Adsorption, structure and dynamics of benzene in ordered and disordered porous carbons

Coasne, Benoît; Alba‐Simionesco, Christiane; Audonnet, Fabrice; Dosseh, Gilberte; Gubbins, Keith E.

doi:10.1039/c0cp02205e

Cited by 57 publications

(37 citation statements)

References 58 publications

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“…So far, a number of efficient absorbent materials, including clay, [1] carbon nanotubes, [2,3] organicinorganic hydrids, [4] zeolites, [5] and activated carbon, [6,7] have been developed. However, these materials suffer from a number of drawbacks, such as poor selectivity and low absorption capacities, due to their weak affinity to organics or oils.…”

Section: Introductionmentioning

confidence: 99%

Superhydrophobic Activated Carbon‐Coated Sponges for Separation and Absorption

Sun¹,

An²,

Zhu³

et al. 2013

ChemSusChem

194

105

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Highly porous activated carbon with a large surface area and pore volume was synthesized by KOH activation using commercially available activated carbon as a precursor. By modification with polydimethylsiloxane (PDMS), highly porous activated carbon showed superhydrophobicity with a water contact angle of 163.6°. The changes in wettability of PDMS‐ treated highly porous activated carbon were attributed to the deposition of a low‐surface‐energy silicon coating onto activated carbon (confirmed by X‐ray photoelectron spectroscopy), which had microporous characteristics (confirmed by XRD, SEM, and TEM analyses). Using an easy dip‐coating method, superhydrophobic activated carbon‐coated sponges were also fabricated; those exhibited excellent absorption selectivity for the removal of a wide range of organics and oils from water, and also recyclability, thus showing great potential as efficient absorbents for the large‐scale removal of organic contaminants or oil spills from water.

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Section: Introductionmentioning

confidence: 99%

Superhydrophobic Activated Carbon‐Coated Sponges for Separation and Absorption

Sun¹,

An²,

Zhu³

et al. 2013

ChemSusChem

194

105

View full text Add to dashboard Cite

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“…[1,2] To address these water pollution issues, absorption technologies are considered one of the most useful approaches. To date, a number of absorbents including clay, [3] active carbon, [4,5] polymers, [6][7][8] and carbon nanotubes [9] have been developed for removal of oil spills or organic contaminants from water. However, these absorbent materials have their respective drawbacks such as poor selectivity and limited working capacity, which limit their practical use on a large scale.…”

Section: Introductionmentioning

confidence: 99%

Superhydrophobic Mesoporous Graphene for Separation and Absorption

et al. 2013

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Mesoporous graphene with a surface area of 306 m2 g−1 was synthesized by employing CaCO3 microspheres as hard templates. By surface modification with polydimethylsiloxane (PDMS) through chemical vapor deposition, the wettability of as‐treated mesoporous graphene can be tailored to be superhydrophobic to water while superoleophilic to oils. The deposition of the low‐surface‐energy silicon‐coating originated from PDMS pyrolysis on porous graphene was confirmed by X‐ray photoelectron spectroscopy. As a result of its porous structures and excellent surface superhydrophobicity, the PDMS‐treated mesoporous graphene exhibits good selectivity, excellent recyclability, and good absorption performance (up to 66 g g−1) for a wide range of oils and organic solvents. Thus, leading to potential use in a variety of applications such as water treatment and purification as well as cleanup of oil spills.

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“…The latter is modeled as a slit-pore, i.e., a sandwich geometry, using a 9-3 LennardJones wall potential. The pore geometry is ideal for exploring the physics of confinement, which can be difficult to extract from experiments on porous materials that often have a complex distribution of pore sizes, geometries, and fluid-pore interactions 9,40 . The possible effects of corrugation and realistic pore geometries and interactions on scaling behavior are discussed in Refs.…”

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confidence: 99%

Predicting How Nanoconfinement Changes the Relaxation Time of a Supercooled Liquid

et al. 2013

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The properties of nanoconfined fluids can be strikingly different from those of bulk liquids. A basic unanswered question is whether the equilibrium and dynamic consequences of confinement are related to each other in a simple way. We study this question by simulation of a liquid comprising asymmetric dumbbell-shaped molecules, which can be deeply supercooled without crystallizing. We find that the dimensionless structural relaxation times − spanning six decades as a function of temperature, density, and degree of confinement − collapse when plotted versus excess entropy. The data also collapse when plotted versus excess isochoric heat capacity, a behaviour that follows from the existence of isomorphs in the bulk and confined states.That confined liquids microscopically relax and flow with different characteristic time scales than bulk liquids is hardly surprising. Confining boundaries bias the spatial distribution of the constituent molecules and the ways by which those molecules can dynamically rearrange. These effects play important roles in the design of coating, nanopatterning, and nanomanufacturing technologies 1,2 . As a result, they have already been experimentally characterized for a wide variety of material systems, including small-molecule fluids 3-10 , polymers 11-16 , ionic liquids 17 , liquid crystals 18 , and dense colloidal suspensions [19][20][21][22][23] , and studied extensively via molecular simulations 22,24-31 . Recent reviews of confined-liquid behavior may be found in, e.g., Refs. 10,32 .Unfortunately, successful theories for predicting the dynamics of inhomogeneous fluids have been slower to emerge. Here, we explore the possibility of a novel approach for predicting how confinement affects the dynamics of viscous fluids. The central idea is motivated by the observation from molecular simulations that, under equilibrium conditions, key dimensionless "reduced" quantities for confined fluids closely correspond to those of homogeneous bulk fluids with the same excess entropy 33-37 (relative to an ideal gas at the same density and temperature). The excess entropy can be computed using Monte Carlo methods 36 or predicted from classical density-functional theories 35,38 . An open question is whether this observed correspondence between dynamics and excess entropy applies for fluids in deeply supercooled liquid states approaching the glass transition, where highly nontrivial dynamic effects of confinement are observed. Another open question is whether thermodynamic properties other than the excess entropy can be used to predict the dynamics in confinement.To investigate these questions we study the behavior of a glass-former comprising asymmetric dumbbell-shaped molecules 39 . This model is perhaps the simplest singlecomponent system that avoids freezing upon cooling or compression in confinement, allowing for a systematic comparison of the properties of supercooled states in both bulk and confined geometries. The latter is modeled as a slit-pore, i.e., a sandwich geometry, using a 9-3 LennardJo...

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Adsorption, structure and dynamics of benzene in ordered and disordered porous carbons

Cited by 57 publications

References 58 publications

Superhydrophobic Activated Carbon‐Coated Sponges for Separation and Absorption

Superhydrophobic Activated Carbon‐Coated Sponges for Separation and Absorption

Superhydrophobic Mesoporous Graphene for Separation and Absorption

Predicting How Nanoconfinement Changes the Relaxation Time of a Supercooled Liquid

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