Atom‐Thick Membranes for Water Purification and Blue Energy Harvesting

Pakulski, Dawid; Czepa, Włodzimierz; Buffa, Stefano Del; Ciesielski, Artur; Samorı́, Paolo

doi:10.1002/adfm.201902394

Cited by 60 publications

(59 citation statements)

References 219 publications

(79 reference statements)

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“…Two‐dimensional (2D) materials with atomic thickness, exemplified by graphene oxide (GO), have emerged as promising nano‐building blocks for next‐generation high‐performance separation membranes due to their capability to construct ultrathin selective layer with controllably ordered interlayer nanochannels, featuring extraordinary permeation properties . Laminar GO membranes have demonstrated attractive gas separation efficiency owing to the sharp size‐exclusion effect from the well‐defined interlayer spacing . However, during the operation in aqueous environment, the hydrophilic GO interlayer channels can adsorb a large amount of water molecules, which subsequently lead to an enlarged interlayer spacing (swelling) or even membrane delamination .…”

Section: Introductionmentioning

confidence: 99%

Ultrafast water‐selective permeation through graphene oxide membrane with water transport promoters

et al. 2019

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Graphene oxide (GO), as a representative two-dimensional material, has shown great prospect in developing high-performance separation membranes via forming ordered and tunable nanochannels. However, for aqueous molecular separations, the implementation of an excellent separation performance remains a critical challenge due to the membrane swelling phenomenon and the trade-off effect between permeation flux and separation factor. Herein, a facile and tunable approach is presented for introducing water transport promoters into GO interlayer channels to construct water transport highways. The combination of covalently cross-linked channel structure, facilitated water-selective sorption, and expedited water-preferential diffusion overcome the trade-off effect, achieving a superior performance from an ultrathin GO membrane with a flux of 5.94 kg/m 2 •h and a water/butanol separation factor of 3,965, which exceeds the performance of state-of-the-art membranes for water/ butanol separation. The strategy proposed here is straightforward, holding great potential to produce high-efficiency GO and other two-dimensional (2D)-material membranes for precise aqueous molecular separations.

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Section: Introductionmentioning

confidence: 99%

Ultrafast water‐selective permeation through graphene oxide membrane with water transport promoters

et al. 2019

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“…15 for real demonstrations) [38][39][40][41][42][43][44][45] and fuel cells [51][52][53][54] for the hydrogen (H 2 ) or methanol economy and their associated mobility to stationary power stations, can cover the main energy needs of the city and transportation, respectively. Furthermore, demonstrated salinity gradient plants and streaming potential harvesters installed at rivers/sea boundaries, 49 as well as various smart ways of harvesting water energy such as evaporation-or moisture-based, 11,50 all enabled by GRM, can revolutionize the way grid-electricity is provided in the near future. few atomic layers (Fig.…”

Section: Overview Of Grm's Emerging Properties At 2d Limit Formulation Techniques Device Manufacturing and Main Applicationsmentioning

confidence: 99%

“…Although the aforementioned approaches are very appealing, they require external stimulus of pressure, salinity-gradient, or the development of sophisticated membranes, thereby restricting their current wide usage. 11,50,298 Other approaches exist with less demanding infrastructure requirements based on triboelectric, electrokinetic, or piezoelectric effects towards transforming the motion of water into electrical energy. 15,299 Specifically, an electronic double layer is formed at the interface between a charged solid surface and a fluid.…”

Section: Grm For Various Forms Of Water-energy Harvestingmentioning

confidence: 99%

Up-scalable emerging energy conversion technologies enabled by 2D materials: from miniature power harvesters towards grid-connected energy systems

Rogdakis

Karakostas

Kymakis

2021

Energy Environ. Sci.

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“…Osmotic power generation using 2D materials are also once of the good choice, to make thin layer by incorporating 2D materials, while interfacial polymerization, the membranes produce clean blue energy. In it possible due to materials' unique properties and novel transport mechanisms occurring at the nano and sub-nanometer length scale [55]. Two different polyethylene glycol (PET) of molecular weight 4,000 and 6,000 g/mol were used for the development of CA membranes by Sharma et al [56].…”

Section: Thin-film Composite (Tfc) Membranes For Energy Generationmentioning

confidence: 99%

Generation of Osmotic Power from Membrane Technology

Ingole

2020

The Handbook of Environmental Chemistry

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The whole world is facing challenges for energy supply due to the economic developments, increasing population because of the decrease in oil/gas reserves. Therefore, in current decades, alternative energy sources are in focus to fulfil the energy gap between energy demand and supply. Wind, solar, and biomass are good and sustainable energy sources buthave high installation costs. Henceforth, to find out the cheap, clean, safe, and adequate energy sources is still a prime challenge for the researchers. Power generation by using membrane technology is the new achievement in this list. From the last few decades, pressure-retarded osmosis (PRO) is involved to generate the power, and it offers the opportunity for utilizing osmotic pressure gradients for a wide range of applications. Generating power from the PRO is an emerging platform technology that produces high electric power. In this research area, the membrane science community has expanded huge attention, currently, polymer composite, and nanocomposite membranes are involved in osmosis power generation application. In this chapter, we discuss the treasured insights and tactics for the fabrication and design of highly active antifouling materials and membranes for pressure-retarded osmotic power generation.

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Atom‐Thick Membranes for Water Purification and Blue Energy Harvesting

Cited by 60 publications

References 219 publications

Ultrafast water‐selective permeation through graphene oxide membrane with water transport promoters

Ultrafast water‐selective permeation through graphene oxide membrane with water transport promoters

Up-scalable emerging energy conversion technologies enabled by 2D materials: from miniature power harvesters towards grid-connected energy systems

Generation of Osmotic Power from Membrane Technology

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