Decoupled Ionic and Electronic Pathways for Enhanced Osmotic Energy Harvesting

Xie, Zhijiang; Xiang, Zhongrun; Fu, Xiaotong; Lin, Zewan; Jiao, Chenlu; Zheng, Ke; Yang, Mei; Qin, Xingzhen; Ye, Dongdong

doi:10.1021/acsenergylett.4c00320

Cited by 6 publications

(1 citation statement)

References 50 publications

(62 reference statements)

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“…Nanopores in solid-state membranes are very promising for emerging technologies and fabricating brand-new nanodevices. − Nanopore approach is considered to have high throughput and sensitivity, which makes it one of the advanced label-free techniques for single-molecule detection. , There are two types of nanopores: biological, , based on pore-forming proteins (α-HL, AeL, ClyA, etc. ), and solid-state, ,− made of inorganic materials (silicon-based materials, polymers, anodic alumina, etc.). In contrast to solid-state nanopores, biopores have some limitations, such as severe requirements for storage and usage conditions (temperature, electrolyte concentration, and pH) and a short shelf life.…”

Section: Introductionmentioning

confidence: 99%

Ultra-Low Intensity Light-Driven Ionic Conductivity through a Plasmonic Nanopore

Lebedev,

Vaulin,

Afonicheva

et al. 2024

ACS Appl. Nano Mater.

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Solid-state nanopore devices with plasmonic nanoantennas are powerful tools that allow for working with individual particles and molecules in solution as well as providing lightinduced control of ionic current flow through them. However, the ionic current flow manipulation by light still requires high power densities and, thus, results in the optical heating of the nanopore. Here, we solve this problem by using a 5 nm nanopore in the gap of a plasmonic bow-tie nanoantenna on a SiN x membrane irradiated by a broadband spectrum of incident light. In this regime, photons are not only strongly localized around the nanopore but also efficiently excite and trap charge carriers on defect states in the band gap of the material of the nanopore walls. As a result, ionic current flow modulation is achieved with several orders of magnitude lower power densities (around 0.035 W/cm 2 ) from a white-light lamp than in previous works employing spectrally narrow laser sources (10 0 −10 5 W/cm 2 ). The lamp irradiation causes a 21% increase in conductivity for a nanopore without a nanoantenna and a 35% increase in conductivity for a nanoantenna-decorated nanopore at the same power of irradiation. The revealed low-intensity approach for ionic current control is preferable for the study of biological objects.

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Section: Introductionmentioning

confidence: 99%

Ultra-Low Intensity Light-Driven Ionic Conductivity through a Plasmonic Nanopore

Lebedev,

Vaulin,

Afonicheva

et al. 2024

ACS Appl. Nano Mater.

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Cellulose Nanocrystal Composite Membrane Enhanced with In Situ Grown Metal–Organic Frameworks for Osmotic Energy Conversion

Wang,

Li,

Xiong

et al. 2024

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Access to clean and renewable energy, osmotic energy from salinity gradient difference, for example, is central to the sustainability of human civilization. Despite numerous examples of nanofluidic membranes for osmotic energy conversion, one produced from abundant and renewable biomass resources remains largely unexplored. In this work, cotton‐derived cellulose nanocrystals (CNCs) are employed to fabricate a membrane by self‐assembly with polyvinyl alcohol (PVA) and subsequent in situ growth of metal–organic framework (MOF), UiO‐66‐(COOH)2, to provide an example. The composite membrane exhibits excellent mechanical strength and toughness due to the long chains and hydrogen bonding interactions of PVA. The incorporation of UiO‐66‐(COOH)2 endows the composite membrane with abundant nano‐ and subnano‐sized ion transport channels, resulting in a 150% increase in ion conductance, while also providing superior cation selectivity through collaboration with the sulfated CNCs. The composite membrane with 27.4% MOF content can achieve an osmotic energy conversion performance of 5.10 W m−2 under a 50‐fold KCl gradient condition and a monovalent cation selectivity of ≈16 for K+/Mg2+. This work presents a solution for harvesting renewable osmotic energy by constructing nanofluidic membranes using plentiful renewable biomass materials and a simple, low‐emission fabrication procedure.

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Rearrangement of cellulose molecular chains in situ for stabilizing two-dimensional nanochannels

Xia,

Yuan,

Wang

et al. 2024

Chemical Engineering Journal

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Decoupled Ionic and Electronic Pathways for Enhanced Osmotic Energy Harvesting

Cited by 6 publications

References 50 publications

Ultra-Low Intensity Light-Driven Ionic Conductivity through a Plasmonic Nanopore

Ultra-Low Intensity Light-Driven Ionic Conductivity through a Plasmonic Nanopore

Cellulose Nanocrystal Composite Membrane Enhanced with In Situ Grown Metal–Organic Frameworks for Osmotic Energy Conversion

Rearrangement of cellulose molecular chains in situ for stabilizing two-dimensional nanochannels

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