Plasmonic polymers unraveled through single particle spectroscopy

Slaughter, Liane Siu; Wang, Lin-Yung; Willingham, Britain A.; Olson, Jana; Swanglap, Pattanawit; Domínguez-Medina, Sergio; Link, Stephan

doi:10.1039/c4nr02839b

Cited by 22 publications

(37 citation statements)

References 77 publications

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“…We argue that these results might have direct consequences in more complex branched aggregates [14,61], whose optical response can be dominated by plasmonic modes supported by chain-like subunits.The description of the optical response of aggregates as ensembles of linear chains is based on the validation of this concept for spherical particles, and we expect it to be valid also in clusters formed by flat-faceted units, at least if the different gaps are always formed between well-aligned flat facets. Furthermore, although the inherent disorder found in self-assembled aggregates modifies to some extent the plasmonic modes, the overall properties of the plasmonic response have been found to be quite robust with respect to disorder in previous work [14,32,62,63]. The experimental realization of such 2 or 3-dimensional aggregates would require particles with more than two flat facets.…”

Section: Discussionmentioning

confidence: 92%

Self-assembled flat-faceted nanoparticles chains as a highly-tunable platform for plasmon-enhanced spectroscopy in the infrared

Aguirregabiria¹,

Aizpurua²,

Esteban³

2017

Opt. Express

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Self-assembly fabrication methods can produce aggregates of metallic nanoparticles separated by nanometer distances which act as versatile platforms for field-enhanced spectroscopy due to the strong fields induced at the interparticle gaps. In this letter we show the advantages of using particles with large flat facets at the gap as the building elements of the aggregates. For this purpose, we analyze theoretically the plasmonic response of chains of metallic particles of increasing length. These chains may be a direct product of the chemical synthesis and can be seen as the key structural unit behind the plasmonic response of two and three dimensional self-assembled aggregates. The longitudinal chain plasmon that dominates the optical response redshifts following an exponential dependence on the number of particles in the chain for all facets studied, with a saturation wavelength and a characteristic decay length depending linearly on the diameter of the facet. According to our calculations, for small Au particles of 50 nm size separated by a 1 nanometer gap, the saturation wavelength for the largest facets considered correspond to a wavelength shift of ≈ 1200 nm with respect to the single particle resonance, compared to shifts of only ≈ 200 nm for the equivalent configuration of perfectly spherical particles. The corresponding decay lengths are 11.8 particles for the faceted nanoparticles and 3.5 particles for the spherical ones. Thus, large flat facets lead to an excellent tunability of the longitudinal chain plasmon, covering the whole biological window and beyond. Furthermore, the maximum near-field at the gap is only moderately weaker for faceted gaps than for spherical particles, while the region of strong local field enhancement extends over a considerably larger volume, allowing to accommodate more target molecules. Our results indicate that flat facets introduce significant advantages for spectroscopic and sensing applications using self-assembled aggregates.

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Section: Discussionmentioning

confidence: 92%

Self-assembled flat-faceted nanoparticles chains as a highly-tunable platform for plasmon-enhanced spectroscopy in the infrared

Aguirregabiria¹,

Aizpurua²,

Esteban³

2017

Opt. Express

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“…In contrast to rod like structures, 33 the excitation energy of the L1 mode in long chains converges at low energies, described as the infinite chain limit. 16 In literature, this limit is typically defined somewhere between 8 and 12 particles (see also a spectral visualization in Figure S1). 15,16 In contrast, nanoparticle dipole moments, perpendicular to the chain axis, couple only weakly, resulting in (almost) degenerate transversal modes (marked as T at 2.2 eV/560 nm).…”

