Plasmonically Nanoconfined Light Probing Invisible Phonon Modes in Defect-Free Graphene

被引：26

作者：

Ikeda, Katsuyoshi ^{[1
,2
,3
]}

Takase, Mai ^{[1
]}

Hayazawa, Norihiko ^{[3
,4
]}

Kawata, Satoshi ^{[3
,4
,5
]}

Murakoshi, Kei ^{[1
]}

Uosaki, Kohei ^{[1
,6
]}

机构：

[1] Hokkaido Univ, Grad Sch Sci, Div Chem, Sapporo, Hokkaido 0600810, Japan

[2] JST PRESTO, Kawaguchi, Saitama 3320012, Japan

[3] RIKEN, Wako, Saitama 3510198, Japan

[4] Tokyo Inst Technol, Interdisciplinary Grad Sch Sci & Engn, Dept Elect Chem, Yokohama, Kanagawa 2268502, Japan

[5] Osaka Univ, Dept Appl Phys, Suita, Osaka 5650871, Japan

[6] Natl Inst Mat Sci, Int Ctr Mat Nanoarchitechton WPI MANA, Tsukuba, Ibaraki 3050044, Japan

来源：

JOURNAL OF THE AMERICAN CHEMICAL SOCIETY | 2013年 / 135卷 / 31期

关键词：

ENHANCED RAMAN-SCATTERING; SURFACE; SPECTROSCOPY;

D O I：

10.1021/ja4056596

中图分类号：

O6 [化学];

学科分类号：

0703 ;

摘要：

We present a simple plasmonic method that enables tuning of accessibility to the dipole-forbidden transition states of matter. This technique is realized by well-controlled plasmonic dimers, which can confine optical fields on the order of molecular dimensions. As an example, the approach is applied to activate invisible noncenter phonon modes of defect-free graphene in resonance Raman spectra. The relative intensity of the normally forbidden modes with respect to the dipole allowed modes progressively increases as the degree of field confinement increases. This opens up a novel avenue for both photochemical excitation of molecular systems and nanoscale characterization of materials.

引用

页码：11489 / 11492

页数：4

共 50 条

[31] Density Functional Theory Calculations of Lithium Adsorption and Insertion to Defect-Free and Defective Graphene
Okamoto, Yasuharu
JOURNAL OF PHYSICAL CHEMISTRY C, 2016, 120 (26): : 14009 - 14014
[32] Synergistic Effect of a Defect-Free Graphene Nanostructure as an Anode Material for Lithium Ion Batteries
Park, Kwang Hyun
Kim, Byung Gon
Song, Sung Ho
NANOMATERIALS, 2020, 10 (01)
[33] Enhancing the reactivity of clean, defect-free epitaxial graphene by the substrate-Experiment and theory
Stach, T.
Seif, A.
Ambrosetti, A.
Silvestrelli, P. L.
Burghaus, U.
JOURNAL OF VACUUM SCIENCE & TECHNOLOGY A, 2023, 41 (06):
[34] Defect-Free, Highly Uniform Washable Transparent Electrodes Induced by Selective Light Irradiation
Zhong, Zhaoyang
Woo, Kyoohee
Kim, Inhyuk
Kim, Hyuntae
Ko, Pyeongsam
Kang, Dongwoo
Kwon, Sin
Kim, Hyunchang
Youn, Hongseok
Moon, Jooho
SMALL, 2018, 14 (21)
[35] Nanofabrication route to achieve sustainable production of next generation defect-free graphene: analysis and characterisation
Misra, Shikhar
Katiyar, Nirmal Kumar
Kumar, Arvind
Goel, Saurav
Biswas, Krishanu
NANOFABRICATION, 2021, 6 (01): : 36 - 43
[36] Defect-Free Mechanical Graphene Transfer Using n-Doping Adhesive Gel Buffer
Seo, Young-Min
Jang, Wonseok
Gu, Taejun
Seok, Hae-Jun
Han, Seunghun
Choi, Byoung Lyong
Kim, Han-Ki
Chae, Heeyeop
Kang, Joohoon
Whang, Dongmok
ACS NANO, 2021, 15 (07) : 11276 - 11284
[37] Advanced Phase Change Composite by Thermally Annealed Defect-Free Graphene for Thermal Energy Storage
Xin, Guoqing
Sun, Hongtao
Scott, Spencer Michael
Yao, Tiankai
Lu, Fengyuan
Shao, Dali
Hu, Tao
Wang, Gongkai
Ran, Guang
Lian, Jie
ACS APPLIED MATERIALS & INTERFACES, 2014, 6 (17) : 15262 - 15271
[38] Defect-free graphene enhances enzyme delivery to fibroblasts derived from the patients with lysosomal disorders
Vranic, Sandra
Jovanovic, Ana
Jones, Simon
Kostarelos, Kostas
Casiraghi, Cinzia
MOLECULAR GENETICS AND METABOLISM, 2023, 138 (02) : 132 - 132
[39] Highly Concentrated, Conductive, Defect-free Graphene Ink for Screen-Printed Sensor Application
Dong Seok Kim
Jae-Min Jeong
Hong Jun Park
Yeong Kyun Kim
Kyoung G.Lee
Bong Gill Choi
Nano-Micro Letters, 2021, 13 (06) : 23 - 36
[40] Defect-Free, Size-Tunable Graphene for High-Performance Lithium Ion Battery
Park, Kwang Hyun
Lee, Dongju
Kim, Jungmo
Song, Jongchan
Lee, Yong Min
Kim, Hee-Tak
Park, Jung-Ki
NANO LETTERS, 2014, 14 (08) : 4306 - 4313

← 1 2 3 4 5 →