Your search keyword '"Sreepal, V."' showing total 10 results

1. pH-dependent water permeability switching and its memory in 1T' MoS$_2$ membranes

Author

Hu, C., Achari, A., Rowe, P., Xiao, H., Suran, S., Li, Z., Huang, K., Chi, C., Cherian, C. T., Sreepal, V., Bentley, P. D., Pratt, A., Zhang, N., Novoselov, K. S., Michaelides, A., and Nair, R. R.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

Intelligent transport of molecular species across different barriers is critical for various biological functions and is achieved through the unique properties of biological membranes. An essential feature of intelligent transport is the ability to adapt to different external and internal conditions and also the ability to memorise the previous state. In biological systems, the most common form of such intelligence is expressed as hysteresis. Despite numerous advances made over previous decades on smart membranes, it is still a challenge for a synthetic membrane to display stable hysteretic behaviour for molecular transport. Here we show the memory effects and stimuli regulated transport of molecules through an intelligent phase changing MoS$_2$ membrane in response to external pH. We show that water and ion permeation through 1T' MoS$_2$ membranes follows a pH dependent hysteresis with a permeation rate that switches by a few orders of magnitude. We demonstrate that this phenomenon is unique to the 1T' phase of MoS$_2$ due to the presence of surface charge and exchangeable ions on the surface. We further demonstrate the potential application of this phenomenon in autonomous wound infection monitoring and pH-dependent nanofiltration. Our work significantly deepens understanding of the mechanism of water transport at the nanoscale and opens an avenue for developing neuromorphic applications, smart drug delivery systems, point-of-care diagnostics, smart sensors, and intelligent filtration devices.

Published

2023

2. Alternating superconducting and charge density wave monolayers within bulk 6R-TaS2

Author

Achari, A., Bekaert, J., Sreepal, V., Orekhov, A., Kumaravadivel, P., Kim, M., Gauquelin, N., Pillai, P. Balakrishna, Verbeeck, J., Peeters, F. M., Geim, A. K., Milosevic, M. V., and Nair, R. R.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Van der Waals (vdW) heterostructures continue to attract intense interest as a route of designing materials with novel properties that cannot be found in naturally occurring materials. Unfortunately, this approach is currently limited to only a few layers that can be stacked on top of each other. Here we report a bulk material consisting of superconducting monolayers interlayered with monolayers displaying charge density waves (CDW). This bulk vdW heterostructure is created by phase transition of 1T-TaS2 to 6R at 800 {\deg}C in an inert atmosphere. Electron microscopy analysis directly shows the presence of alternating 1T and 1H monolayers within the resulting bulk 6R phase. Its superconducting transition (Tc) is found at 2.6 K, exceeding the Tc of the bulk 2H phase of TaS2. The superconducting temperature can be further increased to 3.6 K by exfoliating 6R-TaS2 and then restacking its layers. Using first-principles calculations, we argue that the coexistence of superconductivity and CDW within 6R-TaS2 stems from amalgamation of the properties of adjacent 1H and 1T monolayers, where the former dominates the superconducting state and the latter the CDW behavior.

Published

2022

3. Cation controlled wetting properties of vermiculite membranes and its potential for fouling resistant oil-water separation

Author

Huang, K., Rowe, P., Chi, C., Sreepal, V., Bohn, T., Zhou, K. -G., Su, Y., Prestat, E., Pillai, P. Balakrishna, Cherian, C. T., Michaelides, A., and Nair, R. R.

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science

Abstract

The surface free energy is one of the most fundamental properties of solids, hence, manipulating the surface energy and thereby the wetting properties of solids, has tremendous potential for various physical, chemical, biological as well as industrial processes. Typically, this is achieved by either chemical modification or by controlling the hierarchical structures of surfaces. Here we report a phenomenon whereby the wetting properties of vermiculite laminates are controlled by the hydrated cations on the surface and in the interlamellar space. We find that by exploiting this mechanism, vermiculite laminates can be tuned from superhydrophillic to hydrophobic simply by exchanging the cations; hydrophilicity decreases with increasing cation hydration free energy, except for lithium. Lithium, which has a higher hydration free energy than potassium, is found to provide a superhydrophilic surface due to its anomalous hydrated structure at the vermiculite surface. Building on these findings, we demonstrate the potential application of superhydrophilic lithium exchanged vermiculite as a thin coating layer on microfiltration membranes to resist fouling, and thus, we address a major challenge for oil-water separation technology.

