Dylan Chase-Woods scite author profile

Membranes made of stacked layers of graphene oxide (GO) hold the tantalizing promise of revolutionizing desalination and water filtration if selective transport of molecules can be controlled. We present the findings of an integrated study that combines experiment and molecular dynamics simulation of water intercalated between GO layers. We simulated a range of hydration levels from 1 wt.% to 23.3 wt.% water. The interlayer spacing increased upon hydration from 0.8 nm to 1.1 nm. We also synthesized GO membranes that showed an increase in layer spacing from about 0.7 nm to 0.8 nm and an increase in mass of about 15% on hydration. Water diffusion through GO layers is an order of magnitude slower than that in bulk water, because of strong hydrogen bonded interactions. Most of the water molecules are bound to OH groups even at the highest hydration level. We observed large water clusters that could span graphitic regions, oxidized regions and holes that have been experimentally observed in GO. Slow interlayer diffusion can be consistent with experimentally observed water transport in GO if holes lead to a shorter path length than previously assumed and sorption serves as a key rate-limiting step.

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Graphene oxide membranes with high permeability and selectivity for dehumidification of air

Shin

Liu

Schwenzer

et al. 2016

Carbon

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Hierarchically stacked 2D graphene oxide (GO) membranes are a fascinating and promising new class of materials with the potential for radically improved water vapor/gas separation with excellent selectivity and high permeability. This paper details dehumidification results from flowing gas mixtures through free-standing GO membrane samples prepared by a casting method. The first demonstrated use of free-standing GO membranes for water vapor separation reveals outstanding water vapor permeability and H 2 O/N 2 selectivity. Free-standing GO membranes exhibit extremely high water vapor permeability of 1.82 x 10 5 Barrer and a water vapor permeance of 1.01 x 10-5 mol/m 2 sPa, while the nitrogen permeability was below the system's detection limit, yielding a selectivity >10 4 in 80% relative humidity (RH) air at 30.8 °C. The results show great potential for a range of energy conversion and environmental applications.

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Dylan Chase-Woods

Molecular Dynamics Simulations Reveal that Water Diffusion between Graphene Oxide Layers is Slow

Graphene oxide membranes with high permeability and selectivity for dehumidification of air

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