Mesoscopic structure prediction of nanoparticle assembly and coassembly: Theoretical foundation

Hur, Kahyun; Hennig, Richard G.; Escobedo, Fernando A.; Wiesner, Ulrich

doi:10.1063/1.3502680

Cited by 27 publications

(31 citation statements)

References 59 publications

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“…Tick marks in Fig. 1e for this scaling trace show expected peak positions for a G A lattice with I4 1 32 space group, with (q/q 100 ) 2 ¼ 2, 6,8,10,12,14,16,18,20,22,24,26,30,32,34, where the scattering vector q is defined by q ¼ 4 psiny/l, with scattering angle 2y, X-ray wavelength l and reciprocal vector, q 100 , describing the cubic lattice parameter. Expected and observed peak positions match well, suggesting that the SAXS trace of the hybrid is consistent with the G A morphology.…”

Section: Resultsmentioning

confidence: 99%

“…Here, we demonstrate how the combination of controlled NP synthesis, detailed structural analysis by transmission electron microtomography (TEMT) 15 , energy-dispersive X-ray spectroscopy (EDS) and percolation theory, as well as comparison with a recently developed self-consistent field theory (SCFT) 16,17 enabled highly ordered and porous 3D network formation of single and binary metal NPs from triblock terpolymer self-assembly with particle locations that can be rationalized. Analysis further provided insights into short-and long-range NP-NP correlations, and local and global contributions to structural chirality in an alternating gyroid (G A ) domain.…”

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confidence: 99%

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Linking experiment and theory for three-dimensional networked binary metal nanoparticle–triblock terpolymer superstructures

Hur

Sai

et al. 2014

Nat Commun

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Controlling superstructure of binary nanoparticle mixtures in three dimensions from selfassembly opens enormous opportunities for the design of materials with unique properties. Here we report on how the intimate coupling of synthesis, in-depth electron tomographic characterization and theory enables exquisite control of superstructure in highly ordered porous three-dimensional continuous networks from single and binary mixtures of metal nanoparticles with a triblock terpolymer. Poly(isoprene-block-styrene-block-(N,Ndimethylamino)ethyl methacrylate) is synthesized and used as structure-directing agent for ligand-stabilized platinum and gold nanoparticles. Quantitative analysis provides insights into short-and long-range nanoparticle-nanoparticle correlations, and local and global contributions to structural chirality in the networks. Results provide synthesis criteria for next-generation mesoporous network superstructures from binary nanoparticle mixtures for potential applications in areas including catalysis.

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Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

Linking experiment and theory for three-dimensional networked binary metal nanoparticle–triblock terpolymer superstructures

Hur

Sai

et al. 2014

Nat Commun

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“…Formation of these interconnected networks can be achieved with BCPs, but in the event that one of the functionalities requires an inorganic component, it is necessary to have a library of structures where the nanoparticles are selectively aggregated. BCP-templated nanocomposite structures, in which nanoparticles are forced into specific domains, have been reported both in simulations [44] and experiment, [45][46][47] but they have the same limitations as the conventional nanocomposites mentioned in the introduction (mixing, agglomeration and low inorganic volume fractions). An alternative route is to use HNPs where the hairs are BCPs [48,49] or liquid crystal mesogens [50,51] .…”

Section: Structure Of Hnps and Hnp Assembliesmentioning

confidence: 99%

Hairy nanoparticle assemblies as one-component functional polymer nanocomposites: opportunities and challenges

et al. 2013

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Over the past three decades, the combination of inorganic-nanoparticles and organic-polymers has led to a wide variety of advanced materials, including polymer nanocomposites (PNCs). Recently, synthetic innovations for attaching polymers to nanoparticles to create "hairy nanoparticles" (HNPs) has expanded opportunities in this field. In addition to nanoparticle compatibilization for traditional particle-matrix blending, neat-HNPs afford one-component hybrids, both in composition and properties, which avoids issues of mixing that plague traditional PNCs. Continuous improvements in purity, scalability, and theoretical foundations of structure-performance relationships are critical to achieving design control of neat-HNPs necessary for future applications, ranging from optical, energy, and sensor devices to lubricants, green-bodies, and structures.

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“…38 In the case of polymer nanocomposites the distribution of nanoparticles can be accounted for by combining SCFT with the density functional theory. 39,40 On the other hand, the accuracy of field-based techniques in describing the orientation of the anisotropic particles and, therefore, in predicting the macroscopic anisotropy of the composite is quite limited. As an alternative, hybrid particle-field approaches have been developed [41][42][43] that employ particle-to-field transformation for polymer chains but retain explicit treatment of nanoparticles.…”

Section: Introductionmentioning

confidence: 99%

Ordering of anisotropic nanoparticles in diblock copolymer lamellae: Simulations with dissipative particle dynamics and a molecular theory

Berezkin

Kudryavtsev

Gorkunov

et al. 2017

The Journal of Chemical Physics

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Short title: Ordering of anisotropic nanoparticles: Simulations and theory a) Corresponding author. Electronic mail: yar@ips.ac.ru 2 ABSTRACT Local distribution and orientation of anisotropic nanoparticles in microphase-separated symmetric diblock copolymers has been simulated using dissipative particle dynamics and analyzed with a molecular theory. It has been demonstrated that nanoparticles are characterized by a non-trivial orientational ordering in the lamellar phase due to their anisotropic interactions with isotropic monomer units. In the simulations, the maximum concentration and degree of ordering are attained for nonselective nanorods near the domain boundary. In this case the nanorods have a certain tendency to align parallel to the interface in the boundary region and perpendicular to it inside the domains. Similar orientation ordering of spherical nanoparticles located at the lamellar interface is predicted by the molecular theory which takes into account that the nanoparticles interact with monomer units via both isotropic and anisotropic potentials. Computer simulations enable one to study the effects of the nanorod concentration, length, stiffness, and selectivity of their interactions with the copolymer components on the phase stability and orientational order of nanoparticles. If the volume fraction of the nanorods is lower than 0.1, they have no effect on the copolymer transition from the disordered state into a lamellar microstructure. Increasing nanorod concentration or nanorod length results in clustering of the nanorods and eventually leads to a macrophase separation, whereas the copolymer preserves its lamellar morphology. Segregated nanorods of length close to the width of the diblock copolymer domains are stacked side by side into smectic layers that fill domain space. Thus, spontaneous organization and orientation of nanorods leads to a spatial modulation of anisotropic composite properties creating an opportunity to align block copolymers by external fields which may be important for various applications.

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Mesoscopic structure prediction of nanoparticle assembly and coassembly: Theoretical foundation

Cited by 27 publications

References 59 publications

Linking experiment and theory for three-dimensional networked binary metal nanoparticle–triblock terpolymer superstructures

Linking experiment and theory for three-dimensional networked binary metal nanoparticle–triblock terpolymer superstructures

Hairy nanoparticle assemblies as one-component functional polymer nanocomposites: opportunities and challenges

Ordering of anisotropic nanoparticles in diblock copolymer lamellae: Simulations with dissipative particle dynamics and a molecular theory

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