Browsing by Author "Sahoo M.R."
Now showing 1 - 9 of 9
- Results Per Page
- Sort Options
Item Band gap modulation of graphene by metal substrate: A first principles study(2018) Sahoo M.R.; Sahu S.; Kushwaha A.K.; Nayak S.K.Due to high in-plane charge carrier mobility with high electron velocity and long spin diffusion length, graphene guarantees as a completely unique material for devices with various applications. Unaffected 2pz orbitals of carbon atoms in graphene can be highly influenced by substrates and leads to tuning in electronic properties. We report here a density functional calculation of graphene monolayer based on metallic substrate like nickel surfaces. Band-gap of graphene near K points opens due to interactions between 2pz and d-orbitals of nickel atoms and the gap modulation can be done with the increasing number of layers of substrates. � 2018 Author(s).Item Charge transfer and hybridization effect at graphene-nickel interface: A tight binding model study(2019) Sahu S.; Sahoo M.R.; Kushwaha A.K.; Rout G.C.; Nayak S.K.We have investigated here, the electronic and magnetic properties of graphene�nickel system by tight-binding mean-field approach. Strong hybridization between the 2pz orbital of graphene and 3dz2 orbital of nickel occurs when monolayer graphene is placed over a single layer of ferromagnetically ordered Ni (111) metal due to the excellent lattice matching between the two layers. This hybridization greatly affects the electronic and magnetic properties of the bilayer system, resulting in a significantly reduced local magnetic moment of the nickel layer and an enhanced induced spin polarization on the graphene layer. The calculated Hamiltonian revealed critical information regarding the first-, second-and third-nearest-neighbour hopping integrals of ?? electrons of graphene besides the Coulomb correlation of electrons in nickel (111). The Hubbard type Coulomb interactions present in nickel lattices were treated within the mean-field approximation. Zubarev's technique was employed to calculate electronic Green's functions and subsequent investigation of the temperature dependent ferromagnetic magnetization of nickel (111)was carried out through self-consistent calculation. Further calculations regarding the induced magnetization in the graphene, total magnetization in bilayer layer system, electronic band dispersion, spin resolved density of states (DOS) and spin polarization efficiency have been carried out. The results were corroborated by experimental observations. � 2018 Elsevier LtdItem Engineering Redox Potential of Lithium Clusters for Electrode Material in Lithium-Ion Batteries(2017) Kushwaha A.K.; Sahoo M.R.; Nanda J.; Nayak S.K.Low negative electrode potential and high reactivity makes lithium (Li) ideal candidate for obtaining highest possible energy density among other materials. In this work we show a novel route with which the overall electrode potential could significantly be enhanced through selection of cluster size. Using first principles density functional theory and continuum dielectric model, we studied free energy and redox potential as well as investigated relative stability of Lin (n�?�8) clusters in both gas phase and solution. We found that Li3 has the lowest negative redox potential (thereby highest overall electrode potential) suggesting that cluster based approach could provide a novel way of engineering the next generation battery technology. The microscopic origin of Li3 cluster�s superior performance is related to two major factors: gas phase ionization and difference between solvation free energy for neutral and positive ion. Taken together, the present study provides insight into the engineering of redox potential in battery and could stimulate further work in this direction. � 2017, Springer Science+Business Media, LLC.Item First-principles study of a vertical spin switch in atomic scale two-dimensional platform(2019) Sahoo M.R.; Kushwaha A.K.; Pati R.; Ajayan P.M.; Nayak S.K.High in-plane charge carrier mobility and long spin diffusion length makes graphene a unique material for spin-based devices. However, in a vertical graphene junction, the 2pz orbitals of carbon atoms in graphene can be tuned via suitable magnetic substrates; this would affect the spin injection into graphene. Here, a vertical spin switch has been designed by embedding a single layer of graphene as a tunnel layer between the Ni (1 1 1) substrate. Periodic density functional approach in conjunction with Julliere's model is used to calculate the tunnel magnetoresistance (TMR). Further, single-layered hexagonal Boron Nitride (h-BN) is sandwiched between the graphene and Ni (1 1 1) substrate to understand the role of hybridization at the interface on TMR. Our calculation shows that in contrast to the graphene junction, a much higher TMR value is obtainable in the case of the graphene/h-BN multi-tunnel junction (MTJ). The TMR in graphene junction is found to decrease with the increase of an externally applied electric field, and drops to zero for a field greater than equal to 0.16 V/�. Similar phenomenon was observed in the case of h-BN/graphene MTJ, where TMR value remains unchanged for electric field up to 0.1 V/� beyond which it drops to zero. The change in hybridization and charge-carrier-population at the interface modifies the magnetic exchange interaction and magnetic anisotropy resulting in a spin flip at interface, leads to rapid drop in TMR after a threshold electric field. The high and tunable TMR value suggests h-BN assisted high performance graphene based vertical spin switch. � 2019Item Preparation and properties of activated carbon(2024) Sahoo M.R.Activated carbon or activated charcoal (AC) is a porous and nongraphitizable form of carbon and considered as an efficient adsorbent due to its high porosity and large surface area per unit volume. AC can be prepared from various carbon-rich natural and synthetic precursors, agricultural byproducts, food wastes, domestic