Angstrofluidics: Walking to the Limit

You, Yi; Ismail, Abdulghani; Nam, Gwang‐Hyeon; Goutham, Solleti; Keerthi, Ashok; Radha, Boya

doi:10.1146/annurev-matsci-081320-032747

Cited by 29 publications

(15 citation statements)

References 175 publications

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“…13,110−113,131−135 Nanofluidic channels made from twodimensional crystals enabled the fabrication of devices that relied on the interfacial liquid water properties. 14,46 Those devices were also applied to study the interaction of water with graphene and hexagonal boron nitride surfaces. 65,136 Water Contact Angle.…”

Section: Methods To Study Interfacial Water On Graphite and 2d Layere...mentioning

confidence: 99%

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Interfacial Liquid Water on Graphite, Graphene, and 2D Materials

García

2022

ACS Nano

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The optical, electronic, and mechanical properties of graphite, fewlayer, and two-dimensional (2D) materials have prompted a considerable number of applications. Biosensing, energy storage, and water desalination illustrate applications that require a molecular-scale understanding of the interfacial water structure on 2D materials. This review introduces the most recent experimental and theoretical advances on the structure of interfacial liquid water on graphite-like and 2D materials surfaces. On pristine conditions, atomic-scale resolution experiments revealed the existence of 1−3 hydration layers. Those layers were separated by ∼0.3 nm. The experimental data were supported by molecular dynamics simulations. However, under standard working conditions, atomic-scale resolution experiments revealed the presence of 2−3 hydrocarbon layers. Those layers were separated by ∼0.5 nm. Linear alkanes were the dominant molecular specie within the hydrocarbon layers. Paradoxically, the interface of an aged 2D material surface immersed in water does not have water molecules on its vicinity. Free-energy considerations favored the replacement of water by alkanes.

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Section: Methods To Study Interfacial Water On Graphite and 2d Layere...mentioning

confidence: 99%

“…The interaction of liquid water with graphite-like and 2D materials has generated scientific topics, among them, the wetting transparency of graphene, − ,− the water-flow in nanofluidic channels and nanopores, ,− or the ubiquitous presence of organic adsorbates at the graphite–liquid-water interface. ,− ,− …”

Section: Introductionmentioning

confidence: 99%

Interfacial Liquid Water on Graphite, Graphene, and 2D Materials

García

2022

ACS Nano

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“…Furthermore, analogous to biological potassium ion pump, MXene-based membranes showed spontaneous ionic motion under pressure in conjunction with higher K + /Na + selectivity . A literature review reveals that nanoconfined ion transport in stacked MXene membranes can be regulated by external stimuli, suggesting that 2D MXene material-based membranes can be utilized in the future to comprehend and innovate modern ionic devices, such as ionic diodes and pumps. ,− …”

Section: Challenges and Outlookmentioning

confidence: 99%

Ion-Selective Separation Using MXene-Based Membranes: A Review

Hong

Marzooqi

El‐Demellawi

et al. 2023

ACS Materials Lett.

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Global lack of clean water makes it essential that new technologies are developed for separation of pollutants from raw water. Membrane separation has arisen as a promising solution among other conventional liquid-separation processes, such as evaporation, distillation, and crystallization. Synthetic polymer membranes have been emphasized as an important component in liquid separation processes due to their outstanding water/salt selectivity and ionic conductivity. However, their inherent trade-off between selectivity and permeability has remained a challenge for polymeric membranes. Recently, two-dimensional nanomaterials have been actively sought after as an alternative to polymeric membranes. MXene, a new type of nanomaterial, has been attracting considerable attention as a building block for nanostructured separation membranes. Due to several appealing features, such as their surface functional groups with negative charge, they have been used in size-, charge-, and adsorption-selective separation for different ions or molecules. This article reviews recent progress in MXene-based membranes, with a particular emphasis on ion-selective separation and their applications for water purification including salt rejection, reverse electrodialysis, or heavy metal adsorption. Lastly, the challenges and future directions of MXene-based ion-selective membranes are discussed.

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“…I on transport plays an important role in the process of signal transfer and energy conversion of living matter, 1−4 arousing the development of artificial ion channels which mimic biological protein channels to achieve specific functionalities. 5−9 Thanks to recent advances in nanoprocessing technologies, 10−13 synthetic nanofluidic systems can be fabricated now on the atomic length scale 14 to mimic their natural counterparts, thereby facilitating the revelation of anomalous behaviors and mechanisms of ion transport under extremely confined conditions via various manipulation approaches. 15,16 Among a large diversity of methods for controlling ion transport through artificial channels, light as an exogenous regulating method can readily be implemented and rich photoeffects can be employed for designing multiple functions, which offers a new dimension for ion transport manipulation.…”

mentioning

confidence: 99%

“…Ion transport plays an important role in the process of signal transfer and energy conversion of living matter, − arousing the development of artificial ion channels which mimic biological protein channels to achieve specific functionalities. − Thanks to recent advances in nanoprocessing technologies, − synthetic nanofluidic systems can be fabricated now on the atomic length scale to mimic their natural counterparts, thereby facilitating the revelation of anomalous behaviors and mechanisms of ion transport under extremely confined conditions via various manipulation approaches. , Among a large diversity of methods for controlling ion transport through artificial channels, light as an exogenous regulating method can readily be implemented and rich photoeffects can be employed for designing multiple functions, which offers a new dimension for ion transport manipulation . A van der Waals heterojunction can be used to build a variety of functional electronic devices such as solar cells, photoelectric detectors, and photocatalysis based on its light-harvesting capability. , Moreover, such van der Waals stacking devices can be transferred to ionic systems, thus realizing tunable functions also in nanofluidics. − For a natural photosynthesis process, a photoresponsive ion pump relies primarily on biomolecules embedded in the thylakoid membrane of chloroplasts. , To mimic this process, artificial light-induced ion pumping systems employing multiple channels have been shown, though the mechanism has not been fully understood. ,− In contrast, implementation of artificial ion pumping in a single nanopore in a van der Waals heterojunction with ultimate thickness can in principle offer a direct and effective way to access the microscopic vision of the photodriven ion transport, which remains unexplored.…”

mentioning

confidence: 99%

Light-Driven Ion Transport through Single-Heterojunction Nanopores

Niu

Chen

et al. 2023

Nano Lett.

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Inspired by natural photosynthesis, light has become an emerging ionic behavior regulator and ion-pumping source. Nanoprocessing technology has allowed the bridge between the light-regulated nanofluids and the optoelectronic properties of two-dimensional (2D) materials, which inspires applications like energy harvesting and enhances fundamental understandings in nanofluidics. However, unlike light-induced ion pumping based on densely layered membranes with multiple nanochannels, experimental implementation on atomically thin materials featuring only a single nanochannel remains challenging. Here, we report light-induced ion pumping based on a single artificial heterojunction nanopore. Under light illumination, the induced current through a single nanopore reaches tens of picoamperes. The hole–electron separation originating from the optoelectrical property of a van der Waals PN junction is proposed to capture the light-driven ion transport. Further, different methods are adopted to modify the ion behavior and response time, presenting potential applications in fluidic photoenergy harvesting, photoelectric ion transport control, and bionic artificial neurons.

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Angstrofluidics: Walking to the Limit

Cited by 29 publications

References 175 publications

Interfacial Liquid Water on Graphite, Graphene, and 2D Materials

Interfacial Liquid Water on Graphite, Graphene, and 2D Materials

Ion-Selective Separation Using MXene-Based Membranes: A Review

Light-Driven Ion Transport through Single-Heterojunction Nanopores

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