Shape influence on the ultrafast plasmonic properties of gold nanoparticles

Peckus, Domantas; Tamulevičienė, Asta; Mougin, Karine; Spangenberg, Arnaud; Vidal, Loı̈c; Bauerlin, Quentin; Keller, Marc S.; Henzie, Joel; Puodžiukynas, Linas; Tamulevičius, Tomas; Tamulevičius, Sigitas

doi:10.1364/oe.463961

Cited by 8 publications

(6 citation statements)

References 49 publications

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“…It may be noted that MNPs with a hot electron lifetime (τ) higher than ≈1.5 ps are preferred for photocatalysis. [ 53 ]…”

Section: Resultsmentioning

confidence: 99%

“…It may be noted that MNPs with a hot electron lifetime (𝜏) higher than ≈1.5 ps are preferred for photocatalysis. [53] To assess the STH efficiency of the H-Au system, online gas chromatography (Figure S28, Supporting Information) was employed. Figure 7a shows the rate of H 2 evolution under exposure to simulated solar light (AAA class solar simulator 1 Sun, 1000 mW cm −2 ) for durations up to 3 h. The absorption spectrum for H-Au glass (Figure 1d) spans from 480 to 700 nm, with a peak centered at 536 nm, attributed to particle size distribution.…”

Section: Figure 5bc Illustrates the Changes In The Intensity Of 𝛿(H-o...mentioning

confidence: 99%

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H‐Glass Supported Hybrid Gold Nano‐Islands for Visible‐Light‐Driven Hydrogen Evolution

Mandal,

Gangareddy,

Sethurajaperumal

et al. 2024

Small

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Flat panel reactors, coated with photocatalytic materials, offer a sustainable approach for the commercial production of hydrogen (H2) with zero carbon footprint. Despite this, achieving high solar‐to‐hydrogen (STH) conversion efficiency with these reactors is still a significant challenge due to the low utilization efficiency of solar light and rapid charge recombination. Herein, hybrid gold nano‐islands (HGNIs) are developed on transparent glass support to improve the STH efficiency. Plasmonic HGNIs are grown on an in‐house developed active glass sheet composed of sodium aluminum phosphosilicate oxide glass (H‐glass) using the thermal dewetting method at 550 °C under an ambient atmosphere. HGNIs with various oxidation states (Au0, Au+, and Au−) and multiple interfaces are obtained due to the diffusion of the elements from the glass structure, which also facilitates the lifetime of the hot electron to be ≈2.94 ps. H‐glass‐supported HGNIs demonstrate significant STH conversion efficiency of 0.6%, without any sacrificial agents, via water dissociation. This study unveils the specific role of H‐glass‐supported HGNIs in facilitating light‐driven chemical conversions, offering new avenues for the development of high‐performance photocatalysts in various chemical conversion reactions for large‐scale commercial applications.

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“…It may be noted that MNPs with a hot electron lifetime (τ) higher than ≈1.5 ps are preferred for photocatalysis. [ 53 ]…”

Section: Resultsmentioning

confidence: 99%

Section: Figure 5bc Illustrates the Changes In The Intensity Of 𝛿(H-o...mentioning

confidence: 99%

H‐Glass Supported Hybrid Gold Nano‐Islands for Visible‐Light‐Driven Hydrogen Evolution

Mandal,

Gangareddy,

Sethurajaperumal

et al. 2024

Small

View full text Add to dashboard Cite

show abstract

“… 38 , 39 , 40 The shape of NPs also affects their biodistribution and uptake efficiency by APCs. 41 For example, spherical gold NPs were effectively taken up by APCs compared with rod‐shaped counterparts. The MiSp‐based NM‐NPs are with a size of ∼200 nm and a spherical morphology (Figure 1 ), after loaded with protein, the Lyso‐NM‐NPs can increase to approximately 500 nm in diameter with maintaining the spherical morphology (Figure 2B ).…”

Section: Discussionmentioning

confidence: 99%

“…[38][39][40] The shape of NPs also affects their biodistribution and uptake efficiency by APCs. 41 For example, spherical gold NPs were effectively taken up by APCs compared with rod-shaped F I G U R E 9 Spider-silk based nanoparticles as a suitable carrier for protein antigen induce a robust immune and cellular responses by subcutaneous immunization. These nanoparticles, based on MiSp, significantly enhance antigen-specific immune responses, through mechanisms involving antigen-depot effects at the injection site, efficient uptake by dendritic cells as well as internalization by lymph nodes, promoting maturation and cross-presentation.…”