wastes, petrochemical products, and fruit shells through a two-stage process, that is, (i) carbonization of carbonaceous precursors and (ii) activation of the carbonized precursors by physically or chemically. Depending upon the starting raw materials and product selectivity, the selective activation process is required. Based on the physical characteristics, shape, and size of particles, activated carbons are broadly classified into various categories which have specific applications. ACs can adsorb a wide range of chemicals, organic compounds, and heavy metal ions and can be operated at a wide range of temperatures and humidity conditions. Specific surface area, pore size distributions, hardness, and iodine index are the major physical properties which qualitatively measure the adsorption efficiency of AC. Activated carbons show a wide range of applications such as water or air purifications, metal extractions, catalysis, gas storage, trapping heavy metal ions from wastewater, odor removal, gas storage, and many other industrial and medical applications. � 2024 Apple Academic Press, Inc.Item Probing potential Li-ion battery electrolyte through first principles simulation of atomic clusters(2018) Kushwaha A.K.; Sahoo M.R.; Nayak S.Li-ion battery has wide area of application starting from low power consumer electronics to high power electric vehicles. However, their large scale application in electric vehicles requires further improvement due to their low specific power density which is an essential parameter and is closely related to the working potential windows of the battery system. Several studies have found that these parameters can be taken care of by considering different cathode/anode materials and electrolytes. Recently, a unique approach has been reported on the basis of cluster size in which the use of Li3 cluster has been suggested as a potential component of the battery electrode material. The cluster based approach significantly enhances the working electrode potential up to ?0.6V in the acetonitrile solvent. In the present work, using ab-initio quantum chemical calculation and the dielectric continuum model, we have investigated various dielectric solvent medium for the suitable electrolyte for the potential component Li3 cluster. This study suggests that high dielectric electrolytic solvent (ethylene carbonate and propylene carbonate) could be better for lithium cluster due to improvement in the total electrode potential in comparison to the other dielectric solvent. � 2018 Author(s).Item Study of electronic and magnetic properties of h-BN on Ni surfaces: A DFT approach(2018) Sahoo M.R.; Sahu S.; Kushwaha A.K.; Nayak S.Hexagonal boron nitride (h-BN) is a promising material for implementation in spintronics due to large band gap, low spin-orbit coupling, and a small lattice mismatch to graphene and close-packedsurfaces of fcc-Ni(111). Electronic and magnetic properties of single layer hexagonal Boron Nitride (h-BN) on Ni (111) surface have been studied with density functional calculation. Since lattice constants of nickel surfaces are very close to that of h-BN, nickel acts as a good substrate. We found that the interaction between 2Pz - 3dz2 orbitals leads to change in electronic band structure as well as density of states which results spin polarization in h-BN. � 2018 Author(s).Item Tuning the Electrocatalytic Activity of Co3O4 through Discrete Elemental Doping(2019) Swaminathan J.; Puthirath A.B.; Sahoo M.R.; Nayak S.K.; Costin G.; Vajtai R.; Sharifi T.; Ajayan P.M.To gain constructive insight into the possible effect of doping on the electrocatalytic activity of materials, a catalytic framework with a discrete distribution of dopants is an appropriate model system. Such a system assures well-defined active centers, maximum atom utilization efficiency, and hence enhanced selectivity, catalytic activity, and stability. Herein, a comprehensive investigation of the electrocatalytic activity of iron-doped cobalt oxide (Fe-Co3O4) nanosheets is presented. In order to understand the contribution of dopants, a series of materials with controlled doping levels are investigated. By controlled iron inclusion into the structure of Co3O4, an apparent improvement in the oxygen evolution reaction activity which is reflected in the decrease of 160 mV in the overpotential to reach the current density of 10 mA/cm2 is manifested. Additionally, it is shown that there exists an optimum doping content above which the catalytic activity fades. Further investigation of the system with density functional calculations reveals that, along with the optimization of adsorption energy toward the reaction intermediates, substantial downshift of the Fermi level and delocalization of electron density occurs on introducing iron ions into the structure. Copyright � 2019 American Chemical Society.Item Understanding the Role of Fluorination on the Interaction of Electrolytic Carbonates with Li+ through an Electronic Structure Approach(2019) Kushwaha A.K.; Sahoo M.R.; Nayak S.K.The donor-acceptor orbital interaction between the unoccupied orbital of Li+ and the lone pair of oxygen atoms in the carbonyl group of Li+-carbonate complexes shows significant decrease on fluorination. This has been investigated through molecular orbital formalism based density functional theory. The fluorination process lowers the binding energy (reduced up to 13.8 kcal/mol), and widens the HOMO-LUMO gap (enhanced up to 0.7 eV), which is essential for achieving electrolytes with high potential window in Li-ion battery. Furthermore, the impact of fluorination on few critical factors has been observed, i. e. dipole moment (drastic enhancement), IR spectra (most affected C=O vibrational mode shows blue shift in the spectra) and Raman active mode (carbonyl group stretching mode doublet (vC<C=>O) shifted to higher frequency) which have been probed by vibrational frequency analysis. � 2019 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim