Vanaraj Solanki scite author profile

Borah

2019

Ind. Eng. Chem. Res.

The work presented in this article is aimed to assess the performances of 4763 Metal−Organic Frameworks (MOFs) for separation of hexane isomers using computer simulation methods. These MOFs, taken from the Computational Ready Experimental (CoRE) MOF database, are ranked on the basis of various performance metrics, namely, adsorption selectivity, working capacity, and regenerability. We investigated six binary mixtures, one three-component equimolar mixture, and one five-component equimolar mixture of hexane isomers at temperatures of 383, 433, 483, and 533 K. The MOFs were ranked separately for separation of each of these mixtures. The rankings with respect to these three metrics were found to be mostly different with only a few MOFs in common. We also carried out the rankings at different temperatures close to the typical isomerization reactor temperature. It is observed that the orders of the rankings at different temperatures are different. However, the majority of the MOFs are found to be common in the rankings at different temperatures. MOFs BIMDOR and WAMRIN01 perform the best with high adsorption selectivity for all the mixtures. It is observed that the MOFs with very high adsorption selectivity do not have high working capacity and regenerability. However, MOFs VEHJOJ, VEHJUP, and NAYGUR are found to be potential candidates for practical application of separation of the hexane isomers as they have regenerability >80% and reasonably high working capacity and adsorption selectivity. Further, we looked at various structures' property correlations. These correlations reveal that the largest cavity diameter and pore volume are crucial structural properties to be adjusted for obtaining the best performing MOF structure with high selectivity, high working capacity, and high regenerability. MOFs with a largest cavity diameter close to 10 Å show high values of selectivity, working capacity, and regenerability.

Experimental evidence on RH-dependent crossover from an electronic to protonic conduction with an oscillatory behaviour

Krupanidhi

2017

An oxide semiconductor changes its resistance with exposure of water molecules and is accepted to be governed by electronic and protonic conduction in low and high humid atmosphere, respectively, without any experimental evidences. Here, we report on the experimental evidence of a relative humidity (RH) dependent crossover, from an electronic to protonic conduction and its oscillatory behaviour in mesoporous SnO2. Interestingly, oscillatory conduction observed in the intermediate humidity range (70%–90% RH) lies in between two monotonic variations that substantiate the competitive adsorption and desorption processes of oxygen species and water molecules. In addition, we have shown that the conduction process can be tuned predominantly electronic or protonic by pre- and post-UV treatment. The conductance increases by 2–3 orders as the conduction changes from pure electronic to protonic, suggesting an insulator-to-metal like transition.

Sequential Elemental Dealloying Approach for the Fabrication of Porous Metal Oxides and Chemiresistive Sensors Thereof for Electronic Listening

ACS Appl. Mater. Interfaces

Krupanidhi

2017

Highly porous materials, with large surface area and accessible space, variable chemical compositions, and porosity at different length scales, have captivated the attention of researchers in recent years as an important family of functional materials. Here, we report a novel approach to grow porous metal oxides (PMOs) by sequential elemental dealloying in which a highly mobile element gets dealloyed first under the thermal treatment (annealing) and facilitates the formation of PMOs. Subsequently, a chemiresistive sensor based on porous SnO was fabricated for humidity sensing at room temperature which shows a high sensitivity of 348 in a fully humid [>99% relative humidity (RH)] atmosphere with an accuracy of 1% RH change. In addition, the sensor is highly durable and reproducible. Eventually, the chemiresistive sensor has been exploited for electronic listening toward speaking, whistling, and breath monitoring. Overall, the results advocate the fabrication of PMOs and the development of resistive humidity sensors for electronic listening as well as for biomedical applications.

Exploring the Potentials of Metal–Organic Frameworks as Adsorbents and Membranes for Separation of Hexane Isomers

Borah

2019

J. Phys. Chem. C

Molecular modelling and computational science tools were employed to select a number of metal−organic frameworks (MOFs) from a pool of 4764 structures to investigate and assess their kinetic and adsorption-based separation performances in separating hexane isomers. The self-diffusivities of all single-component isomers were obtained from molecular dynamics simulations at infinite dilution and at a loading of 4 molecules/unit cell and at several temperatures. The self-diffusivities of the binary mixtures of the hexane isomers were also computed to obtain the kinetic separation metrics. The diffusivities at infinite dilution and at 298 K show a variety of trends as a degree of branching in the chosen MOFs. The linear hexane diffuses faster than other isomers in majority of the MOFs. On the other hand, the MOFs considered here show reverse adsorption selectivity, with the dibranched isomers adsorbing more than the linear one. The diffusivities at infinite dilution, as a function of temperature, of all isomers in the MOFs considered in the present study show Arrhenius behavior. The activation energies calculated from the Arrhenius plots complement the diffusivities. Further, the performances of these chosen MOFs were assessed in separating the linear hexane from the two dibranched ones as well as the dibranched ones from each other. MOF IYIHUU shows the highest membrane selectivity of the dibranched hexanes over the linear one at 433 K and at a pressure of 10 bar. Several MOFs show membrane selectivity of 22DMB over 23DMB, close to two or more indicating their ability to distinguish the two dibranched isomers kinetically.

Structural And Optical Study Of MeV Cobalt Ion Implanted Silicon

Mishra¹,

Solanki²,

Rath³

et al. 2014

Adv. Mater. Lett.