Robust Phase Behavior of Model Transient Networks

Filali, M.; Ouazzani, Mohamed Jamil; Michel, Eric; Aznar, R.; Porte, and Grégoire; Appell, J.

doi:10.1021/jp0113073

Cited by 61 publications

(115 citation statements)

References 27 publications

(71 reference statements)

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“…Here, we review the theory of the structure and thermodynamic properties of equilibrium networks. This paper unifies concepts that have been previously discussed in several publications, each in different experimental contexts such as gels [1], worm-like micelles [2], microemulsions [2,3], dipolar liquids [4] and colloids [5,6]. In all these systems the networks consist of selfassembling, one-dimensional objects (e.g.…”

Section: Introductionmentioning

confidence: 62%

“…Due to the hydrophobic interaction, it is energetically preferable for the chain ends to reside inside the hydrophobic core of the microemulsion droplets, and to a first approximation one can neglect the very small number of free hydrophobic chain ends in contact with water and assume that all the polymer ends reside within the droplets. Thus, a given polymer chain can either connect two neighbouring droplets (which we shall term a 'bonding chain'), or loop on a single droplet, so that both of its ends reside inside the same drop [5]. The free energy difference between a looped polymer and a bonding one is largely determined by the difference in the number of spatial configurations available to a looped polymer compared with one that forms a bond between two drops.…”

Section: Network In Polymer-microemulsion Systemsmentioning

confidence: 99%

“…It has been found experimentally that as the ratio of the number of the polymers to the number of droplets is changed, the system undergoes two independent transitions: (i) a continuous fluid to gel transition, attributed to a formation of an infinite network (ii) a first-order thermodynamic phase transition, where the system separates into a dense system of tightly connected droplets, in equilibrium with a phase of dilute droplets, decorated with polymer loops [5].…”

Section: Network In Polymer-microemulsion Systemsmentioning

confidence: 99%

See 2 more Smart Citations

Entropic networks in colloidal, polymeric and amphiphilic systems

Zilman

Tlusty

Safran

2002

J. Phys.: Condens. Matter

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Self-assembly in soft-matter systems often results in the formation of locally cylindrical or chain-like structures. We review the theory of these systems whose large-scale structure and properties depend on whether the chains are finite, with end-caps or join to form junctions that result in networks. Physical examples discussed here include physical gels, wormlike micelles, dipolar fluids and microemulsions. In all these cases, the competition between endcaps and junctions results in an entropic phase separation into junction-rich and junction-poor phases, as recently observed by electron microscopy and seen in computer simulations. A simple model that accounts for these phenomena is reviewed. Extensions of these ideas can be applied to treat network formation and phase separation in a system of telechelic (hydrophobically tipped, hydrophilic) polymers and oil-in-water microemulsions, as observed in recent experiments.

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Section: Introductionmentioning

confidence: 62%

Section: Network In Polymer-microemulsion Systemsmentioning

confidence: 99%

Section: Network In Polymer-microemulsion Systemsmentioning

confidence: 99%

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Entropic networks in colloidal, polymeric and amphiphilic systems

Zilman

Tlusty

Safran

2002

J. Phys.: Condens. Matter

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“…Depending on the length of the alkyl end groups incorporated, hydrophobic aggregation is expected as it is known for previously studied linear and star like hydrophobically end-capped polymers. 1,3,16,35,[63][64][65][66] SANS experiments were exemplarily done on 1 wt% and 5 wt% solutions of polymer samples with dodecyl stickers (entries 4, 10 and 15, see Table 1) in order to learn about their structure in aqueous solution. The scattering curves (Fig.…”

Section: Self-assembly Of the Polymers In Aqueous Solutionmentioning

confidence: 99%

“…Typical rheology modifiers used are a,u-double hydrophobically end-capped hydrophilic polymers. [1][2][3][4][5][6][7][8][9][10][11] So far, these have been mostly polyethylene oxides (PEOs) end-capped with n-alkyl ethers, n-alkyl urethanes (HEURs), and fatty acid esters or, alternatively, PEOs bearing short hydrophobic polymer end blocks. 8 The thickening effect of these compounds has been studied intensely.…”

Section: Introductionmentioning

confidence: 99%

One-step RAFT synthesis of well-defined amphiphilic star polymers and their self-assembly in aqueous solution

et al. 2012

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Multifunctional chain transfer agents for RAFT polymerisation were designed for the one-step synthesis of amphiphilic star polymers. Thus, hydrophobically end-capped 3-and 4-arm star polymers, as well as linear ones for reference, were made of the hydrophilic monomer N,N-dimethylacrylamide (DMA) in high yield with molar masses up to 150 000 g mol À1, narrow molar mass distribution (PDI # 1.2) and high end group functionality ($90%). The associative telechelic polymers form transient networks of interconnected aggregates in aqueous solution, thus acting as efficient viscosity enhancers and rheology modifiers, eventually forming hydrogels. The combination of dynamic light scattering (DLS), small angle neutron scattering (SANS) and rheology experiments revealed that several molecular parameters control the structure and therefore the physical properties of the aggregates. In addition to the size of the hydrophilic block (maximum length for connection) and the length of the hydrophobic alkyl chain ends (stickiness), the number of arms (functionality) proved to be a key parameter.

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Attractive Pickering Emulsion Gels

Yang

et al. 2021

Advanced Materials

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Properties of emulsions highly depend on the interdroplet interactions and, thus, engineering interdroplet interactions at molecular scale are essential to achieve desired emulsion systems. Here, attractive Pickering emulsion gels (APEGs) are designed and prepared by bridging neighboring particle‐stabilized droplets via telechelic polymers. In the APEGs, each telechelic molecule with two amino end groups can simultaneously bind to two carboxyl functionalized nanoparticles in two neighboring droplets, forming a bridged network. The APEG systems show typical shear‐thinning behaviors and their viscoelastic properties are tunable by temperature, pH, and molecular weight of the telechelic polymers, making them ideal for direct 3D printing. The APEGs can be photopolymerized to prepare APEG‐templated porous materials and their microstructures can be tailored to optimize their performances, making the APEG systems promising for a wide range of applications.

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Robust Phase Behavior of Model Transient Networks

Cited by 61 publications

References 27 publications

Entropic networks in colloidal, polymeric and amphiphilic systems

Entropic networks in colloidal, polymeric and amphiphilic systems

One-step RAFT synthesis of well-defined amphiphilic star polymers and their self-assembly in aqueous solution

Attractive Pickering Emulsion Gels

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