Published

2020

4. pH-dependent water permeability switching and its memory in MoS2 membranes

Author

Hu, C. Y., primary, Achari, A., additional, Rowe, P., additional, Xiao, H., additional, Suran, S., additional, Li, Z., additional, Huang, K., additional, Chi, C., additional, Cherian, C. T., additional, Sreepal, V., additional, Bentley, P. D., additional, Pratt, A., additional, Zhang, N., additional, Novoselov, K. S., additional, Michaelides, A., additional, and Nair, R. R., additional

Published

2023

5. Non-van der Waals quasi-2D materials; recent advances in synthesis, emergent properties and applications

Author

Balan, A. P., Puthirath, A. B., Roy, S., Costin, G., Oliveira, E. F., Saadi, M. A. S. R., Sreepal, V., (0000-0002-4066-3840) Friedrich, R., Serles, P., Biswas, A., Iyengar, S. A., Chakingal, N., Bhattacharyya, S., Saju, S. K., Pardo, S. C., Sassi, L. M., Filleter, T., (0000-0003-0074-7588) Krasheninnikov, A., Galvao, D. S., Vajtai, R., Nair, R. R., Ajayan, P. M., Balan, A. P., Puthirath, A. B., Roy, S., Costin, G., Oliveira, E. F., Saadi, M. A. S. R., Sreepal, V., (0000-0002-4066-3840) Friedrich, R., Serles, P., Biswas, A., Iyengar, S. A., Chakingal, N., Bhattacharyya, S., Saju, S. K., Pardo, S. C., Sassi, L. M., Filleter, T., (0000-0003-0074-7588) Krasheninnikov, A., Galvao, D. S., Vajtai, R., Nair, R. R., and Ajayan, P. M.

Abstract

The discovery of novel materials that are stable at ambient conditions with emergent functionalities is a pressing need of the 21st century to keep the pace of social and technological advancement in a sustainable manner. Nanotechnology and nanomaterials are one of this kind and the current era has already witnessed several groundbreaking discoveries of materials and disruptive technological advancements. Starting from 0D fullerene, the invention of 1D carbon nanotubes, and most recently 2D graphene, all are allotropes of carbon, have brought a lot of research opportunities to understand different physical and chemical phenomena at atomic and molecular scales and to convert such properties into useful applications. Among them, 2D materials find special attention due to unique properties such as ballistic carrier transport, immunity from substrate effects and commendable in plane mechanical robustness. However, the library of such materials is limited, and one can see that most of the technically viable materials that are already industrialized in a large scale belong to the class of non-van der Waals materials. The effect of confinement in one dimension on non-van der Waals materials remains unexplored owing to the difficulty in fabricating these materials to the ultra-thin limit with large lateral size or area. Recent advancement of cleaving non-van der Waals bulk materials to their ultra-thin counter parts through the state-of-the-art liquid phase exfoliation approach leads to renewed research interest among scientific community. The existence of cleaving/parting planes in certain directions of non-van der Waals materials, where the bonding strength is relatively weak compared to other crystallographic directions of the bulk crystal, facilitate smooth exfoliation when subjected to shear force through suitable methods. Herein, we attempt to discuss the rationale of such methods in the synthesis of non-van der Waals 2D materials that possess cleavage/parting planes

Published

2022

6. pH-dependent water permeability switching and its memory in MoS2 membranes.

Author

Hu, C. Y., Achari, A., Rowe, P., Xiao, H., Suran, S., Li, Z., Huang, K., Chi, C., Cherian, C. T., Sreepal, V., Bentley, P. D., Pratt, A., Zhang, N., Novoselov, K. S., Michaelides, A., and Nair, R. R.

Abstract

Intelligent transport of molecular species across different barriers is critical for various biological functions and is achieved through the unique properties of biological membranes1–4. Two essential features of intelligent transport are the ability to (1) adapt to different external and internal conditions and (2) memorize the previous state5. In biological systems, the most common form of such intelligence is expressed as hysteresis6. Despite numerous advances made over previous decades on smart membranes, it remains a challenge to create a synthetic membrane with stable hysteretic behaviour for molecular transport7–11. Here we demonstrate the memory effects and stimuli-regulated transport of molecules through an intelligent, phase-changing MoS2 membrane in response to external pH. We show that water and ion permeation through 1T′ MoS2 membranes follows a pH-dependent hysteresis with a permeation rate that switches by a few orders of magnitude. We establish that this phenomenon is unique to the 1T′ phase of MoS2, due to the presence of surface charge and exchangeable ions on the surface. We further demonstrate the potential application of this phenomenon in autonomous wound infection monitoring and pH-dependent nanofiltration. Our work deepens understanding of the mechanism of water transport at the nanoscale and opens an avenue for the development of intelligent membranes.We demonstrate the memory effects and stimuli-regulated transport of molecules through an intelligent, phase-changing MoS2 membrane in response to external pH, a phenomenon unique to the 1T′ phase of MoS2. [ABSTRACT FROM AUTHOR]

Published

2023

7. Cation-controlled wetting properties of vermiculite membranes and its promise for fouling resistant oil–water separation

Author

Huang, K., primary, Rowe, P., additional, Chi, C., additional, Sreepal, V., additional, Bohn, T., additional, Zhou, K.-G., additional, Su, Y., additional, Prestat, E., additional, Pillai, P. Balakrishna, additional, Cherian, C. T., additional, Michaelides, A., additional, and Nair, R. R., additional

Published

2020

8. Ion exchange in atomically thin clays and micas.

Author

Zou YC, Mogg L, Clark N, Bacaksiz C, Milovanovic S, Sreepal V, Hao GP, Wang YC, Hopkinson DG, Gorbachev R, Shaw S, Novoselov KS, Raveendran-Nair R, Peeters FM, Lozada-Hidalgo M, and Haigh SJ

Abstract

The physical properties of clays and micas can be controlled by exchanging ions in the crystal lattice. Atomically thin materials can have superior properties in a range of membrane applications, yet the ion-exchange process itself remains largely unexplored in few-layer crystals. Here we use atomic-resolution scanning transmission electron microscopy to study the dynamics of ion exchange and reveal individual ion binding sites in atomically thin and artificially restacked clays and micas. We find that the ion diffusion coefficient for the interlayer space of atomically thin samples is up to 10 4 times larger than in bulk crystals and approaches its value in free water. Samples where no bulk exchange is expected display fast exchange at restacked interfaces, where the exchanged ions arrange in islands with dimensions controlled by the moiré superlattice dimensions. We attribute the fast ion diffusion to enhanced interlayer expandability resulting from weaker interlayer binding forces in both atomically thin and restacked materials. This work provides atomic scale insights into ion diffusion in highly confined spaces and suggests strategies to design exfoliated clay membranes with enhanced performance., (© 2021. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2021

9. Author Correction: Ion exchange in atomically thin clays and micas.

Author

Zou YC, Mogg L, Clark N, Bacaksiz C, Milovanovic S, Sreepal V, Hao GP, Wang YC, Hopkinson DG, Gorbachev R, Shaw S, Novoselov KS, Raveendran-Nair R, Peeters FM, Lozada-Hidalgo M, and Haigh SJ

Published

2021

10. Two-Dimensional Covalent Crystals by Chemical Conversion of Thin van der Waals Materials.

Author

Sreepal V, Yagmurcukardes M, Vasu KS, Kelly DJ, Taylor SFR, Kravets VG, Kudrynskyi Z, Kovalyuk ZD, Patanè A, Grigorenko AN, Haigh SJ, Hardacre C, Eaves L, Sahin H, Geim AK, Peeters FM, and Nair RR

Abstract

Most of the studied two-dimensional (2D) materials have been obtained by exfoliation of van der Waals crystals. Recently, there has been growing interest in fabricating synthetic 2D crystals which have no layered bulk analogues. These efforts have been focused mainly on the surface growth of molecules in high vacuum. Here, we report an approach to making 2D crystals of covalent solids by chemical conversion of van der Waals layers. As an example, we used 2D indium selenide (InSe) obtained by exfoliation and converted it by direct fluorination into indium fluoride (InF 3 ), which has a nonlayered, rhombohedral structure and therefore cannot  possibly be obtained by exfoliation. The conversion of InSe into InF 3 is found to be feasible for thicknesses down to three layers of InSe, and the obtained stable InF 3 layers are doped with selenium. We study this new 2D material by optical, electron transport, and Raman measurements and show that it is a semiconductor with a direct bandgap of 2.2 eV, exhibiting high optical transparency across the visible and infrared spectral ranges. We also demonstrate the scalability of our approach by chemical conversion of large-area, thin InSe laminates obtained by liquid exfoliation, into InF 3 films. The concept of chemical conversion of cleavable thin van der Waals crystals into covalently bonded noncleavable ones opens exciting prospects for synthesizing a wide variety of novel atomically thin covalent crystals.

Published

2019