Defect tolerance and the effect of structural inhomogeneity in plasmonic DNA-nanoparticle superlattices

Ross, Michael B.; Ku, Jessie C.; Blaber, Martin G.; Mirkin, Chad A.; Schatz, George C.

doi:10.1073/pnas.1513058112

Cited by 35 publications

(55 citation statements)

References 54 publications

(67 reference statements)

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“…Because defects and inhomogeneity in the superlattice can affect the optical response of these materials, it is crucial to produce high-quality crystals. 40 Each SAXS pattern shows, regardless of the solution ionic strength, a high degree of single-crystalline ordering of nanoparticles arranged into a bcc crystallographic symmetry (Figure S5). The crystallinity was further characterized by performing SAD using a transmission electron microscope (TEM) (Figure 3).…”

Section: Resultsmentioning

confidence: 99%

The Importance of Salt-Enhanced Electrostatic Repulsion in Colloidal Crystal Engineering with DNA

et al. 2019

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Realizing functional colloidal single crystals requires precise control over nanoparticles in three dimensions across multiple size regimes. In this regard, colloidal crystallization with programmable atom equivalents (PAEs) composed of DNA-modified nanoparticles allows one to program in a sequence-specific manner crystal symmetry, lattice parameter, and, in certain cases, crystal habit. Here, we explore how salt and the electrostatic properties of DNA regulate the attachment kinetics between PAEs. Counterintuitively, simulations and theory show that at high salt concentrations (1 M NaCl), the energy barrier for crystal growth increases by over an order of magnitude compared to low concentration (0.3 M), resulting in a transition from interface-limited to diffusion-limited crystal growth at larger crystal sizes. Remarkably, at elevated salt concentrations, well-formed rhombic dodecahedron-shaped microcrystals up to 21 μm in size grow, whereas at low salt concentration, the crystal size typically does not exceed 2 μm. Simulations show an increased barrier to hybridization between complementary PAEs at elevated salt concentrations. Therefore, although one might intuitively conclude that higher salt concentration would lead to less electrostatic repulsion and faster PAE-to-PAE hybridization kinetics, the opposite is the case, especially at larger inter-PAE distances. These observations provide important insight into how solution ionic strength can be used to control the attachment kinetics of nanoparticles coated with charged polymeric materials in general and DNA in particular.

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Section: Resultsmentioning

confidence: 99%

The Importance of Salt-Enhanced Electrostatic Repulsion in Colloidal Crystal Engineering with DNA

et al. 2019

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“…applications. For colloidal crystals in general, notable applications include photonics 4,5 , sensing 6,7 , and catalysis 8,9 . By controlling the relative sizes of colloidal particles in binary systems and the nature of their interactions, a myriad of structures have been produced experimentally from self-assembly: CsCl, NaCl, CuAu, NaTl, AlB 2 , MgZn 2 , Cr 3 Si, Cu 3 Au, Cs 6 C 60 , and others 2,3,[10][11][12][13][14][15] .…”

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confidence: 99%

Assembly of three-dimensional binary superlattices from multi-flavored particles

et al. 2018

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Binary superlattices constructed from nano- or micron-sized colloidal particles have a wide variety of applications, including the design of advanced materials. Self-assembly of such crystals from their constituent colloids can be achieved in practice by, among other means, the functionalization of colloid surfaces with single-stranded DNA sequences. However, when driven by DNA, this assembly is traditionally premised on the pairwise interaction between a single DNA sequence and its complement, and often relies on particle size asymmetry to entropically control the crystalline arrangement of its constituents. The recently proposed "multi-flavoring" motif for DNA functionalization, wherein multiple distinct strands of DNA are grafted in different ratios to different colloids, can be used to experimentally realize a binary mixture in which all pairwise interactions are independently controllable. In this work, we use various computational methods, including molecular dynamics and Wang-Landau Monte Carlo simulations, to study a multi-flavored binary system of micron-sized DNA-functionalized particles modeled implicitly by Fermi-Jagla pairwise interactions. We show how self-assembly of such systems can be controlled in a purely enthalpic manner, and by tuning only the interactions between like particles, demonstrate assembly into various morphologies. Although polymorphism is present over a wide range of pairwise interaction strengths, we show that careful selection of interactions can lead to the generation of pure compositionally ordered crystals. Additionally, we show how the crystal composition changes with the like-pair interaction strengths, and how the solution stoichiometry affects the assembled structures.

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“…For plasmonic nanostructures and assemblies, it is well-known that parameters such as particle size, shape, and composition determine the final optical properties of a plasmonic nanomaterial. 52 , 53 Particularly, in the case of assemblies of plasmonic particles, other parameters such as the interparticle distances and the relative geometry of the particles to each other can also have a huge impact on the final optical properties of assembled systems. 42 , 54 , 55 In the following, we demonstrate that the protein-assisted self-assembly approach is highly modular in terms of parameters such as size and composition ( i.e.…”

Section: Resultsmentioning

confidence: 99%

Protein-Assisted Assembly of Modular 3D Plasmonic Raspberry-like Core/Satellite Nanoclusters: Correlation of Structure and Optical Properties

et al. 2016

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We present a bottom-up assembly route for a large-scale organization of plasmonic nanoparticles (NPs) into three-dimensional (3D) modular assemblies with core/satellite structure. The protein-assisted assembly of small spherical gold or silver NPs with a hydrophilic protein shell (as satellites) onto larger metal NPs (as cores) offers high modularity in sizes and composition at high satellite coverage (close to the jamming limit). The resulting dispersions of metal/metal nanoclusters exhibit high colloidal stability and therefore allow for high concentrations and a precise characterization of the nanocluster architecture in dispersion by small-angle X-ray scattering (SAXS). Strong near-field coupling between the building blocks results in distinct regimes of dominant satellite-to-satellite and core-to-satellite coupling. High robustness against satellite disorder was proved by UV/vis diffuse reflectance (integrating sphere) measurements. Generalized multiparticle Mie theory (GMMT) simulations were employed to describe the electromagnetic coupling within the nanoclusters. The close correlation of structure and optical property allows for the rational design of core/satellite nanoclusters with tailored plasmonics and well-defined near-field enhancement, with perspectives for applications such as surface-enhanced spectroscopies.

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Defect tolerance and the effect of structural inhomogeneity in plasmonic DNA-nanoparticle superlattices

Cited by 35 publications

References 54 publications

The Importance of Salt-Enhanced Electrostatic Repulsion in Colloidal Crystal Engineering with DNA

The Importance of Salt-Enhanced Electrostatic Repulsion in Colloidal Crystal Engineering with DNA

Assembly of three-dimensional binary superlattices from multi-flavored particles

Protein-Assisted Assembly of Modular 3D Plasmonic Raspberry-like Core/Satellite Nanoclusters: Correlation of Structure and Optical Properties

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