Nanomaterials‐Based Nanochannel Membrane for Osmotic Energy Harvesting

Li, Shangzhen; Wang, Jin; Lv, Yongtao; Cui, Zheng; Wang, Lei

doi:10.1002/adfm.202308176

Cited by 10 publications

(2 citation statements)

References 244 publications

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“…However, it is essential to ensure sufficient spacing between hydrogel chains during the construction of ion transport channels to mitigate the adverse effects of densely bonded networks on ion-conductivity [ 132 ]. Another approach involves integrating hydrogel material with other substances possessing micro-nano pore structures [ 133 ]. For example, Yan et al [ 33 ], coated a portion of the titanium oxide nanoparticle film with a cobalt hydrogel featuring strong hygroscopicity ( Figure 7 b).…”

Section: Performance Enhancement Methods Of Polymer-based Nanogeneratorsmentioning

confidence: 99%

A Review of Polymer-Based Environment-Induced Nanogenerators: Power Generation Performance and Polymer Material Manipulations

Xie,

Yan,

2024

Polymers

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Natural environment hosts a considerable amount of accessible energy, comprising mechanical, thermal, and chemical potentials. Environment-induced nanogenerators are nanomaterial-based electronic chips that capture environmental energy and convert it into electricity in an environmentally friendly way. Polymers, characterized by their superior flexibility, lightweight, and ease of processing, are considered viable materials. In this paper, a thorough review and comparison of various polymer-based nanogenerators were provided, focusing on their power generation principles, key materials, power density and stability, and performance modulation methods. The latest developed nanogenerators mainly include triboelectric nanogenerators (TriboENG), piezoelectric nanogenerators (PENG), thermoelectric nanogenerators (ThermoENG), osmotic power nanogenerator (OPNG), and moist-electric generators (MENG). Potential practical applications of polymer-based nanogenerator were also summarized. The review found that polymer nanogenerators can harness a variety of energy sources, with the basic power generation mechanism centered on displacement/conduction currents induced by dipole/ion polarization, due to the non-uniform distribution of physical fields within the polymers. The performance enhancement should mainly start from strengthening the ion mobility and positive/negative ion separation in polymer materials. The development of ionic hydrogel and hydrogel matrix composites is promising for future nanogenerators and can also enable multi-energy collaborative power generation. In addition, enhancing the uneven distribution of temperature, concentration, and pressure induced by surrounding environment within polymer materials can also effectively improve output performance. Finally, the challenges faced by polymer-based nanogenerators and directions for future development were prospected.

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Section: Performance Enhancement Methods Of Polymer-based Nanogeneratorsmentioning

confidence: 99%

A Review of Polymer-Based Environment-Induced Nanogenerators: Power Generation Performance and Polymer Material Manipulations

Xie,

Yan,

2024

Polymers

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“…Alternatively, two-dimensional (2D) lamellar nanofluidic membranes made from semiconductor nanosheets provide new possibilities for light-controlled ion transport and ionic-energy utilizations. These nacre-like systems, with densely stacked multilayered structures, can always be fabricated via facile and scalable vacuum filtration. , Benefiting from the chemical characteristics of 2D materials, the subnanometer interstitial space between nanosheets allows surface-charge-governed ion transport, thereby selectively transporting counterions while expelling co-ions. Furthermore, the excellent intrinsic photoelectric properties of 2D semiconductors enable rapid light responsiveness in nanofluidic membranes.…”

Section: Introductionmentioning

confidence: 99%

Light-Powered Directional Ion Transport via PFN-Br/MoS₂ Heterogeneous Membranes: Band Alignment and Activation Energy Barrier Engineering

