Precise and Ultrafast Molecular Sieving Through Graphene Oxide Membranes

Joshi, Rakesh; Carbone, Paola; Wang, FengChao; Kravets, V. G.; Su, Yang; Grigorieva, I. V.; Wu, HengAn; Geǐm, A. K.; Nair, R. R.

doi:10.1126/science.1245711

Cited by 2,168 publications

(1,896 citation statements)

References 52 publications

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“…However, at the gap between the edges of non-interlocked neighboring GO sheets and, at the cracks and holes of the sheet, they can diffuse perpendicular to the GO sheets and permeate through the membrane. 18,55 Thus, such structural defects supplement the role of the interlayer nanochannels in the separation of the ions and molecules. Moreover, oxygen-containing functional groups on the GO sheets are ionized in the wet state and thus negatively charged.…”

Section: Multilayer Graphene Desalination Membranesmentioning

confidence: 99%

“…55 In this regard, the interlayer spacing of the GO sheets has a key role. Although in graphite, which is composed of pristine graphene sheets, the interlayer spacing in dry state is only 3.4 Å, the presence of oxygen-containing functional groups on the GO sheets increases this spacing to 6-7 Å.…”

Section: Multilayer Graphene Desalination Membranesmentioning

confidence: 99%

“…18 Such promising features make multilayer GO structure an ideal candidate for the production of advanced ionic and molecular sieving membranes for desalination. 1,4, [53][54][55][56] Theoretical considerations. According to molecular simulations, water flows at a very high rate in planar graphene nanochannels because of the very large slip length and low friction on graphene sheets.…”

Section: Multilayer Graphene Desalination Membranesmentioning

confidence: 99%

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Graphene membranes for water desalination

2017

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Extensive environmental pollution caused by worldwide industrialization and population growth has led to a water shortage. This problem lowers the quality of human life and wastes a large amount of money worldwide each year due to the related consequences. One main solution for this challenge is water purification. State-of-the-art water purification necessitates the implementation of novel materials and technologies that are cost and energy efficient. In this regard, graphene nanomaterials, with their unique physicochemical properties, are an optimum choice. These materials offer extraordinarily high surface area, mechanical durability, atomic thickness, nanosized pores and reactivity toward polar and non-polar water pollutants. These characteristics impart high selectivity and water permeability, and thus provide excellent water purification efficiency. This review introduces the potential of graphene membranes for water desalination. Although literature reviews have mostly concerned graphene's capability for the adsorption and photocatalysis of water pollutants, updated knowledge related to its sieving properties is quite limited. NPG Asia Materials (2017) 9, e427; doi:10.1038/am.2017.135; published online 25 August 2017 INTRODUCTION Currently,~1.2 billion people around the world are suffering from a shortage of water and its adverse consequences on health, food and energy. 1,2 On one hand, population growth, increased industrialization and greater energy needs and, on the other hand, loss of snowmelt, shrinkage of glaciers and so on will worsen this situation in upcoming years. As estimated by the world water council, the number of affected people will rise to 3.9 billion in the coming decades. 2,3 One of the most promising approaches to alleviate the water shortage, desalination can increase the water supply beyond what is available from the hydrological cycle. 4 Seawater desalination indeed provides an infinite, steady supply of high-quality water that does not harm natural freshwater ecosystems.Seawater comprises a vast supply of water (97.5% of all water on the planet). Thus, the growth of the installation of seawater desalination facilities in the past decade to circumvent water shortage problems in water-stressed countries has progressed quickly. In 2016, the global water production by desalination was estimated to be 38 billion cubic meter per year, that is, two times higher than that in 2008. 5 So far, seawater desalination has been mainly performed via multistage flash distillation and reverse osmosis (RO). 6 Mostly in the arid Persian Gulf countries, desalination plants perform based on heating and then condensing seawater. This kind of desalination plant consumes large amounts of thermal and electric energy, thus emitting greenhouse gases extensively. 7 In addition to this non-economical and non-ecofriendly version of desalination plants, the main type of desalination plants constructed in the past two decades, as well as future planned ones, are based on RO technology (Figure 1). 8

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Section: Multilayer Graphene Desalination Membranesmentioning

confidence: 99%

Section: Multilayer Graphene Desalination Membranesmentioning

confidence: 99%

Section: Multilayer Graphene Desalination Membranesmentioning

confidence: 99%

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Graphene membranes for water desalination

