Gallium Plasmonics: Deep Subwavelength Spectroscopic Imaging of Single and Interacting Gallium Nanoparticles

Knight, Mark W.; Coenen, Toon; Yang, Yang; Brenny, Benjamin J. M.; Losurdo, Maria; Brown, April S.; Everitt, Henry O.; Polman, A.

doi:10.1021/nn5072254

Cited by 142 publications

(152 citation statements)

References 68 publications

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“…Similar results were obtained by Albella et al [60] through a numerical study based on the Discrete Dipole Approximation (DDA) [61]. Other methods used to study this type of nanoparticles include variable-angle spectroscopic and Mueller matrix ellipsometry [62] or hyperspectral cathodoluminescence imaging [63].…”

Section: Galliumsupporting

confidence: 72%

Plasmonics in the Ultraviolet with Aluminum, Gallium, Magnesium and Rhodium

et al. 2018

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Ultraviolet plasmonics (UV) has become an active topic of research due to the new challenges arising in fields such as biosensing, chemistry or spectroscopy. Recent studies have pointed out aluminum, gallium, magnesium and rhodium as promising candidates for plasmonics in the UV range. Aluminum and magnesium present a high oxidation tendency that has a critical effect in their plasmonic performance. Nevertheless, gallium and rhodium have drawn a lot of attention because of their low tendency of oxidation and, at the same time, good plasmonic response in the UV and excellent photocatalytic properties. Here, we present a short overview of the current state of UV plasmonics with the latest findings in the plasmonic response and applications of aluminum, gallium, magnesium and rhodium nanoparticles.

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Section: Galliumsupporting

confidence: 72%

Plasmonics in the Ultraviolet with Aluminum, Gallium, Magnesium and Rhodium

et al. 2018

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“…1a), we observe that the NP contact angle on the substrate plane is close to 90º, giving rise to hemispherical shapes. This morphology results from the surface tension of liquid Ga on the silicon substrate, and it is preserved during the functionalization works due to the formation of a thin oxide film on the NP surface (Knight et al 2015;Wu et al 2009). …”

Section: Nanoparticle Characterizationmentioning

confidence: 99%

Immunosensing platform based on gallium nanoparticle arrays on silicon substrates

Marín

Hernández

Ruiz

et al. 2015

Biosensors and Bioelectronics

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“…While the formation of Ga grains from thinly deposited Ga films may be explained through Ostwald ripening [31] and references within, the formation of Ga grains on films whose thickness is much larger than the actual height of the grains is not trivial. Our STM measurements revealed that the first deposited Ga film had an approximate thickness of 32 µm and its surface is densely populated with grains that have large aspect ratio values from 1-1.8.…”

Section: Discussionmentioning

confidence: 99%

“…The Ga deposition method resembles the procedure used by Knight et al; [31] the main difference involved a longer deposition time, which resulted in the larger thicknesses of our Ga films. The films were prepared by depositing Ga (99.99% purity, Gallium Source, USA) on p type (boron doped) Si(111) mono-wafer substrates (Institute of Electronic Materials Technology, Poland).…”

Section: Deposition Of Galliummentioning

confidence: 99%

“…Hence, some Ga grains may have a base that is equal or smaller than the projection of the Ga grain on the substrate, implying a contact angle at the base larger than 90 o , as reported in the literature. [31] The aspect ratio of the Ga grains, defined as the ratio between the height of the Ga grain to the half the diameter of its substrate projection, was obtained from these images. The aspect ratio of a hemisphere shaped grain was equal to 1, a value which can conveniently serve as a reference.…”

Section: Stm Of the Gallium Filmsmentioning

confidence: 99%

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Characterization of the topography and thickness of gallium thin films by scanning tunneling microscopy

Bratfalean

Marconi

Colniță

2016

Instrumentation Science & Technology

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Scanning tunneling microscopy (STM) was employed to characterize the topography of 32 and 4 µm thick gallium films; thicknesses that have not yet been addressed. The STM images revealed submicron grains on both surfaces although a reduced grain density was observed on the thinner film. The granular structure may be explained by a thin gallium oxide layer that acted as an elastic membrane against liquid gallium underneath that expanded during freezing of the sample. We also believe that the same gallium oxide layer is also responsible for an intriguing effect that appears as soon as the tungsten tip lands on the gallium film: the onset of continuous regular z-oscillations of the tip even at rest. This is an effect that we believe has not been previously reported in the literature. We have also demonstrated, for the first time, a new thickness determination method for the gallium film based on an STM image obtained during the solid-to-liquid phase transition.

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Gallium Plasmonics: Deep Subwavelength Spectroscopic Imaging of Single and Interacting Gallium Nanoparticles

Cited by 142 publications

References 68 publications

Plasmonics in the Ultraviolet with Aluminum, Gallium, Magnesium and Rhodium

Plasmonics in the Ultraviolet with Aluminum, Gallium, Magnesium and Rhodium

Immunosensing platform based on gallium nanoparticle arrays on silicon substrates

Characterization of the topography and thickness of gallium thin films by scanning tunneling microscopy

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