Universal Noble Metal Nanoparticle Seeds Realized Through Iterative Reductive Growth and Oxidative Dissolution Reactions

O’Brien, Matthew N.; Jones, Matthew R.; Brown, Keith A.; Mirkin, Chad A.

doi:10.1021/ja503509k

Cited by 204 publications

(266 citation statements)

References 34 publications

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“…The crystallinity of a NP core, on the other hand, leads to a great expansion of the palette of particle shapes: rods, dumbbells, cubes, hexagons, tetrahedrons, octahedrons, concave rhombic dodecahedra, tetrahexahedra, and others ( Fig. 1, B to G) (20). Even NPs that are considered to be spherical are often actually prolate in shape, with an aspect ratio of 1.1 to 1.2 (21), and are also often faceted (20).…”

Section: What Is a Nanoparticle?mentioning

confidence: 99%

Nonadditivity of nanoparticle interactions

Batista

Larson

Kotov

2015

Science

442

240

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Understanding interactions between inorganic nanoparticles (NPs) is central to comprehension of self-organization processes and a wide spectrum of physical, chemical, and biological phenomena. However, quantitative description of the interparticle forces is complicated by many obstacles that are not present, or not as severe, for microsize particles (μPs). Here we analyze the sources of these difficulties and chart a course for future research. Such difficulties can be traced to the increased importance of discreteness and fluctuations around NPs (relative to μPs) and to multiscale collective effects. Although these problems can be partially overcome by modifying classical theories for colloidal interactions, such an approach fails to manage the nonadditivity of electrostatic, van der Waals, hydrophobic, and other interactions at the nanoscale. Several heuristic rules identified here can be helpful for discriminating between additive and nonadditive nanoscale systems. Further work on NP interactions would benefit from embracing NPs as strongly correlated reconfigurable systems with diverse physical elements and multiscale coupling processes, which will require new experimental and theoretical tools. Meanwhile, the similarity between the size of medium constituents and NPs makes atomic simulations of their interactions increasingly practical. Evolving experimental tools can stimulate improvement of existing force fields. New scientific opportunities for a better understanding of the electronic origin of classical interactions are converging at the scale of NPs.

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Section: What Is a Nanoparticle?mentioning

confidence: 99%

Nonadditivity of nanoparticle interactions

Batista

Larson

Kotov

2015

Science

442

240

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“…1A), and can be synthesized via a seed-mediated method that yields >95% of the desired shape with <5% variation in size (Fig. 1A) (21). Particle uniformity was rigorously analyzed with a recently reported and freely available program that algorithmically analyzes transmission electron microscopy (TEM) images to analytically determine nanoparticle structure (22).…”

mentioning

confidence: 99%

Exploring the zone of anisotropy and broken symmetries in DNA-mediated nanoparticle crystallization

O’Brien

Girard

Lin

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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In this work, we present a joint experimental and molecular dynamics simulations effort to understand and map the crystallization behavior of polyhedral nanoparticles assembled via the interaction of DNA surface ligands. In these systems, we systematically investigated the interplay between the effects of particle core (via the particle symmetry and particle size) and ligands (via the ligand length) on crystallization behavior. This investigation revealed rich phase diagrams, previously unobserved phase transitions in polyhedral crystallization behavior, and an unexpected symmetry breaking in the ligand distribution on a particle surface. To understand these results, we introduce the concept of a zone of anisotropy, or the portion of the phase space where the anisotropy of the particle is preserved in the crystallization behavior. Through comparison of the zone of anisotropy for each particle we develop a foundational roadmap to guide future investigations.ver the past decade, major advances in the control of nanoparticle interactions have led to powerful methods to assemble colloidal crystals (1-9). A high degree of structural control can be achieved in these methods if surface-bound ligands are used as nanoscale bonding elements to control the specificity, spacing, and strength of interactions. DNA has emerged as a particularly versatile ligand whose chemically and structurally defined nature can be used to program the symmetry, lattice parameters, and habit of colloidal crystals (1,2,7,(10)(11)(12)(13)(14)(15)(16)(17)(18)(19). The shape of the underlying nanoparticle influences the directionality of DNA interactions, which can result in correlated nanoparticle orientations and predictable crystal symmetries based on geometric considerations (7,13,16,19,20). However, predictive control can be lost if the DNA shell does not preserve the anisotropy of the particle core (13), and thus key questions pertain to (i) the phase space over which predictable directional interactions persist and (ii) the nature of the phase transitions that occur as the anisotropy of the particle disappears. Identifying this "zone of anisotropy" and the broken symmetries that form are critical to establish design rules for work with nonspherical particles and to develop nanostructured materials with controlled properties.Herein, we systematically investigate the phase space encoded by particle symmetry, particle size (L), and DNA length (D) to understand and map where directional interactions persist (Fig. 1). We show that particle symmetry dictates the crystalline states that can be accessed and how easily changes in L and D affect phase transitions between these states, which include transitions in Bravais lattice (i.e., the symmetry of how the particles are arranged within the unit cell) and particle orientation. The concepts introduced herein provide a roadmap to understand and predict particle crystallization behavior toward the construction of functional nanoparticle-based materials.To map the zone of anisotropy in DNA-mediated nan...

