Bridging length scales in colloidal liquids and interfaces from near-critical divergence to single particles

Royall, C. Patrick; Aarts, Dirk G. A. L.; Tanaka, Hajime

doi:10.1038/nphys679

Cited by 52 publications

(30 citation statements)

References 30 publications

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“…At elevated T , measurements of γ(q; T ) using GISAXS are challenging due to the significant vapour density. However, -v-like interfaces in suitable colloidal suspensions can be studied well [48] even close to criticality [49], which allows one to analyse γ(q; T ) along the lines presented here.…”

Section: Definition Of γ(Q)-mentioning

confidence: 99%

Enhanced wavelength-dependent surface tension of liquid-vapour interfaces

Höfling¹,

Dietrich²

2015

EPL

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Due to the simultaneous presence of bulk-like and interfacial fluctuations the understanding of the structure of liquid-vapour interfaces poses a long-lasting and ongoing challenge for experiments, theory, and simulations. We provide a new analysis of this topic by combining high-quality simulation data for Lennard-Jones fluids with an unambiguous definition of the wavenumber-dependent surface tension γ(q) based on the two-point correlation function of the fluid. Upon raising the temperature, γ(q) develops a maximum at short wavelengths. We compare these results with predictions from density functional theory. Our analysis has repercussions for the interpretation of grazing-incidence small-angle X-ray scattering (GISAXS) at liquid interfaces.

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Section: Definition Of γ(Q)-mentioning

confidence: 99%

Enhanced wavelength-dependent surface tension of liquid-vapour interfaces

Höfling¹,

Dietrich²

2015

EPL

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“…[29][30][31] This development means that the structure of experimental systems that display Brownian motion can now be analysed with higher-order structural detection algorithms, with interest in, for example, colloidal gels, 32 glasses, 29 and critical fluctuations. 33 Here we describe a recent addition to the collection of high-order structural detection algorithms, the topological cluster classification (TCC) algorithm. This algorithm has been used to investigate higher-order structure in colloidal 32,34 and molecular 35 gels, colloid-polymer mixtures, 36 colloidal clusters, [37][38][39] simple liquids, 60 liquidvapor interfaces, 40 supercooled liquids, [41][42][43] and crystallising fluids.…”

Section: Introductionmentioning

confidence: 99%

Identification of structure in condensed matter with the topological cluster classification

Malins¹,

Williams²,

Eggers³

et al. 2013

The Journal of Chemical Physics

142

197

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We describe the topological cluster classification (TCC) algorithm. The TCC detects local structures with bond topologies similar to isolated clusters which minimise the potential energy for a number of monatomic and binary simple liquids with m ≤ 13 particles. We detail a modified Voronoi bond detection method that optimizes the cluster detection. The method to identify each cluster is outlined, and a test example of Lennard-Jones liquid and crystal phases is considered and critically examined.

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“…The length scale of forces generated by polymer addition can be varied by the degree of polymerization, the concentration, and the polymer structure. 18 In a recent publication, Feng et al 23 reported interesting reentrant flocculation behavior of colloidal particles in an aqueous dispersion containing polymers. Several different polymer and particle combinations were investigated, but the ones displaying the re-entrant behavior had one common property: a solvent (water) that becomes poorer (for the polymer) as the temperature was increased.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Colloidal dispersions have been the subject of many studies, with focus ranging from stability and drug delivery, to self-assembly, patch formation, and so on. − The stability of such dispersions can often be controlled by pH and temperature variation, or with additives, such as salt or polymers. − One advantage in a system where polymers are used is their ability to mediate attractive, as well as repulsive, interactions between the particles, depending on parameters such as polymer length, solvent quality, or the presence of grafting bonds to the particles. This may facilitate a controlled stability. − Crystallization of colloidal particles has also been investigated in many soft matter studies, and the coexistence between “gas” and ”liquid” phases can often be regulated by polymer properties. , Previous work , has established thermoresponsive aggregation, or cluster formation, in aqueous dispersions containing polystyrene (PS) particles, carrying a layer of grafted short polyethylene glycol (PEG) chains. A temperature increase from an ambient value, at which the dispersion remained sterically stabilized, caused a reduced solubility of the polymer grafts, which eventually resulted in gelation, aggregation, or cluster formation.…”

Section: Introductionmentioning

confidence: 99%

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From Attraction to Repulsion to Attraction: Non-monotonic Temperature Dependence of Polymer-Mediated Interactions in Colloidal Dispersions

2021

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In this work, we have synthesized polystyrene particles that carry short end-grafted polyethylene glycol (PEG) chains. We then added dissolved 100 kDa PEG polymers and monitored potential flocculation by confocal microscopy. Qualitative predictions, based on previous theoretical developments in this field (Xie, F.; et al. Soft Matter 2016, 12, 658), suggest a non-monotonic temperature response. These theories propose that the “free” (dissolved) polymers will mediate attractive depletion interactions at room temperature, with a concomitant clustering/flocculation at a sufficiently high polymer concentration. At high temperatures, where the solvent is poorer, this is predicted to be replaced by attractive bridging interactions, again resulting in particle condensation. Interestingly enough, our theoretical framework, based on classical density functional theory, predicts an intermediate temperature regime where the polymer-mediated interactions are repulsive! This obviously implies a homogeneous dispersion in this regime. These qualitative predictions have been experimentally tested and confirmed in this work, where flocs of particles start to form at room temperature for a high enough polymer dosage. At temperatures near 45 °C, the flocs redisperse, and we obtain a homogeneous sample. However, samples at about 75 °C will again display clusters and eventually phase separation. Using results from these studies, we have been able to fine-tune parameters of our coarse-grained theoretical model, resulting in predictions of temperature-dependent stability that display semiquantitative accuracy. A crucial aspect is that under “intermediate” conditions, where the polymers neither adsorb nor desorb at the particle surfaces, the polymer-mediated equilibrium interaction is repulsive.

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Bridging length scales in colloidal liquids and interfaces from near-critical divergence to single particles

Cited by 52 publications

References 30 publications

Enhanced wavelength-dependent surface tension of liquid-vapour interfaces

Enhanced wavelength-dependent surface tension of liquid-vapour interfaces

Identification of structure in condensed matter with the topological cluster classification

From Attraction to Repulsion to Attraction: Non-monotonic Temperature Dependence of Polymer-Mediated Interactions in Colloidal Dispersions

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