Hierarchical self-assembly of suspended branched colloidal nanocrystals into superlattice structures

Miszta, Karol; Graaf, Joost de; Bertoni, Giovanni; Dorfs, Dirk; Brescia, Rosaria; Marras, Sergio; Ceseracciu, Luca; Cingolani, R.; Roij, René van; Dijkstra, Marjolein; Manna, Liberato

doi:10.1038/nmat3121

Cited by 425 publications

(475 citation statements)

References 35 publications

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“…32 Our group recently reported an experimental and simulation study of the hierarchical self-assembly of anisotropic branched colloidal nanocrystals, so-called octapods, into 3D superstructures in the liquid bulk phase. 20 In this Letter, we extend our findings to the formation of monolayers consisting of octapods, which were obtained by a deposition−evaporation procedure. In the experiments, we obtained monolayers in the micrometer size range in which the octapods with a pod lengthto-diameter ratio of L/D ≈ 4.8 arranged into a square-lattice crystal (SC).…”

supporting

confidence: 64%

Ordered Two-Dimensional Superstructures of Colloidal Octapod-Shaped Nanocrystals on Flat Substrates

Graaf²,

Qiao

et al. 2012

Nano Lett.

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We studied crystal structures in a monolayer consisting of anisotropic branched colloidal (nano)octapods. Experimentally, octapods were observed to form a monolayer on a substrate with a square-lattice crystal structure by dropcasting and fast evaporation of solvent. The experimental results were analyzed by Monte Carlo simulations using a hard octapod model consisting of four interpenetrating spherocylinders. We confirmed by means of free-energy calculations that crystal structures with a (binary-lattice) square morphology are indeed thermodynamically stable at high densities. The effect of the pod length-to-diameter ratio on the crystal structures was also considered and we used this to constructed the phase diagram for these hard octapods. In addition to the (binary-lattice) square crystal phase, a rhombic crystal and a hexagonal plastic-crystal (rotator) phase were obtained. Our phase diagram may prove instrumental in guiding future experimental studies. KEYWORDS: Octapods, nanocrystals, quasi-2D, self-assembly, anisotropy, colloids T he study of nanocrystal monolayers offers many opportunities for the creation of new materials with bulk properties that differ substantially from the materials that form by self-assembly in three dimensions. 1,2 This has led to a strong experimental and simulation interest in the behavior of nanocrystals in a (quasi-)2D geometry, that is, three-dimensional (3D) particles confined to a two-dimensional (2D) geometry. For instance, the seemingly simple system consisting of monodisperse hard disks in a 2D plane has sparked intense debate on the nature of the 2D solid−liquid phase transition. 3−6 In addition, experiments and simulations 7−14 showed that rod-and square-shaped convex anisotropic particles display a rich mesophase behavior when confined to a (quasi-)2D geometry.Advances in the synthesis of colloids and nanocrystals have resulted in monodisperse samples consisting of complex particles with anisotropic hard and soft interactions 15−21 and present many possibilities for further development in this field. Moreover, new simulation techniques are available to study the experimentally observed phenomenology for these new particles and to tackle the complex numerical problems such investigations bring about. 22−31 Only recently has the investigation into the phase behavior of anisotropic particles in (quasi-)2D by simulation been extended to the realm of nonconvex particles. 29 However, studying the phase behavior of nonconvex particles under confinement remains challenging due to geometric restrictions and the complex interactions between the particles. 32 Our group recently reported an experimental and simulation study of the hierarchical self-assembly of anisotropic branched colloidal nanocrystals, so-called octapods, into 3D superstructures in the liquid bulk phase. 20 In this Letter, we extend our findings to the formation of monolayers consisting of octapods, which were obtained by a deposition−evaporation procedure. In the experiments, we obtained monolay...

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supporting

confidence: 64%

Ordered Two-Dimensional Superstructures of Colloidal Octapod-Shaped Nanocrystals on Flat Substrates

Graaf²,

Qiao

et al. 2012

Nano Lett.

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“…3−5 Subsequently, these studies were extended to colloids with anisotropic shapes, such as rods and plates, 6,7 and also to a variety of colloidal interactions. 8 Attraction (depletion, 9−12 van der Waals, 13,14 or Coulomb 13,15 ) and/or repulsion (steric 16 or Coulomb 17 ) were applied to govern the colloidal self-assembly process. Additionally, recognition mechanisms based on particles with complementary shapes 18 or on Watson−Crick attraction between DNA strands 19−22 have led to an extended control over the self-organization process.…”

