Engineered Asymmetric Heterogeneous Membrane: A Concentration-Gradient-Driven Energy Harvesting Device

Zhang, Zhen; Kong, Xiangyu; Xiao, Kai; Liu, Qian; Xie, Ganquan; Li, Pei; Ma, Jie; Tian, Ye; Wen, Liping; Jiang, Lei

doi:10.1021/jacs.5b09918

Cited by 305 publications

(269 citation statements)

References 79 publications

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“…In [14], besides evaluating performance of commercially available membrane, they had tested a tailor made membrane with significant reduction in resistance and achieved 1.3 W/m 2 . More recent type of membrane was reported such as pore-filling ion exchange membranes with open area spacer that achieved 2.4 w/m 2 [15], asymmetric heterogeneous membrane [16] which can be applied in nanofluidic application and membrane with chevron corrugation that reduce the pressure drop is able to produce up to 0.89w/m 2 . Works on modelling and simulation of RED process including the cell pair model based on thermodynamic and transport equation was proposed by Veerman [17].…”

Section: Reverse Electrodialysis (Red)mentioning

confidence: 99%

Harnessing ‘Blue energy’: A Review on Techniques and Preliminary Analysis

Hasan¹,

Khai²,

Kannan³

et al. 2017

MATEC Web Conf.

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Abstract.Energy harvesting from the ocean called 'blue energy' began in the 1970's and should have reached its peak by today, but due to varying interests in the field and the growing potentials of other sources, its development was delayed. Recently, it receives more interest and a number of institutes has deployed their pilot plant. Blue energy is a type of renewable energy based on salinity gradient where power is generated from different salt concentration in saltwater (the ocean) and freshwater (river). When the mixing of seawater and freshwater occurs, an increase in the entropy of this system is observed and free energy is dissipated. This research aims to identify and compare existing techniques or methods of blue energy harvesting developed over time. Five different techniques were reviewed, looking at their principle of operation, configuration and performance. Based on the review, capacitive mixing method was selected for further analysis. Experiment was conducted to evaluate different factor including the concentration of sea water, volumes and type of electrodes. The highest output power obtained is 89.7 mW, while the average is about 30 mW.

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Section: Reverse Electrodialysis (Red)mentioning

confidence: 99%

Harnessing ‘Blue energy’: A Review on Techniques and Preliminary Analysis

Hasan¹,

Khai²,

Kannan³

et al. 2017

MATEC Web Conf.

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“…In principle, this rectification could be enhanced by modifying the central compartment characteristics and controlling the pore tip shape and the nature and distribution of the pHsensitive groups. 12,23,31 We use a three-compartment electrochemical cell and two multiporous membranes with conical nanopores arranged in series. The membrane functionality is based on the pH-reversed ion current rectification and does not require specific surface functionalizations.…”

Section: -27mentioning

confidence: 99%

Multipore membranes with nanofluidic diodes allowing multifunctional rectification and logical responses

Cervera

Ramı́rez

Gómez

et al. 2016

Applied Physics Letters

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We have arranged two multipore membranes with conical nanopores in a three-compartment electrochemical cell. The membranes act as tunable nanofluidic diodes whose functionality is entirely based on the pH-reversed ion current rectification and does not require specific surface functionalizations. This electrochemical arrangement can display different electrical behaviors (quasi-linear ohmic response and inward/outward rectifications) as a function of the electrolyte concentration in the external solutions and the applied voltage at the pore tips. The multifunctional response permits to implement different logical responses including NOR and INHIBIT functions.

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“…These heterogeneous membranes can respond to both single and multiple stimuli, offering important guidance for the use of functional BCPs in nanofluidic science. [36] Our group has designed novel artificial asymmetric nanochannels based on mesoporous zeolite (MCM 41) and polyimide (PI) and investigated the ionic current behavior and rectifying characteristics of this system, both theo retically and experimentally (Figure 2e). [37] Recently, Gao and co workers fabricated organic-inorganic hybrid nanochannels [37] Copyright 2014, Royal Society of Chemistry.…”

Section: Introductionmentioning

confidence: 99%

Smart Bioinspired Nanochannels and their Applications in Energy‐Conversion Systems

Fan

Liu

et al. 2017

Advanced Materials

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materials. For example, nanochannels fab ricated in elastic materials can respond to an applied pressure, [4] and conical nanochannels in poly(ethylene tereph thalate) (PET) membranes can respond to pH. [5] Thus, it is convenient to achieve simple responsive properties by directly using responsive materials to construct the nano channels. The second route is an indirect method, where functional molecules and materials are modified onto the inner surfaces of nanochannels. This method can change the physical and chemical properties of nanochannels to make the system more intelligent. [6] Smart bioinspired nano channels with different shapes and compositions have been fabri cated, and these nanochannels can respond to various stimuli, such as pH, [7] light, [8] temperature, [9] specific ions, [10] and mole cules. [11] Compared with their fragile biological counterparts, smart bioinspired nanochannels possess excellent mechanical robustness, controllable geometry, tunable surface properties, and good chemical stability. [12] These advantages make them useful for many potential applications, ranging from molecular filters to biosensors to energy conversion devices. [13] Smart bioinspired nanochannels not only provide a basic research platform to simulate the ion transport process in living bodies, but also boost the generation of energy conver sion devices. In nature, ion channels can be used as switches to regulate mass transport and energy conversion. Learning from nature, numerous energy conversion systems based on artificial ion channels have been devised, [14] which are of great significance for the development of sustainable energy. Here, we summarize recent advances in the fabrication of smart bioinspired nanochannels and highlight their applications in energy conversion systems. Recent Advances in the Fabrication of Smart Bioinspired Nanochannels Materials and TechniquesThe fragility and instability of biological ion channels have motivated the development of smart bioinspired nanochan nels. To satisfy specific application requirements, various materials such as biological, [15] inorganic, [16] organic, [17] and composite materials [18] have been used to fabricate artificial nanochannels. Currently, nanochannels with diverse shapes and structures can be obtained using different techniques and Smart bioinspired nanochannels exhibiting ion-transport properties similar to biological ion channels have attracted extensive attention. Like ion channels in nature, smart bioinspired nanochannels can respond to various stimuli, which lays a solid foundation for mass transport and energy conversion. Fundamental research into smart bioinspired nanochannels not only furthers understanding of life processes in living bodies, but also inspires researchers to construct smart nanodevices to meet the increasing demand for the use of renewable resources. Here, a brief summary of recent research progress regarding the design and preparation of smart bioinspired nanochannels is presented. Moreover, representative applications ...

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Engineered Asymmetric Heterogeneous Membrane: A Concentration-Gradient-Driven Energy Harvesting Device

Cited by 305 publications

References 79 publications

Harnessing ‘Blue energy’: A Review on Techniques and Preliminary Analysis

Harnessing ‘Blue energy’: A Review on Techniques and Preliminary Analysis

Multipore membranes with nanofluidic diodes allowing multifunctional rectification and logical responses

Smart Bioinspired Nanochannels and their Applications in Energy‐Conversion Systems

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