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Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps

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Zeitschriftentitel: Advanced Materials Interfaces
Personen und Körperschaften: Gu, Panpan, Zheng, Tianxing, Zhang, Wei, Ai, Bin, Zhao, Zhiyuan, Zhang, Gang
In: Advanced Materials Interfaces, 7, 2020, 6
Format: E-Article
Sprache: Englisch
veröffentlicht:
Wiley
Schlagwörter:
Mechanical Engineering
Mechanics of Materials
author_facet Gu, Panpan
Zheng, Tianxing
Zhang, Wei
Ai, Bin
Zhao, Zhiyuan
Zhang, Gang
Gu, Panpan
Zheng, Tianxing
Zhang, Wei
Ai, Bin
Zhao, Zhiyuan
Zhang, Gang
author Gu, Panpan
Zheng, Tianxing
Zhang, Wei
Ai, Bin
Zhao, Zhiyuan
Zhang, Gang
spellingShingle Gu, Panpan
Zheng, Tianxing
Zhang, Wei
Ai, Bin
Zhao, Zhiyuan
Zhang, Gang
Advanced Materials Interfaces
Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
Mechanical Engineering
Mechanics of Materials
author_sort gu, panpan
spelling Gu, Panpan Zheng, Tianxing Zhang, Wei Ai, Bin Zhao, Zhiyuan Zhang, Gang 2196-7350 2196-7350 Wiley Mechanical Engineering Mechanics of Materials http://dx.doi.org/10.1002/admi.201902021 <jats:title>Abstract</jats:title><jats:p>Controlling the formation of bimetallic heterogeneous nanogaps structures have many applications in the plasmonics and catalysis fields. Here, a simple and systematic method is developed to fabricate tunable and stable Au–Ag nanowire‐based plasmonic metamaterials. The sub‐10 nm Au–Ag bimetallic heterogeneous nanogaps with desirable optical properties are fabricated by a simple, ultrarapid, and robust nanoskiving technique. Compared to the monometallic linear Ag–Ag and Au–Au nanogaps, the Au–Ag bimetallic heterogeneous nanogaps exhibit remarkable surface enhanced Raman spectroscopy (SERS) enhancement properties due to the nanogaps between the adjacent Au/Ag nanowires, and the Ag/Au bimetallic composite film. In addition, 3D bimetallic heterogeneous nanogaps are built and produce much stronger electric fields than those of the 1D linear nanogaps. The sub‐10 nm Au–Ag heterogeneous nanogaps are promising to be used in SERS substrate, plasmon devices, catalysis, and printed electronics.</jats:p> Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps Advanced Materials Interfaces
doi_str_mv 10.1002/admi.201902021
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title Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
title_unstemmed Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
title_full Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
title_fullStr Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
title_full_unstemmed Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
title_short Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
title_sort sub‐10 nm au–ag heterogeneous plasmonic nanogaps
topic Mechanical Engineering
Mechanics of Materials
url http://dx.doi.org/10.1002/admi.201902021
publishDate 2020
physical
description <jats:title>Abstract</jats:title><jats:p>Controlling the formation of bimetallic heterogeneous nanogaps structures have many applications in the plasmonics and catalysis fields. Here, a simple and systematic method is developed to fabricate tunable and stable Au–Ag nanowire‐based plasmonic metamaterials. The sub‐10 nm Au–Ag bimetallic heterogeneous nanogaps with desirable optical properties are fabricated by a simple, ultrarapid, and robust nanoskiving technique. Compared to the monometallic linear Ag–Ag and Au–Au nanogaps, the Au–Ag bimetallic heterogeneous nanogaps exhibit remarkable surface enhanced Raman spectroscopy (SERS) enhancement properties due to the nanogaps between the adjacent Au/Ag nanowires, and the Ag/Au bimetallic composite film. In addition, 3D bimetallic heterogeneous nanogaps are built and produce much stronger electric fields than those of the 1D linear nanogaps. The sub‐10 nm Au–Ag heterogeneous nanogaps are promising to be used in SERS substrate, plasmon devices, catalysis, and printed electronics.</jats:p>