Section: Discussionmentioning

confidence: 99%

Spider minor ampullate silk protein nanoparticles: an effective protein delivery system capable of enhancing systemic immune responses

Yu,

Chen,

et al. 2024

MedComm

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Spider silk proteins (spidroins) are particularly attractive due to their excellent biocompatibility. Spider can produce up to seven different types of spidroins, each with unique properties and functions. Spider minor ampullate silk protein (MiSp) might be particularly interesting for biomedical applications, as the constituent silk is mechanically strong and does not super‐contract in water, attributed to its amino acid composition. In this study, we evaluate the potential of recombinant nanoparticles derived from Araneus ventricosus MiSp as a protein delivery carrier. The MiSp‐based nanoparticles were able to serve as an effective delivery system, achieving nearly 100% efficiency in loading the model protein lysozyme, and displayed a sustained release profile at physiological pH. These nanoparticles could significantly improve the delivery efficacy of the model proteins through different administration routes. Furthermore, nanoparticles loaded with model protein antigen lysozyme after subcutaneous or intramuscular administration could enhance antigen‐specific immune responses in mouse models, through a mechanism involving antigen‐depot effects at the injection site, long‐term antigen persistence, and efficient uptake by dendritic cells as well as internalization by lymph nodes. These findings highlight the transnational potential of MiSp‐based nanoparticle system for protein drug and vaccine delivery.

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“…The oscillation frequency is closely related to the electron density, the effective mass of electrons, and the shape and size of the surface charge distribution . Therefore, in order to accumulate enough heat to realize the photothermal effect, particles with complex geometric features are usually prepared, which can change the shape of the charge distribution and enhance the local electron density while obtaining a larger specific surface area, which is because the electron density on the surface of Au nanoparticles is proportional to the surface curvature. , High-frequency vibration makes the local temperature rise, thus affecting the surrounding structure or material properties . In other words, Au nanoparticles provide an adjustment strategy for the release control of liposomes through the photothermal effect.…”

Section: Photoresponsive Liposomes Based On Au Nanoparticlesmentioning

confidence: 99%

Recent Development of Photoresponsive Liposomes Based on Organic Photosensitizers, Au Nanoparticles, and Azobenzene Derivatives for Nanomedicine

Pan

et al. 2022

ACS Appl. Nano Mater.

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Photoresponsive liposomes are controlled-release liposomes modified by photoresponsive materials. They use light with high spatial and temporal precision as a means of regulation. After excitation by light at appropriate wavelengths, photoresponsive liposomes can influence the permeability of phospholipid bilayers through the photothermal or photoisomerization effect of photoresponsive materials. The photothermal effect causes the phospholipid layer to become dispersed by local heating, and the photoisomerization effect modulates the release behavior by establishing permeation channels on the phospholipid layer through changes in the dipole moments of azobenzene derivatives. Currently, photoresponsive liposomes are widely used as a cutting-edge strategy for nanomedicine. In this paper, three types of photoresponsive liposomes based on organic photosensitizers, Au nanoparticles, and azobenzene derivatives with abundant research reports were introduced based on the differences in the photoresponse principles and forms of different photoresponsive materials. This review aims to reflect the differences in the structures, properties, photoresponsive materials, and principles of action of different photoresponsive liposomes. Moreover, this work outlines the current status of their application in the field of nanomedicine.

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Shape influence on the ultrafast plasmonic properties of gold nanoparticles

Cited by 8 publications

References 49 publications

H‐Glass Supported Hybrid Gold Nano‐Islands for Visible‐Light‐Driven Hydrogen Evolution

H‐Glass Supported Hybrid Gold Nano‐Islands for Visible‐Light‐Driven Hydrogen Evolution

Spider minor ampullate silk protein nanoparticles: an effective protein delivery system capable of enhancing systemic immune responses

Recent Development of Photoresponsive Liposomes Based on Organic Photosensitizers, Au Nanoparticles, and Azobenzene Derivatives for Nanomedicine

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