas A&M University)
- Hiroyuki S. Suzuki
(National Institute for Materials Science
University of Tokyo)
- Shin-ichi Kimura
(Institute for Molecular Science
Osaka University, Suita)
- Takuya Iizuka
(Institute for Molecular Science
Toyota Technological Institute)
- Zhe Fei
(Iowa State University)
- Keiichiro Imura
(Institute for Molecular Science
Nagoya University)
- Noriaki K. Sato
(Nagoya University)
- Tiger H. Tao
(University of Texas-Austin
Shanghai Institute of Microsystem and Information Technology, Chinese Academy of Sciences)
- Mengkun Liu
(Stony Brook University)
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
Suggested Citation
Stephanie N. Gilbert Corder & Xinzhong Chen & Shaoqing Zhang & Fengrui Hu & Jiawei Zhang & Yilong Luan & Jack A. Logan & Thomas Ciavatti & Hans A. Bechtel & Michael C. Martin & Meigan Aronson & Hiroyu, 2017.
"Near-field spectroscopic investigation of dual-band heavy fermion metamaterials,"
Nature Communications, Nature, vol. 8(1), pages 1-7, December.
Handle:
RePEc:nat:natcom:v:8:y:2017:i:1:d:10.1038_s41467-017-02378-3
DOI: 10.1038/s41467-017-02378-3
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