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author Gu, Panpan, Zheng, Tianxing, Zhang, Wei, Ai, Bin, Zhao, Zhiyuan, Zhang, Gang
author_facet Gu, Panpan, Zheng, Tianxing, Zhang, Wei, Ai, Bin, Zhao, Zhiyuan, Zhang, Gang, Gu, Panpan, Zheng, Tianxing, Zhang, Wei, Ai, Bin, Zhao, Zhiyuan, Zhang, Gang
author_sort gu, panpan
container_issue 6
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container_title Advanced Materials Interfaces
container_volume 7
description <jats:title>Abstract</jats:title><jats:p>Controlling the formation of bimetallic heterogeneous nanogaps structures have many applications in the plasmonics and catalysis fields. Here, a simple and systematic method is developed to fabricate tunable and stable Au–Ag nanowire‐based plasmonic metamaterials. The sub‐10 nm Au–Ag bimetallic heterogeneous nanogaps with desirable optical properties are fabricated by a simple, ultrarapid, and robust nanoskiving technique. Compared to the monometallic linear Ag–Ag and Au–Au nanogaps, the Au–Ag bimetallic heterogeneous nanogaps exhibit remarkable surface enhanced Raman spectroscopy (SERS) enhancement properties due to the nanogaps between the adjacent Au/Ag nanowires, and the Ag/Au bimetallic composite film. In addition, 3D bimetallic heterogeneous nanogaps are built and produce much stronger electric fields than those of the 1D linear nanogaps. The sub‐10 nm Au–Ag heterogeneous nanogaps are promising to be used in SERS substrate, plasmon devices, catalysis, and printed electronics.</jats:p>
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id ai-49-aHR0cDovL2R4LmRvaS5vcmcvMTAuMTAwMi9hZG1pLjIwMTkwMjAyMQ
imprint Wiley, 2020
imprint_str_mv Wiley, 2020
institution DE-D275, DE-Bn3, DE-Brt1, DE-D161, DE-Gla1, DE-Zi4, DE-15, DE-Pl11, DE-Rs1, DE-105, DE-14, DE-Ch1, DE-L229
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publisher Wiley
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series Advanced Materials Interfaces
source_id 49
spelling Gu, Panpan Zheng, Tianxing Zhang, Wei Ai, Bin Zhao, Zhiyuan Zhang, Gang 2196-7350 2196-7350 Wiley Mechanical Engineering Mechanics of Materials http://dx.doi.org/10.1002/admi.201902021 <jats:title>Abstract</jats:title><jats:p>Controlling the formation of bimetallic heterogeneous nanogaps structures have many applications in the plasmonics and catalysis fields. Here, a simple and systematic method is developed to fabricate tunable and stable Au–Ag nanowire‐based plasmonic metamaterials. The sub‐10 nm Au–Ag bimetallic heterogeneous nanogaps with desirable optical properties are fabricated by a simple, ultrarapid, and robust nanoskiving technique. Compared to the monometallic linear Ag–Ag and Au–Au nanogaps, the Au–Ag bimetallic heterogeneous nanogaps exhibit remarkable surface enhanced Raman spectroscopy (SERS) enhancement properties due to the nanogaps between the adjacent Au/Ag nanowires, and the Ag/Au bimetallic composite film. In addition, 3D bimetallic heterogeneous nanogaps are built and produce much stronger electric fields than those of the 1D linear nanogaps. The sub‐10 nm Au–Ag heterogeneous nanogaps are promising to be used in SERS substrate, plasmon devices, catalysis, and printed electronics.</jats:p> Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps Advanced Materials Interfaces
spellingShingle Gu, Panpan, Zheng, Tianxing, Zhang, Wei, Ai, Bin, Zhao, Zhiyuan, Zhang, Gang, Advanced Materials Interfaces, Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps, Mechanical Engineering, Mechanics of Materials
title Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
title_full Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
title_fullStr Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
title_full_unstemmed Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
title_short Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
title_sort sub‐10 nm au–ag heterogeneous plasmonic nanogaps
title_unstemmed Sub‐10 nm Au–Ag Heterogeneous Plasmonic Nanogaps
topic Mechanical Engineering, Mechanics of Materials
url http://dx.doi.org/10.1002/admi.201902021