Carbonized Cotton Fibers for Ultrahigh Power-Density Electrokinetic Energy Harvesting

Saha, Kundan; Deka, Jumi; Kumar, Avinash; Mondal, Monotosh; Bora, Barsha Rani; Bakli, Chirodeep; Sood, A. K.; Chakraborty, Suman; Raidongia, Kalyan

doi:10.1021/acsaem.3c02409

Cited by 3 publications

(1 citation statement)

References 62 publications

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“…The urgent need to develop innovative strategies to harvest energy from sustainable resources has led to numerous technological innovations and explorations in recent years. − Extracting electrical energy from naturally abundant, clean, and renewable sources could be a promising solution to address the ever-growing energy and environmental crisis. Recently developed technologies like triboelectric nanogenerators, − piezoelectric nanogenerators, − electret nanogenerators, , electrokinetic nanogenerators, − solar cells, − thermoelectric cells, − and moisture-driven generators ,− have shown great efficiencies in converting environmental energy into electricity. However, many of these devices rely on either time- or location-specific environmental conditions such as sunlight, wind, flowing water, thermal, pressure, or moisture gradients.…”

Section: Introductionmentioning

confidence: 99%

Assembly of Natural Clay Minerals as Highly Robust Evaporation-Driven Power Generator

Bora,

Nath,

Dey

et al. 2024

ACS Appl. Energy Mater.

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Inexhaustible natural resources, such as water, wind, moisture, and ubiquitous natural processes such as evaporation or condensation, could offer optimal energy strategies for a sustainable future. Recently, there has been a surge in interest surrounding evaporation-driven power generators (EDPs), which rely on capillary-driven water flow through permselective nanochannels, followed by evaporation into the atmosphere. Despite huge potential, existing EDPs encounter hurdles like expensive and environmentally unfriendly active materials and complex fabrication processes. Here, we introduce a bilayer membrane composed of two distinct clay minerals, vermiculite (VM) and halloysite nanotube (HNT) clay, to develop an evaporation-driven energy generator capable of generating an open-circuit potential up to 406 mV along with short circuit currents of ∼3.4 μA, resulting in a power density up to 0.85 mW/cm 3 . Due to the affordability, biocompatibility of the materials employed, and simplicity of device fabrication, this energy generator can be upscaled to power low-energy electronic devices and sensors. The all-clay power generator can withstand extreme temperatures; exposure to 180 °C did not affect its power harvesting properties. Individual energy generators are connected in series to power small electronic devices, such as humidity meters, calculators, and LEDs.

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Section: Introductionmentioning

confidence: 99%

Assembly of Natural Clay Minerals as Highly Robust Evaporation-Driven Power Generator

Bora,

Nath,

Dey

et al. 2024

ACS Appl. Energy Mater.

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Non-monotonic variation in the streaming potential in polyelectrolyte grafted nanochannels mediated by ion partitioning effects

Patwari,

Kumar,

Bakli

et al. 2024

Analytica Chimica Acta

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Interplay of fluid rheology and micro-patterning toward modulating draining characteristics on an inclined substrate

Das,

Kumar,

Bakli

2024

Physics of Fluids

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We investigate a gravity-driven thin film flow of a non-Newtonian liquid over an inclined micro-patterned surface. We demonstrate the effect of micro-patterning on the film draining rate and the velocity profile by varying the relative slit width (Tr) and the length of the periodic irregularities (L). We unveil the interplay of the substrate structure and the fluid rheology by modeling the non-Newtonian thin film using the Carreau model, and the rheology of the film is varied for different values of power index n. Through numerical simulations, we delineate the effects of inertia, viscous, and capillary forces on the physics of thin film flow. We report a significant augmentation of flow velocity for both shear-thinning and shear-thickening fluids as a result of substrate micro-patterning, with the relative slit width playing a dominant role while the length of the periodic irregularities has only a minor influence on drainage characteristics. However, when the sole effect of fluid rheology is considered, flow velocity enhances for pseudoplastic fluid and decreases for dilatant fluid in comparison to Newtonian fluid. We examine the combined effect of rheology and substrate topography, revealing the dominating influence of micro-patterning at high slit-widths, while the fluid rheology has a greater role to play at lower slit-widths. We also demonstrate that the susceptibility of flow physics on varying rheology or topography is greatest for low viscosity liquids. Finally, we mark different regimes where the augmentation of average velocity and surface velocity are individually achieved. Hence, we propose a suitable combination of substrate structure and fluid rheology to engineer a flow characteristic. Based on the suitability for various applications, we provide the key to simultaneously optimizing the fluid rheology and substrate micro-patterning for precise engineering and controlling the draining characteristics of a thin film.

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Carbonized Cotton Fibers for Ultrahigh Power-Density Electrokinetic Energy Harvesting

Cited by 3 publications

References 62 publications

Assembly of Natural Clay Minerals as Highly Robust Evaporation-Driven Power Generator

Assembly of Natural Clay Minerals as Highly Robust Evaporation-Driven Power Generator

Non-monotonic variation in the streaming potential in polyelectrolyte grafted nanochannels mediated by ion partitioning effects

Interplay of fluid rheology and micro-patterning toward modulating draining characteristics on an inclined substrate

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