Zhou,

Jin,

Jia

et al. 2024

ACS Appl. Mater. Interfaces

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Biological photoresponsive ion transport systems consistently attract researchers' attention owing to their remarkable functions of harvesting energy from nature and participating in visual perception systems. Designing and constructing artificial lightdriven ion transport devices to mimic biological counterparts remains a challenge owing to fabrication limitations in nanoconfined spaces. Herein, a typical conjugated polyelectrolyte (PFN-Br) was assembled onto a laminated MoS 2 M using simple solutionprocessing vacuum filtration, resulting in a heterogeneous three-and two-dimensional nanoporous membrane. The designed band alignment between PFN-Br and MoS 2 enables effective directional ion transport under irradiation in an equilibrium solution, even against a 30-fold concentration gradient. The staggered energy structure of PFN-Br and MoS 2 enhances charge separation and establishes a photogenerated potential as the driving force for ion transport. Additionally, the activation energy barrier for ion transport across the heterogeneous membrane decreased by 60% after light irradiation, considerably improving ion transport flux. The easy fabrication and high performance of the membrane in light-powered ion transport provide promising approaches for designing nanofluidic devices with possible applications in energy conversion, light-enhanced biosensing, and photoresponsive ionic devices.

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Rapid and Controllable Multilayer Cell Sheet Assembly via Biodegradable Nanochannel Membranes

Yang,

Rathnam,

Hou

et al. 2024

Adv Funct Materials

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The ability to precisely arrange and control the assembly of diverse cell types into intricate 3D structures remains a critical challenge in tissue engineering. Herein, a versatile and programmable 3D cell sheet assembly is described technology by developing a biodegradable nanochannel (BNC) membrane to fulfill this unmet need. This membrane, hierarchically assembled from 2D nanomaterial aggregates, exhibits both exceptional fluid permeability and rapid biodegradation under physiological conditions. The unique properties of the BNC membrane enable precise spatial and temporal control over cell assembly, facilitating the creation of complex 3D cellular architectures. The BNC membrane is integrated with a programmable negative‐pressure‐based cell assembly strategy to form single and multicellular 3D sheets in a highly controllable manner. To demonstrate the feasibility and translatability of this technology in the field of tissue engineering approaches to screen stem cell‐derived therapeutics with “core–shell” macrophage‐fibroblast multicellular patterns and treat murine diabetic skin wounds via scaffold‐free 3D adipose‐derived mesenchymal stem cell (ADMSC) sheets are devised. In summary, the results demonstrate that the BNC membrane‐based 3D cell sheet assembly approach significantly advances current tissue engineering capabilities, offering substantial potential for both regenerative medicine applications and the development of physiologically relevant disease models.

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Nanomaterials‐Based Nanochannel Membrane for Osmotic Energy Harvesting

Cited by 10 publications

References 244 publications

A Review of Polymer-Based Environment-Induced Nanogenerators: Power Generation Performance and Polymer Material Manipulations

A Review of Polymer-Based Environment-Induced Nanogenerators: Power Generation Performance and Polymer Material Manipulations

Light-Powered Directional Ion Transport via PFN-Br/MoS₂ Heterogeneous Membranes: Band Alignment and Activation Energy Barrier Engineering

Rapid and Controllable Multilayer Cell Sheet Assembly via Biodegradable Nanochannel Membranes

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Nanomaterials‐Based Nanochannel Membrane for Osmotic Energy Harvesting

Cited by 10 publications

References 244 publications

A Review of Polymer-Based Environment-Induced Nanogenerators: Power Generation Performance and Polymer Material Manipulations

A Review of Polymer-Based Environment-Induced Nanogenerators: Power Generation Performance and Polymer Material Manipulations

Light-Powered Directional Ion Transport via PFN-Br/MoS2 Heterogeneous Membranes: Band Alignment and Activation Energy Barrier Engineering

Rapid and Controllable Multilayer Cell Sheet Assembly via Biodegradable Nanochannel Membranes

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Product

Resources

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Light-Powered Directional Ion Transport via PFN-Br/MoS₂ Heterogeneous Membranes: Band Alignment and Activation Energy Barrier Engineering