Section: ■ Introductionmentioning

confidence: 99%

Lyotropic Smectic B Phase Formed in Suspensions of Charged Colloidal Platelets

et al. 2012

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Here, we present the first observation of a smectic B (Sm B ) phase in a system of charged colloidal gibbsite platelets suspended in dimethyl sulfoxide (DMSO). The use of DMSO, a polar aprotic solvent, leads to a long range of the electrostatic Coulomb repulsion between platelets. We believe this to be responsible for the formation of the layered liquid crystalline phase consisting of hexagonally ordered particles, that is, the Sm B phase. We support our finding by highresolution X-ray scattering experiments, which additionally indicate a high degree of ordering in the Sm B phase. ■ INTRODUCTIONSelf-organization in colloidal suspensions leads to a fascinating range of colloidal crystal and liquid crystalline (LC) phases. 1,2 Initially attention of both experiments and simulations was focused on spherical particles interacting through hard-core repulsion. 3−5 Subsequently, these studies were extended to colloids with anisotropic shapes, such as rods and plates, 6,7 and also to a variety of colloidal interactions. 8 Attraction (depletion, 9−12 van der Waals, 13,14 or Coulomb 13,15 ) and/or repulsion (steric 16 or Coulomb 17 ) were applied to govern the colloidal self-assembly process. Additionally, recognition mechanisms based on particles with complementary shapes 18 or on Watson−Crick attraction between DNA strands 19−22 have led to an extended control over the self-organization process.LC phase formation in suspensions of hard colloidal discs has been studied theoretically, 23,24 experimentally 25 and using computer simulations. 26 Already in the 1940s Lars Onsager qualitatively predicted a transition from a disordered isotropic (I) to an orientationally ordered nematic (N) phase in suspensions of hard platelet-like particles. 27 At higher colloidal concentrations, platelets can also form a columnar (C) phase, with orientational and 2D positional ordering. Experimentally, both LC phases (N and C) were found only in a single hard platelet system, namely, that of sterically stabilized gibbsite (γ-Al(OH) 3 ) platelets. 25 Charged colloidal platelets have been studied mostly experimentally. In addition to the typical for platelets I−N−C phase sequence, a columnar nematic 28 and lamellar 29−32 phases were observed. Moreover, even chiral liquid crystals were found in aqueous suspensions of graphehe oxide sheets. 33 The enrichment of the phase diagram of charged platelets is clearly due to the electrostatic repulsion between the platelets. Recently, Morales-Anda et al. 34 presented Monte Carlo computer simulation results for a model system of charged colloidal platelets. While the authors predict a columnar nematic phase characterized by interpenetrating columns, no evidence for any layered LC phase, such as smectic or lamellar, in charged platelet suspensions was found.In this article, we show that increasing the range of the electrostatic Coulomb repulsion leads to the formation of a new and unexpected LC phase in colloidal platelet suspensions. Specifically, we study monodisperse rigid gibbsite platelets ...

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“…Colloidal NCs can also selfassemble into three-dimensionally ordered colloidal superparticles [131]. The geometry and properties of these superstructures can be tailored by the size, shape, composition and surface chemistry of the NC or hetero-NC building blocks [129][130][131][132][133][134][135][136][137][138]. In particular, surface ligands have been shown to have a dramatic impact on the directionality of the self-organization process [135,[139][140][141][142][143], leading in some cases to atomically aligned NC superlattices [135,139,143].…”

Section: Collective Effects In Nc Superstructures: When 1 1 1 Is Largmentioning

confidence: 99%

Excited-State Dynamics in Colloidal Semiconductor Nanocrystals

Rabouw

Donegá

2016

Photoactive Semiconductor Nanocrystal Quantum Dots

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Colloidal semiconductor nanocrystals have attracted continuous worldwide interest over the last three decades owing to their remarkable and unique sizeand shape-, dependent properties. The colloidal nature of these nanomaterials allows one to take full advantage of nanoscale effects to tailor their optoelectronic and physical-chemical properties, yielding materials that combine size-, shape-, and composition-dependent properties with easy surface manipulation and solution processing. These features have turned the study of colloidal semiconductor nanocrystals into a dynamic and multidisciplinary research field, with fascinating fundamental challenges and dazzling application prospects. This review focuses on the excited-state dynamics in these intriguing nanomaterials, covering a range of different relaxation mechanisms that span over 15 orders of magnitude, from a few femtoseconds to a few seconds after photoexcitation. In addition to reviewing the state of the art and highlighting the essential concepts in the field, we also discuss

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Hierarchical self-assembly of suspended branched colloidal nanocrystals into superlattice structures

Cited by 425 publications

References 35 publications

Ordered Two-Dimensional Superstructures of Colloidal Octapod-Shaped Nanocrystals on Flat Substrates

Ordered Two-Dimensional Superstructures of Colloidal Octapod-Shaped Nanocrystals on Flat Substrates

Lyotropic Smectic B Phase Formed in Suspensions of Charged Colloidal Platelets

Excited-State Dynamics in Colloidal Semiconductor Nanocrystals

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