Size effect in ion transport through angstrom-scale slits

Esfandiar, Ali; Radha, Boya; Wang, FengChao; Yang, Qiong; Hu, Sheng; Garaj, Slaven; Nair, R. R.; Geǐm, A. K.; Gopinadhan, K.

doi:10.1126/science.aan5275

Cited by 442 publications

(580 citation statements)

References 36 publications

(104 reference statements)

Supporting

Mentioning

539

Contrasting

Unclassified

Order By: Relevance

“…[5] Tw o-dimensional materials, [6] for example graphene and graphene oxide (GO), would be the ultimate step for such membranes,a nd nanosheets with similar 2D structures have been assembled into nano-channeled membranes,ahot topic of scientific research. [9] These nanosheet membranes already have demonstrated the desired advantages,s uch as outstanding separation performance,flexibility,and interesting nanoscale fluidic properties. [8] Recently,G eim et al described the ions transportation properties through angstrom-scale graphene slits.…”

mentioning

confidence: 99%

“…[8] Recently,G eim et al described the ions transportation properties through angstrom-scale graphene slits. [9] These nanosheet membranes already have demonstrated the desired advantages,s uch as outstanding separation performance,flexibility,and interesting nanoscale fluidic properties. [6] Tw od imensional carbon nitride (C 3 N 4 ) materials are another obvious choice with inherent lateral porosity,and it already attracting broad interest with its broad applications in sensing,b io-imaging,n ovel solar energy exploitation, as well as photocatalysis.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Nanofluidic Ion Transport and Energy Conversion through Ultrathin Free‐Standing Polymeric Carbon Nitride Membranes

et al. 2018

View full text Add to dashboard Cite

Ions transport through confined space with characteristic dimensions comparable to the Debye length has many applications, for example, in water desalination, dialysis, and energy conversion. However, existing 2D/3D smart porous membranes for ions transport and further applications are fragile, thermolabile, and/or difficult to scale up, limiting their practical applicability. Now, polymeric carbon nitride alternatively allows the creation of an ultrathin free-standing carbon nitride membrane (UFSCNM), which can be fabricated by simple CVD polymerization and exhibits excellent nanofluidic ion-transport properties. The surface-charge-governed ion transport also endows such UFSCNMs with the function of converting salinity gradients into electric energy. With advantages of low cost, facile fabrication, and the ease of scale up while supporting high ionic currents, UFSCNM can be considered as an alternative for energy conversion systems and new ionic devices.

show abstract

mentioning

confidence: 99%

mentioning

confidence: 99%

Nanofluidic Ion Transport and Energy Conversion through Ultrathin Free‐Standing Polymeric Carbon Nitride Membranes

et al. 2018

View full text Add to dashboard Cite

show abstract

“…Mass transfer through nanoconfined pores,s lits,t ubes,o r channels is vital to many applications,s uch as catalysis,f uel cell systems,a nd membrane separation. [1] Recently,2 D lamellar membranes with highly efficient mass transfer ability exhibit distinct superiority in hydrogen production, water purification, organic recycling,and desalination, as compared to the state-of-the-art polymeric membranes. [2] However,the underlying molecular-level origin is rarely explored.…”

mentioning

confidence: 99%

“…In contrast, nonpolar molecules with disordered configuration in both hydrophilic and hydrophobic nanochannels have comparable permeance.T wo phenomenological transport models correlate the permeance with the mass transport mechanism of molecules that display ordered and disordered configuration.Mass transfer through nanoconfined pores,s lits,t ubes,o r channels is vital to many applications,s uch as catalysis,f uel cell systems,a nd membrane separation. [1] Recently,2 D lamellar membranes with highly efficient mass transfer ability exhibit distinct superiority in hydrogen production, water purification, organic recycling,and desalination, as compared to the state-of-the-art polymeric membranes. [2] However,the underlying molecular-level origin is rarely explored.…”

mentioning

confidence: 99%

Elucidating Ultrafast Molecular Permeation through Well‐Defined 2D Nanochannels of Lamellar Membranes

Cui

et al. 2019

Angew Chem Int Ed

View full text Add to dashboard Cite

Lamellar membranes with well‐defined 2D nanochannels show fast, selective permeation, but the underlying molecular transport mechanism is unexplored. Now, regular robust MXene Ti3C2Tx lamellar membranes are prepared, and the size and wettability of nanochannels are manipulated by chemically grafted hydrophilic (−NH2) or hydrophobic (−C6H5, −C12H25) groups. These nanochannels have a sharp difference in mass transfer behavior. Hydrophilic nanochannels, in which polar molecules form orderly aligned aggregates along channel walls, impart ultrahigh permeance (>3000 L m−2 h−1 bar−1), which is more than three times higher than that in hydrophobic nanochannels with disordered molecular configuration. In contrast, nonpolar molecules with disordered configuration in both hydrophilic and hydrophobic nanochannels have comparable permeance. Two phenomenological transport models correlate the permeance with the mass transport mechanism of molecules that display ordered and disordered configuration.

show abstract

“…[4] On the other hand, graphene oxide contains plentyo fr eactive oxygen groups (À COOH, ÀOH, carbonyl, and epoxy), which provides possibility for chemical modificationa nd produces functional materials for aw ide range of applications. [5] In particular,t hese GOs have been demonstrated to efficiently separate various materials such as cations, [6] gases, [7] and organic molecules [8] because of their properties such as large surfacea rea, tunable interactive sites, as well as adjustable interlayer spacing. [9] Chiral molecules, including polymers [10] and biomolecules, [11] have also been utilized to functionalize these graphene oxides and show typical enantioselective interaction towardg uest enantiomers.…”

mentioning

confidence: 99%

β‐Cyclodextrin Functionalized Nanoporous Graphene Oxides for Efficient Resolution of Asparagine Enantiomers

Qie

Guo

et al. 2018

Chemistry An Asian Journal

View full text Add to dashboard Cite

Efficient resolution of racemic mixture has long been an attractive but challenging subject since Pasteur separated tartrate enantiomers in 19 century. Graphene oxide (GO) could be flexibly functionalized by using a variety of chiral host molecules and therefore, was expected to show excellent enantioselective resolution performance. However, this combination with efficient enantioselective resolution capability has been scarcely demonstrated. Here, nanoporous graphene oxides were produced and then covalently functionalized by using a chiral host material-β-cyclodextrin (β-CD). This chiral GO displayed enantioselective affinity toward the l-enantiomers of amino acids. In particular, >99 % of l-asparagine (Asn) was captured in a racemic solution of Asn while the adsorption of d-enantiomer was not observed. This remarkable resolution performance was subsequently modelled by using an attach-pull-release dynamic method. We expect this preliminary concept could be expanded to other chiral host molecules and be employed to current membrane separation technologies and finally show practical use for many other racemates.

show abstract

Size effect in ion transport through angstrom-scale slits

Cited by 442 publications

References 36 publications

Nanofluidic Ion Transport and Energy Conversion through Ultrathin Free‐Standing Polymeric Carbon Nitride Membranes

Nanofluidic Ion Transport and Energy Conversion through Ultrathin Free‐Standing Polymeric Carbon Nitride Membranes

Elucidating Ultrafast Molecular Permeation through Well‐Defined 2D Nanochannels of Lamellar Membranes

β‐Cyclodextrin Functionalized Nanoporous Graphene Oxides for Efficient Resolution of Asparagine Enantiomers

Contact Info

Product

Resources

About