Cloudy Carnegie
Overview
Explore the profile of Cloudy Carnegie including associated specialties, affiliations and a list of published articles.
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Articles
11
Citations
402
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0
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Recent Articles
1.
Jakob L, Deacon W, Zhang Y, de Nijs B, Pavlenko E, Hu S, et al.
Nat Commun
. 2023 Jun;
14(1):3291.
PMID: 37280203
Molecular vibrations couple to visible light only weakly, have small mutual interactions, and hence are often ignored for non-linear optics. Here we show the extreme confinement provided by plasmonic nano-...
2.
Salmon A, Kleemann M, Huang J, Deacon W, Carnegie C, Kamp M, et al.
ACS Nano
. 2020 Mar;
14(4):4982-4987.
PMID: 32208688
The properties of nanoplasmonic structures depend strongly on their geometry, creating the need for high-precision control and characterization. Here, by exploiting the low activation energy of gold atoms on nanoparticle...
3.
Carnegie C, Urbieta M, Chikkaraddy R, de Nijs B, Griffiths J, Deacon W, et al.
Nat Commun
. 2020 Feb;
11(1):682.
PMID: 32015332
The dynamic restructuring of metal nanoparticle surfaces is known to greatly influence their catalytic, electronic transport, and chemical binding functionalities. Here we show for the first time that non-equilibrium atomic-scale...
4.
de Nijs B, Carnegie C, Szabo I, Grys D, Chikkaraddy R, Kamp M, et al.
ACS Sens
. 2019 Oct;
4(11):2988-2996.
PMID: 31565921
Quantitative applications of surface-enhanced Raman spectroscopy (SERS) often rely on surface partition layers grafted to SERS substrates to collect and trap-solvated analytes that would not otherwise adsorb onto metals. Such...
5.
Carnegie C, Griffiths J, de Nijs B, Readman C, Chikkaraddy R, Deacon W, et al.
J Phys Chem Lett
. 2018 Dec;
9(24):7146-7151.
PMID: 30525662
Reproducible confinement of light on the nanoscale is essential for the ability to observe and control chemical reactions at the single-molecule level. Here we reliably form millions of identical nanocavities...
6.
Chikkaraddy R, Turek V, Kongsuwan N, Benz F, Carnegie C, van de Goor T, et al.
Nano Lett
. 2017 Nov;
18(1):405-411.
PMID: 29166033
Fabricating nanocavities in which optically active single quantum emitters are precisely positioned is crucial for building nanophotonic devices. Here we show that self-assembly based on robust DNA-origami constructs can precisely...
7.
Kleemann M, Chikkaraddy R, Alexeev E, Kos D, Carnegie C, Deacon W, et al.
Nat Commun
. 2017 Nov;
8(1):1296.
PMID: 29101317
Strong coupling of monolayer metal dichalcogenide semiconductors with light offers encouraging prospects for realistic exciton devices at room temperature. However, the nature of this coupling depends extremely sensitively on the...
8.
de Nijs B, Benz F, Barrow S, Sigle D, Chikkaraddy R, Palma A, et al.
Nat Commun
. 2017 Oct;
8(1):994.
PMID: 29057870
Nanoparticles attached just above a flat metallic surface can trap optical fields in the nanoscale gap. This enables local spectroscopy of a few molecules within each coupled plasmonic hotspot, with...
9.
de Nijs B, Kamp M, Szabo I, Barrow S, Benz F, Wu G, et al.
Faraday Discuss
. 2017 Sep;
205:505-515.
PMID: 28932831
Rigid gap nano-aggregates of Au nanoparticles formed using cucurbit[n]uril (CB[n]) molecules are used to investigate the competitive binding of ethanol and methanol in an aqueous environment. We show it is...
10.
Benz F, Schmidt M, Dreismann A, Chikkaraddy R, Zhang Y, Demetriadou A, et al.
Science
. 2016 Nov;
354(6313):726-729.
PMID: 27846600
Trapping light with noble metal nanostructures overcomes the diffraction limit and can confine light to volumes typically on the order of 30 cubic nanometers. We found that individual atomic features...