Assembly of silver nanoparticles on nanowires into ordered nanostructures with femtosecond laser radiation

Lin, Luchan; Huang, Hong; Sivayoganathan, Mugunthan; Ping, Li; Zou, Guisheng; Duley, W. W.; Zhou, Yunhong

doi:10.1364/ao.54.002524

Cited by 12 publications

(10 citation statements)

References 35 publications

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“…In order for this color change to occur, the majority of the Ag-NPLs would have to be anisotropically oriented, on average, within the polymer; thus, the two separate plasmon bands (longitudinal and transverse) exhibit a non-uniform response to the polarized light. Multiple axial-dependent plasmonic bands have been observed previously for ansiotropic particles including nanorice [1], nanowires [9], and nanorods [26]. Similar dichroic polarization behavior was observed by Dirix et al for composites containing oriented pearl necklace arrays; however, these arrays were produced in situ and lack the optical and morphological tractability that our method provides [6].…”

Section: Resultssupporting

confidence: 86%

“…Due to their dichroic nature and facile synthesis, ellipsoidal silver nanoparticles (Ag-NPs), including so-called nanorice [1], nanocarrots [2], nanorods [3], and nanoplates [4], are excellent candidates for the design of devices with controlled absorption of light. Specific control of the assembly and orientation of Ag-NPs has led to the development of polarizing films [5][6][7][8], nano-antennas [9], dichroic optical filters [6,10], and surface-enhanced Raman substrates [11]. Oriented arrays of Ag-NPs can be difficult and expensive to fabricate in large reproducible quantities and are limited in their tractability over the optical properties.…”

Section: Introductionmentioning

confidence: 99%

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Macroscopic Alignment of Silver Nanoplates in an Adaptable Dichroic Polarizer

et al. 2018

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Morphological control to precisely tailor the energy absorption bands of plasmonic particles is improving constantly, with efforts to improve the monodispersity of the designed particles leading to sharper plasmonic features in controlled spectral regions. Transitioning these highly tailored plasmonic additives into a robust polymer composite platforms while retaining their specified plasmonic features has proven challenging, with the elevated temperatures and mechanical forces involved in composite manufacturing resulting in particle agglomeration and morphology alterations. In this work, thermally stable protecting layers are developed onto tailored silver nanoplate (Ag-NPL) plasmonic additives to facilitate their survivable processing at elevated temperature. The produced coatings allow for their implementation in a facile, low-cost method to produce uniform dichroic optical polarizers based on the protected Ag-NPLs in a polymer matrix. Nanocomposites are obtained through an extrusion and injection molding process, which is shown to induce alignment of anisotropic particles based on sheer forces. As the optical position of the resonances is dependent on the morphology of the additive, and unlike other methods where the anisotropy in the NP is induced in situ, our method can be easily adapted to varying optical regimes by modifying the size and shape of the initial additive. Furthermore, the method presented in this work forgoes the need for a polymer stretching alignment mechanism which enables the ability to use various types of anisotropic particles with visible and near-infrared operating regimes.

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Section: Resultssupporting

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Macroscopic Alignment of Silver Nanoplates in an Adaptable Dichroic Polarizer

et al. 2018

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“…Through combination of two lasers with different wavelengths as a trapping laser and heating source, fs laser trapping can be used to probe the temperature of particles in solution . Moreover, a nanostructure can be built by a combination of optical force and nonlinear effect of the fs laser, which breaks through the diffraction limitation. , Irradiating the fs laser on metal nanowires generates a plasmon, which induces force to attract nanoparticles. , Fs trapping is receiving much attention as a potential tool in chemistry and material science or in biological science, and its studies or dynamics and mechanism are strongly requested.…”

Section: Introductionmentioning

confidence: 99%

“…17,18 Irradiating the fs laser on metal nanowires generates a plasmon, which induces force to attract nanoparticles. 19,20 Fs trapping is receiving much attention as a potential tool in chemistry and material science or in biological science, and its studies or dynamics and mechanism are strongly requested.…”

Section: Introductionmentioning

confidence: 99%

Formation Mechanism and Fluorescence Characterization of a Transient Assembly of Nanoparticles Generated by Femtosecond Laser Trapping

Chiang

Chen²,

Usman

et al. 2019

J. Phys. Chem. C

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Femtosecond (fs) laser trapping of dielectric nanoparticles displays a unique trapping and directional ejection phenomenon, which is never observed in continuous-wave (cw) laser trapping. We studied the fs laser trapping and considered its dynamics and mechanism in terms of gathering, association, and ejection of nanoparticles. By tuning solution viscosity through adding ethylene glycol, the trapping behavior by fs and cw lasers are examined and compared with each other. The viscous solution slows down the diffusional and rotational movement of nanoparticles and increases the chance of nanoparticle assembly in the trapping site, which eventually leads to the novel ejection. We took advantage of fluorescence measurement to confirm the formation of the nanoparticle assembly during fs laser trapping. A red emission irregularly appeared in the fluorescence spectra, which strongly supports the transient assembly formation in the molecular level.

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“…Introduction: Array of Au NPs (gold nanoparticles) is a much sought after structure having a wide range of applications in photovoltaics [1], surface enhanced fluorescence [2], bio sensing [3], label-free visualisation of living cells [4], magnetic memory and so on. Different processes are available to fabricate an array of Au NPs such as focused ion beam fabrication [5], femtosecond laser irradiation [6], thermal dewetting [7][8][9], nanoplastic forming with thermal dewetting [10][11][12][13] and so on. However, most of these processes results in random sized nanoparticles (NPs) and their position are also random and/or it is difficult to achieve over a larger area.…”

mentioning

confidence: 99%

Fabrication of large‐area ordered array of gold nanoparticles on c‐Si substrate and its characterisation through reflectance spectra

Meena

Kumar

Goswami

et al. 2016

Micro & Nano Letters

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Ordered arrays of substrate supported gold nanodots are fabricated on c-Si as substrate. Electron beam lithography followed by DC sputter coating was used for the fabrication of ordered gold nanodots over a 1 × 1 cm 2 area on c-Si substrate. The fabricated ordered arrays of gold nanodots were characterised through the reflectance spectra. Reduction of 60.67% in reflectance was exhibited by ordered gold nanodots when compared with bare c-Si. For comparison, a random gold nanoparticle array of approximately same particle size was fabricated and the reflectance was compared with the ordered array. It was found that the reflectance of ordered array is 52.27% less than that of random array. This route is suitable for fabrication of large area ordered gold nanodots which has applications in photovoltaic industry.

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Assembly of silver nanoparticles on nanowires into ordered nanostructures with femtosecond laser radiation

Cited by 12 publications

References 35 publications

Macroscopic Alignment of Silver Nanoplates in an Adaptable Dichroic Polarizer

Macroscopic Alignment of Silver Nanoplates in an Adaptable Dichroic Polarizer

Formation Mechanism and Fluorescence Characterization of a Transient Assembly of Nanoparticles Generated by Femtosecond Laser Trapping

Fabrication of large‐area ordered array of gold nanoparticles on c‐Si substrate and its characterisation through reflectance spectra

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