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Clay-Based Nanofluidic Membrane Derived from Vermiculite Nanoflakes for Pressure-Responsive Power Generation

Jumi Deka, Kundan Saha, Anish Yadav, Kalyan Raidongia

2021ACS Applied Nano Materials15 citationsDOI

Abstract

The intrinsic thermal and chemical stability of vermiculite clay is exploited here to fabricate a robust and responsive energy device that consumes atmospheric water molecules as the cathode reagent. A nanofluidic membrane of clay was prepared by reconstructing exfoliated nanolayers of natural vermiculite clay and doped with poly(diallyldimethylammonium chloride) (PDDA). X-ray diffraction studies determined the height of the two-dimensional nanofluidic channels to be ∼0.41 nm. Application of a modest pressure of 56 kPa, on the Al foil placed on top of a PDDA-doped nanofluidic vermiculite membrane (PDDA-VM), yields a stable potential of ∼0.8 V. The output current value of the clay-based devices can be tuned by varying parameters like intercalating cations, device geometry, thickness of the polymeric coating, and applied pressure. The natural clay-based energy device is found to be highly robust; exposure to liquid nitrogen (−195 °C), heat pulse (450 °C), water steams, and mechanical stress (100 N) did not deteriorate its performance. Interestingly, the PDDA-VMs exhibit extraordinary fire retardancy, with ∼70% recovery in the power output after exposure to an open flame.

Topics & Concepts

VermiculiteMaterials scienceMembraneChemical engineeringIntercalation (chemistry)CoatingClay mineralsNanotechnologyComposite materialMineralogyChemistryInorganic chemistryBiochemistryEngineeringSolar-Powered Water Purification MethodsInnovative Energy Harvesting TechnologiesMembrane-based Ion Separation Techniques
Clay-Based Nanofluidic Membrane Derived from Vermiculite Nanoflakes for Pressure-Responsive Power Generation | Litcius