Salinity Gradient-Induced Power Generation in Nanochannels: The Role of pH-Sensitive Polyelectrolyte Layers

Mehta, Sumit Kumar; Raj, Abhishek; Mondal, Pranab Kumar

doi:10.1021/acs.langmuir.3c01236

Cited by 10 publications

(12 citation statements)

References 32 publications

(132 reference statements)

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“…Nanopores, nanopipettes, and nanochannels have various applications such as in biological sensing, 1,2 biological separation, 3 energy conversion, 4,5 water desalination, 6 etc. Accordingly, the understanding and control of the transport phenomena, especially ionic transport, in such elements have been the subject of many research studies during the past two decades.…”

Section: Introductionmentioning

confidence: 99%

Improved ionic current rectification utilizing cylindrical nanochannels coated with polyelectrolyte layers of non-uniform thickness

Nekoubin,

Hardt,

Sadeghi

2024

Soft Matter

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Section: Introductionmentioning

confidence: 99%

Improved ionic current rectification utilizing cylindrical nanochannels coated with polyelectrolyte layers of non-uniform thickness

Nekoubin,

Hardt,

Sadeghi

2024

Soft Matter

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“…Grafting polyelectrolyte (PE) brushes onto solid–liquid interfaces offers a promising bioinspired strategy of fabricating functionalized nanochannels and nanoparticles because of its inherent capability of regulating many physicochemical properties of interfaces formed between the hard surfaces and ionic solutions. − A soft interface, typically represented by a rigid surface covered by a polyelectrolyte layer (PEL), can be ion-penetrable, resulting alterations in the electrostatic potential distribution within the EDL in contact with a bare rigid surface. − These surfaces are primarily composed of polymer brushes (PBs), which are assemblies of polymer chains. These chains are tethered or grafted by one of their ends to a surface or to the backbone of another polymer chain.…”

Section: Introductionmentioning

confidence: 99%

Highly Efficient Conversion of Salinity Difference to Electricity in Nanofluidic Channels Boosted by Variable Thickness Polyelectrolyte Coating

Nekoubin,

Sadeghi,

Chakraborty

2024

Langmuir

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The inherent limits of the current produced by imposing salinity gradients along a nanofluidic channel having "hard" boundary walls heavily constrain the resulting energy harvesting efficacy, acting as major hindrances against the practicability of harnessing high power density from the mixing of water having different salinities. In this work, the infusion of variable-thickness polyelectrolyte layer of a conical shape is projected to augment salinity gradient power generation in nanochannels. Such a progressive thickening of a charged interfacial layer on account of axially declining ion concentration facilitates the shedding of enhanced numbers of mobile ions, bearing a net charge of equal and opposite to the surface-bound ions, into the mainstream current flow. We show that the proposed design can convert energy at a higher efficiency as compared to both solid-state and available polyelectrolyte layer (PEL)-covered nanochannels. The same is true for the maximum power density at moderate and high concentration ratios including natural salt gradient conditions for which more than 50% increase is achievable. The maximum values achieved for efficiency and power density read 50.3% and 6.6 kW/m 2 , respectively. Our results provide fundamental insights on strategizing variable-thickness polyelectrolyte layer grafting on the nanochannel interfaces, toward realizing high-performance osmotic power generators by altering the local ionic clouds alongside the grafted layers and enhancing the ionic mobility by inducing a driving potential gradient concomitantly. These findings open up a new strategy of efficient conversion of the power of the salinity difference of seawater and river water into electricity in a nanofluidic framework, surpassing the previously established limits of blue energy harvesting technologies.

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“…The integration of pH-sensitive polyelectrolyte layers (PELs) within nanochannels has shown potential to enhance power densities significantly, leveraging the additional charged groups introduced by the polyelectrolytes. 18,19 However, the impact of ion partitioning, 20–25 especially in configurations involving PELs with distinct permittivity from the surrounding electrolyte, remains underexplored. In this context, it is noted that PEL has a lower electrical permittivity, which allows for more electrostatic self-energy, whereas the void electrolytic region has a high electrical permittivity, causing low electrostatic self-energy.…”

Section: Introductionmentioning

confidence: 99%

Maximizing blue energy: the role of ion partitioning in nanochannel systems

Mehta,

Deb,

Nandy

et al. 2024

Phys. Chem. Chem. Phys.

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Salinity Gradient-Induced Power Generation in Nanochannels: The Role of pH-Sensitive Polyelectrolyte Layers

Cited by 10 publications

References 32 publications

Improved ionic current rectification utilizing cylindrical nanochannels coated with polyelectrolyte layers of non-uniform thickness

Improved ionic current rectification utilizing cylindrical nanochannels coated with polyelectrolyte layers of non-uniform thickness

Highly Efficient Conversion of Salinity Difference to Electricity in Nanofluidic Channels Boosted by Variable Thickness Polyelectrolyte Coating

Maximizing blue energy: the role of ion partitioning in nanochannel systems

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