2017

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“…For example, it was found that sub-micrometer-thick graphene oxide (GO) membranes were almost impermeable to liquids, vapors, or gases but allowed unimpeded permeation of water [1] because of the nearly frictionless flow of water molecules through the two-dimensional hydrophobic nonoxidized capillaries. Moreover, it was further demonstrated that GO membranes could act as molecular sieves to block all solutes with hydrated radii > 0.45 nm when immersed in water [2], in which size exclusion appears to account for this behavior. For smaller sizefitted solutes that can enter in nanochannels, GO membrane could achieve more accurate ion selectivity via the diverse interactions between ions and sp 2 clusters or oxygen-containing functional groups on GO basal planes [3].…”

Section: Graphene-based Membranes For Organic Solvent Nanofiltrationmentioning

confidence: 99%

Graphene-based membranes for organic solvent nanofiltration

Zhu

2018

Sci. China Mater.

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Different from the conventional polymeric separation membranes having a wide flexible-pore size distribution, layered graphene-based films with interconnected nanochannels provide narrowly well-defined nanopore-size distribution and thus are extremely advantageous for precise liquid filtration and separation. Recently, considerable progress has been achieved in graphene-based membranes for molecular sieving in water. For example, it was found that sub-micrometer-thick graphene oxide (GO) membranes were almost impermeable to liquids, vapors, or gases but allowed unimpeded permeation of water [1] because of the nearly frictionless flow of water molecules through the two-dimensional hydrophobic nonoxidized capillaries. Moreover, it was further demonstrated that GO membranes could act as molecular sieves to block all solutes with hydrated radii > 0.45 nm when immersed in water [2], in which size exclusion appears to account for this behavior. For smaller sizefitted solutes that can enter in nanochannels, GO membrane could achieve more accurate ion selectivity via the diverse interactions between ions and sp 2 clusters or oxygen-containing functional groups on GO basal planes [3].The findings mentioned above implicate that GO membranes are extremely promising for a broad spectrum of separation due to their tunability in pore size to remove various target solutes, including expansion by inserting large spacers and decrease by reducing, crosslinking, etc. [4]. Consequently, most existing studies focused on the adjustment of pore structure for high flux and retention. The representative novel nanostrandchanneled GO membrane exhibited 10-time higher permeance than the conventional polymeric separation membranes [5]. However, graphene-based membranes confronted with some crucial challenges in practical industrial applications, such as scale-up of membranes to large-area, the narrow interlayer spacing in water for highly effective desalination, molecular transport mechanism confined in nanocapillaries, stability in water for long periods of time, especially graphene-based membranes used for organic solvent nanofiltration (OSN).Over the past two years, some successes have been achieved in these aspects. Large-area GO membranes were accessible by an industrially adaptable method of blade coating, which aligned the discotic nematic phase of GO on a porous support [6]. The highly ordered GO membranes formed organized channels and demonstrated outstanding water permeability. Another alternative method is spray coating GO aqueous dispersion and few-layered graphene to yield robust membranes that are easy and scalable to produce [7]. The hybrid layered membranes maintained effective NaCl rejection near 85% and 96% for an anionic dye. The achievement of 97% high rejection for NaCl is a significant breakthrough due to the controllable limited swelling of GO laminates in water [8]. The ion permeation rates were found to decrease exponentially with decreasing sieve size because of dehydration effects whereas water transport was sligh...

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“…A schematic representation of the desalination of salt water is shown in Figure 6. R. K. Joshi et al studied the permeation of water through micrometer thick GO laminates prepared using a vacuum filtration technique (112). The GO laminates act like a molecular sieve which block all solute particles possessing a hydrated diameter greater than 4.5 Å.…”

Section: Graphene Carbon Nanotubes and Their Composites Used In Watmentioning

confidence: 99%

Nanotechnology Solutions for Global Water Challenges

McGuinness

Garvey

Whelan

et al. 2015

ACS Symposium Series

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The lack of clean and safe drinking water is responsible for more deaths than war, terrorism and weapons of mass destruction combined. This suggests contaminated water poses a significant threat to human health and welfare. In addition, standard water disinfection approaches such as sedimentation, filtration, and chemical or biological degradation are not fully capable of destroying emerging contaminants (e.g. pesticides, pharmaceutical waste products) or certain types of bacteria (e.g. Cryptosporidium parvum). Nanomaterials and nanotechnology based devices can potentially be employed to solve the challenges posed by various contaminants and

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Precise and Ultrafast Molecular Sieving Through Graphene Oxide Membranes

Cited by 2,168 publications

References 52 publications

Graphene membranes for water desalination

Graphene membranes for water desalination

Graphene-based membranes for organic solvent nanofiltration

Nanotechnology Solutions for Global Water Challenges

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