Section: Nano Lettersmentioning

confidence: 99%

Direct Observation of Plasmon Band Formation and Delocalization in Quasi-Infinite Nanoparticle Chains

et al. 2019

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Chains of metallic nanoparticles sustain strongly confined surface plasmons with relatively low dielectric losses. To exploit these properties in applications, such as waveguides, the fabrication of long chains of low disorder and a thorough understanding of the plasmon-mode properties, such as dispersion relations, are indispensable. Here, we use a wrinkled template for directed self-assembly to assemble chains of gold nanoparticles. With this up-scalable method, chain lengths from two particles (140 nm) to 20 particles (1500 nm) and beyond can be fabricated. Electron energy-loss spectroscopy supported by boundary element simulations, finite-difference time-domain, and a simplified dipole coupling model reveal the evolution of a band of plasmonic waveguide modes from degenerated single-particle modes in detail. In striking difference from plasmonic rod-like structures, the plasmon band is confined in excitation energy, which allows light manipulations below the diffraction limit. The non-degenerated surface plasmon modes show suppressed radiative losses for efficient energy propagation over a distance of 1500 nm.

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“…One-dimensional (1D) plasmonic nanochains − are now utilized in numerous plasmon-driven applicatons, − including optical sensing, , catalysis, and energy harvesting. , The plasmonic properties of nanochains resemble those of other anisotropic plasmonic objects such as nanorods (NRs) , and nanowires, exhibiting localized surface plasmon resonance (LSPR) in transverse and longitudinal modes. , Tuning of the LSPR responses of plasmonic nanochains is flexible and supported by their large number of architectural parameters available for adjustment, including shape and composition of nanoparticle (NP) building blocks, number of NPs per chain, and gap distance between adjacent NPs in the chain. ,− To date, few studies have explored the use of plasmonic nanochains for intracellular applications, owing to the limitations of various existing methods of 1D assembly. Dewetting necessitates dispersion of plasmonic NPs in organic solvents and subsequent drying for assembly on solid substrates, − yet it is unclear whether the nanochains retain their morphology upon their transferal to aqueous cell culture medium.…”

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confidence: 99%

Dopamine-Mediated Assembly of Citrate-Capped Plasmonic Nanoparticles into Stable Core–Shell Nanoworms for Intracellular Applications

et al. 2019

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Plasmonic nanochains, derived from the one-dimensional assembly of individual plasmonic nanoparticles (NPs), remain infrequently explored in biological investigations due to their limited colloidal stability, ineffective cellular uptake, and susceptibility to intracellular disassembly. We report the synthesis of polydopamine (PDA)-coated plasmonic “nanoworms” (NWs) by sonicating citrate-capped gold (Cit-Au) NPs in a concentrated dopamine (DA) solution under alkaline conditions. DA mediates the assembly of Cit-Au NPs into Au NWs within 1 min, and subsequent self-polymerization of DA for 60 min enables the growth of an outer conformal PDA shell that imparts stability to the inner Au NW structure in solution, yielding “core–shell” Au@PDA NWs with predominantly 4–5 Au cores per worm. Our method supports the preparation of monometallic Au@PDA NWs with different core sizes and bimetallic PDA-coated NWs with Au and silver cores. The protonated primary amine and catechol groups of DA, with their ability to interact with Cit anions via hydrogen bonding and electrostatic attraction, are critical to assembly. When compared to unassembled PDA-coated Au NPs, our Au@PDA NWs scatter visible light and absorb near-infrared light more intensely and enter HeLa cancer cells more abundantly. Au@PDA NWs cross the cell membrane as intact entities primarily via macropinocytosis, mostly retain their inner NW structure and outer PDA shell inside the cell for 24 h, and do not induce noticeable cytotoxicity. We showcase three intracellular applications of Au@PDA NWs, including label-free dark-field scattering cell imaging, delivery of water-insoluble cargos without pronounced localization in acidic compartments, and photothermal killing of cancer cells.

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Plasmonic polymers unraveled through single particle spectroscopy

Cited by 22 publications

References 77 publications

Self-assembled flat-faceted nanoparticles chains as a highly-tunable platform for plasmon-enhanced spectroscopy in the infrared

Self-assembled flat-faceted nanoparticles chains as a highly-tunable platform for plasmon-enhanced spectroscopy in the infrared

Direct Observation of Plasmon Band Formation and Delocalization in Quasi-Infinite Nanoparticle Chains

Dopamine-Mediated Assembly of Citrate-Capped Plasmonic Nanoparticles into Stable Core–Shell Nanoworms for Intracellular Applications

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