Silver Nanodisk Growth by Surface Plasmon Enhanced Photoreduction of Adsorbed [Ag<sup>+</sup>]

Maillard, Mathieu; Huang, Pinray; Brus, L. E.

doi:10.1021/nl034666d

Cited by 518 publications

(528 citation statements)

References 29 publications

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“…1 The irradiation wavelength controls the particle shape. Plasmon excitation can also photocatalyze small Ag colloid reformulation into large truncated prisms, and even fusion of such prisms into yet larger prisms.…”

Section: Introductionmentioning

confidence: 99%

Photoinduced Thermal Copper Reduction onto Gold Nanocrystals under Potentiostatic Control

2006

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We study the photoreduction of adsorbed copper ions onto Au nanoparticles, on an indium tin oxide (ITO) electrode in an aqueous electrochemical cell, as a function of applied voltage and laser intensity. The photocurrent is a nonlinear function of laser intensity and increases sharply with cathodic voltage in the underpotential deposition region. The photoreduction is attributed to laser heating of the Au nanoparticles rather than "hot electron" processes. Numerical simulation of the Butler-Volmer kinetic equation using experimental parameters predicts a several orders of magnitude increase in current for a temperature rise of a few Kelvin.

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Section: Introductionmentioning

confidence: 99%

Photoinduced Thermal Copper Reduction onto Gold Nanocrystals under Potentiostatic Control

2006

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“…More recently, surfactant-directed synthesis has enabled the high-yield production of gold nanorods [15,16], which are also tunable [17]. Silver nanoparticles can be synthesized with controlled shape and optical properties guided by optical illumination [18]. More complex architectures have also been described, including gold nanocages [19][20][21], elongated core-shell geometries [22] and gold nanostars [23][24][25][26][27][28].…”

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confidence: 99%

Biomedical Applications of Plasmon Resonant Metal Nanoparticles

2006

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The strong optical absorption and scattering of noble metal nanoparticles is due to an effect called localized surface plasmon resonance, which enables the development of novel biomedical applications. The resonant extinction, which can be tuned to the near-infrared, allows the nanoparticles to act as molecular contrast agents in a spectral region where tissue is relatively transparent. The localized heating due to resonant absorption, also tunable into the near-infared, enables new thermal ablation therapies and drug delivery mechanisms. The sensitivity of these resonances to their environment leads to simple affinity sensors for the detection of low-level molecular analytes. Coupled with their general lack of toxicity, these applications suggest that noble metal nanoparticles are a highly promising class of nanomaterials for new biomedical applications.

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“…Scientist gained significant control both the over size [7] and surfaces [8][9][10][11][12] for nanoparticles. They have demonstrated that anisotropy in nanostructure like triangular prisms [13][14][15][16][17][18], nanoscale rods [19][20][21][22][23][24][25][26], nanoshells [27][28][29][30][31], multipods [32][33][34], disks [35][36][37][38][39] and cubes [40][41][42] shows better performance over solid spheres. …”

Section: Nanomaterials and Nanotechnologymentioning

confidence: 99%

Nanoplasmonics and its Applied Devices

Rahman¹

2014

Journal of Nanotechnology and Smart Materials

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Nanoplasmonics makes a connection to conventional optics to the nanoworld. Interesting performance like subwavelength focusing to invisibility cloaking, nanoplasmonics have profound applications in science and engineering world from biophotonics to nanocircuitry. Metal and dielectric have free d-shell electrons. When metal and dielectric of different refractive index come in contact, these free electrons get accumulated in a region at the metal-semiconductor interface forming nanoplasmons. Practical implementation of nano device fabrication is the most challenging task due to the dissipative losses in metal. The optimum operating condition can be achieved by the efficient use of optical gain. We review here the ongoing progress in the field of nanoplasmonic research.

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Silver Nanodisk Growth by Surface Plasmon Enhanced Photoreduction of Adsorbed [Ag⁺]

Cited by 518 publications

References 29 publications

Photoinduced Thermal Copper Reduction onto Gold Nanocrystals under Potentiostatic Control

Photoinduced Thermal Copper Reduction onto Gold Nanocrystals under Potentiostatic Control

Biomedical Applications of Plasmon Resonant Metal Nanoparticles

Nanoplasmonics and its Applied Devices

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Silver Nanodisk Growth by Surface Plasmon Enhanced Photoreduction of Adsorbed [Ag+]

Cited by 518 publications

References 29 publications

Photoinduced Thermal Copper Reduction onto Gold Nanocrystals under Potentiostatic Control

Photoinduced Thermal Copper Reduction onto Gold Nanocrystals under Potentiostatic Control

Biomedical Applications of Plasmon Resonant Metal Nanoparticles

Nanoplasmonics and its Applied Devices

Contact Info

Product

Resources

About

Silver Nanodisk Growth by Surface Plasmon Enhanced Photoreduction of Adsorbed [Ag⁺]