Understanding the Giant Gap between Single‐Pore‐ and Membrane‐Based Nanofluidic Osmotic Power Generators

Gao, Jun; Liu, Xueli; Jiang, Yanan; Ding, Liping; Jiang, Lei; Guo, Wei

doi:10.1002/smll.201804279

Cited by 112 publications

(126 citation statements)

References 45 publications

(111 reference statements)

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“…Finite‐element method was employed to solve the model with appropriate boundary conditions, following an established process. [ 56–59 ] The model channel was 2 nm high and 1 µm long. For heterogeneous nanochannels, the negatively charged (n‐part, 400 nm long, −60 mC m −2 ) and positively charged parts (p‐part, 400 nm long, 60 mC m −2 ) were connected by a 200‐nm long transition zone.…”

Section: Methodsmentioning

confidence: 99%

Electric‐Field‐Induced Ionic Sieving at Planar Graphene Oxide Heterojunctions for Miniaturized Water Desalination

Jia

Cao

et al. 2020

Advanced Materials

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Section: Methodsmentioning

confidence: 99%

Electric‐Field‐Induced Ionic Sieving at Planar Graphene Oxide Heterojunctions for Miniaturized Water Desalination

Jia

Cao

et al. 2020

Advanced Materials

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“…It is experimentally challenging to scale up the heterogeneous membrane, which can be ascribed to the combined effect of multiple factors such as enhanced entering resistance (i.e., the sum of reservoir resistance and reservoir/ nanopores interfacial resistance), hindered counter-ion diffusion (caused by relatively low selectivity), and increased stochastic defects. Normalizing this high power density into real high power for industrial large-scale membrane applications is a necessity, which needs the joint efforts of both experimental and theoretical scientists in the future 60,61 . 1.…”

Section: Gel Lonmentioning

confidence: 99%

Improved osmotic energy conversion in heterogeneous membrane boosted by three-dimensional hydrogel interface

et al. 2020

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The emerging heterogeneous membranes show unprecedented superiority in harvesting the osmotic energy between ionic solutions of different salinity. However, the power densities are limited by the low interfacial transport efficiency caused by a mismatch of pore alignment and insufficient coupling between channels of different dimensions. Here we demonstrate the use of three-dimensional (3D) gel interface to achieve high-performance osmotic energy conversion through hybridizing polyelectrolyte hydrogel and aramid nanofiber membrane. The ionic diode effect of the heterogeneous membrane facilitates one-way ion diffusion, and the gel layer provides a charged 3D transport network, greatly enhancing the interfacial transport efficiency. When used for harvesting the osmotic energy from the mixing of sea and river water, the heterogeneous membrane outperforms the state-of-the-art membranes, to the best of our knowledge, with power densities of 5.06 W m −2. The diversity of the polyelectrolyte and gel makes our strategy a potentially universal approach for osmotic energy conversion.

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“…This phenomenon can be ascribed to the decreased range of the overlapped EDLs in large channels, leading to a reduced local concentration gradient . This means, the nano‐sized pores may help to reduce the influence of the transportation of counter‐ion into the channel, thus enhance the osmotic transport ability . Moreover, a tandem of MXM‐RED stacks was constructed to obtain higher voltages.…”

Section: Resultsmentioning

confidence: 99%

Oppositely Charged Ti₃C₂T_x MXene Membranes with 2D Nanofluidic Channels for Osmotic Energy Harvesting

et al. 2020

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Membrane‐based reverse electrodialysis (RED) is considered as the most promising technique to harvest osmotic energy. However, the traditional membranes are limited by high internal resistance and low efficiency, resulting in undesirable power densities. Herein, we report the combination of oppositely charged Ti3C2Tx MXene membranes (MXMs) with confined 2D nanofluidic channels as high‐performance osmotic power generators. The negatively or positively charged 2D MXene nanochannels exhibit typical surface‐charge‐governed ion transport and show excellent cation or anion selectivity. By mixing the artificial sea water (0.5 m NaCl) and river water (0.01 m NaCl), we obtain a maximum power density of ca. 4.6 Wm−2, higher than most of the state‐of‐the‐art membrane‐based osmotic power generators, and very close to the commercialization benchmark (5 Wm−2). Through connecting ten tandem MXM‐RED stacks, the output voltage can reach up 1.66 V, which can directly power the electronic devices.

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Understanding the Giant Gap between Single‐Pore‐ and Membrane‐Based Nanofluidic Osmotic Power Generators

Cited by 112 publications

References 45 publications

Electric‐Field‐Induced Ionic Sieving at Planar Graphene Oxide Heterojunctions for Miniaturized Water Desalination

Electric‐Field‐Induced Ionic Sieving at Planar Graphene Oxide Heterojunctions for Miniaturized Water Desalination

Improved osmotic energy conversion in heterogeneous membrane boosted by three-dimensional hydrogel interface

Oppositely Charged Ti₃C₂T_x MXene Membranes with 2D Nanofluidic Channels for Osmotic Energy Harvesting

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Understanding the Giant Gap between Single‐Pore‐ and Membrane‐Based Nanofluidic Osmotic Power Generators

Cited by 112 publications

References 45 publications

Electric‐Field‐Induced Ionic Sieving at Planar Graphene Oxide Heterojunctions for Miniaturized Water Desalination

Electric‐Field‐Induced Ionic Sieving at Planar Graphene Oxide Heterojunctions for Miniaturized Water Desalination

Improved osmotic energy conversion in heterogeneous membrane boosted by three-dimensional hydrogel interface

Oppositely Charged Ti3C2Tx MXene Membranes with 2D Nanofluidic Channels for Osmotic Energy Harvesting

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Product

Resources

About

Oppositely Charged Ti₃C₂T_x MXene Membranes with 2D Nanofluidic Channels for Osmotic Energy Harvesting