Your search keyword '"Dowerah, Dikshita"' showing total 2 results

1. Partial Oxidation of Methane to Methanol by Using Molecular O2 on Pd2+ Catalyst: An Insight from Theory.

Author

Dutta, Priyanka, Biswakarma, Nishant, Dowerah, Dikshita, Neog, Shilpa, Islam, Saiful, Sarma, Srutishree, Basumatary, Moumita, Churi, Partha Pratim, Sarma, Plaban Jyoti, Gour, Nand Kishor, and Deka, Ramesh Chandra

Subjects

PARTIAL oxidation, OXIDATION of methanol, POTENTIAL energy surfaces, ATOMIC orbitals, DENSITY functional theory, METHANE as fuel, METHANOL

Abstract

The partial oxidation of methane to methanol using cationic Pd2 dimers is investigated by employing density functional theory (DFT) method. We used B3PW91 functional for geometry optimization, and frequency calculations of all species involved in [Pd2]++O2+2CH4 reaction. Furthermore, a density‐fitting triple zeta valence with single‐polarization (def2TZVP) is used in the calculation to determine the atomic orbitals of the atoms. We oxidized Pd2+ to [Pd2O2]+ using O2 and performed possible partial oxidation of methane to methanol on [Pd2O2]+ and [Pd2O]+ and explored various intermediates and transition states on the potential energy surface (PES) diagram. From Potential Energy Surface (PES) analysis, it is found that the [Pd2O2]+ in doublet spin state multiplicity (SM=2) following radical mechanism is the more preferred pathway for methane to methanol conversion. [ABSTRACT FROM AUTHOR]

Published

2023

2. Structural insight into locked nucleic acid based novel antisense modifications: A DFT calculations at monomer and MD simulations at oligomer level.

Author

Uppuladinne, Mallikarjunachari V.N., Dowerah, Dikshita, Sonavane, Uddhavesh B., Ray, Suvendra Kumar, Deka, Ramesh C., and Joshi, Rajendra R.

Subjects

*MOLECULAR dynamics, *MONOMERS, *NUCLEIC acids, *BINDING energy, *BASE pairs

Abstract

In the present study, five novel LNA based antisense modifications have been proposed. A conformational search was carried out using TANGO, followed by geometry optimization using MOPAC. Based on their electronic energies the most stable conformation for each modification was identified. Further, DFT based full geometry optimization on the most stable conformations at the gas phase B3LYP/6-31G(d,p) using a Gaussian03 and single point energy calculations on the optimized structures at the solvent phase B3LYP/6-311G(d,p) level of theory were done to derive their quantum chemical descriptors using the Gaussian09. A comparison of global reactivity descriptors confirmed that the LNA based modifications were the most reactive. Base-pair stability was recorded by observing the binding energies and base-pairing conformations of modified GC base pairs at the B3LYP/6-311G(d,p) level of theory. Molecular dynamics simulations have been performed at the oligomer duplex level by incorporating individual modifications on 20-mer RNA-RNA duplexes using AMBER16. Free energy calculations of duplex structures suggested that incorporation of A2 modification into the RNA-RNA duplex increased the duplex binding affinity similar to LNA. Whereas, the A3 modification showed less binding compared to LNA but improved binding compared to MOE. This computational approach using quantum chemical methods may be very useful to propose better modifications than the existing ones before performing the experiments in the area of antisense technology. [Display omitted] • LNA, MOE and LNA-based modifications were studied by quantum chemical calculations. • Most stable conformation for all these modifications was identified by conformational search. • LNA and LNA-based modifications are more suitable compared to others. • MD simulations were carried out on oligomer duplexes with modifications incorporated. • The proposed modification A3 has shown similar properties with LNA modification. [ABSTRACT FROM AUTHOR]

Published

2021