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“…Similar effects occur in polytypic semiconductors (i.e., materials capable of adopting two different crystalline structures), where the energy difference between polytypes can fall within the temperature fluctuations of the system (15,16,22). These problems can be circumvented with larger seeds whose fate can be monitored and directly correlated with product structure (28). Indeed, if literaturereported seed-mediated syntheses optimized for a particular shape are repeated with larger, more uniform seeds, yields can be improved to >95% with CV <5% for at least eight different nonspherical shapes with widely tunable sizes (28).…”

Section: From Atoms To Crystalline Nanoparticlesmentioning

confidence: 95%

“…In particular, the automated, algorithmic analysis of electron microscopy (EM) images holds tremendous potential to improve the rigor of nanomaterial characterization. This powerful tool can be used to minimize sampling bias, to improve throughput, and to quantitatively measure structure with single-nanoparticle resolution (28,29). The largest limitation associated with this approach pertains to the informational loss in the conversion of 2D projections from EM images to 3D shapes (30,31).…”

Section: From Atoms To Crystalline Nanoparticlesmentioning

confidence: 99%

“…These problems can be circumvented with larger seeds whose fate can be monitored and directly correlated with product structure (28). Indeed, if literaturereported seed-mediated syntheses optimized for a particular shape are repeated with larger, more uniform seeds, yields can be improved to >95% with CV <5% for at least eight different nonspherical shapes with widely tunable sizes (28). This represents a particularly powerful advance that emphasizes the importance of seed stability and uniformity in the synthesis of homogeneous products.…”

Section: From Atoms To Crystalline Nanoparticlesmentioning

confidence: 99%

See 1 more Smart Citation

The nature and implications of uniformity in the hierarchical organization of nanomaterials

O’Brien

Jones

Mirkin

2016

Proc. Natl. Acad. Sci. U.S.A.

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In this Perspective, we present a framework that defines how to understand and control material structure across length scales with inorganic nanoparticles. Three length scales, frequently discussed separately, are unified under the topic of hierarchical organization: atoms arranged into crystalline nanoparticles, ligands arranged on nanoparticle surfaces, and nanoparticles arranged into crystalline superlattices. Through this lens, we outline one potential pathway toward perfect colloidal matter that emphasizes the concept of uniformity. Uniformity is of both practical and functional importance, necessary to increase structural sophistication and realize the promise of nanostructured materials. Thus, we define the nature of nonuniformity at each length scale as a means to guide ongoing research efforts and highlight potential problems in the field.nanomaterial | uniformity | colloidal crystal | dispersity | hierarchy

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Universal Noble Metal Nanoparticle Seeds Realized Through Iterative Reductive Growth and Oxidative Dissolution Reactions

Cited by 204 publications

References 34 publications

Nonadditivity of nanoparticle interactions

Nonadditivity of nanoparticle interactions

Exploring the zone of anisotropy and broken symmetries in DNA-mediated nanoparticle crystallization

The nature and implications of uniformity in the hierarchical organization of nanomaterials

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