Your search keyword '"Abhishek Parija"' showing total 8 results

1. Mapping Catalytically Relevant Edge Electronic States of MoS2

Author

Abhishek Parija, Yun-Hyuk Choi, Zhuotong Liu, Justin L. Andrews, Luis R. De Jesus, Sirine C. Fakra, Mohammed Al-Hashimi, James D. Batteas, David Prendergast, and Sarbajit Banerjee

Subjects

Chemistry, QD1-999

Published

2018

2. Mapping polaronic states and lithiation gradients in individual V2O5 nanowires

Author

Luis R. De Jesus, Gregory A. Horrocks, Yufeng Liang, Abhishek Parija, Cherno Jaye, Linda Wangoh, Jian Wang, Daniel A. Fischer, Louis F. J. Piper, David Prendergast, and Sarbajit Banerjee

Subjects

Science

Abstract

Rapid insertion and extraction of lithium ions from a cathode material is imperative for lithium-ion battery function. Here, the authors present evidence of inhomogeneities in charge localization, local structural distortions and polaron formation induced upon lithiation using scanning transmission X-ray microscopy.

Published

2016

3. Reversible Room-Temperature Fluoride-Ion Insertion in a Tunnel-Structured Transition Metal Oxide Host

Author

Sarbajit Banerjee, Wasif Zaheer, Abhishek Parija, Conan Weiland, Justin L. Andrews, Cherno Jaye, Jesus M. Velazquez, Jinghua Guo, David A. Shapiro, Daniel A. Fischer, Young-Sang Yu, and Forrest P. Hyler

Subjects

Battery (electricity), Materials science, Renewable Energy, Sustainability and the Environment, Oxide, Energy Engineering and Power Technology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Energy storage, 0104 chemical sciences, Ion, chemistry.chemical_compound, Fuel Technology, Chemical engineering, chemistry, Transition metal, Chemistry (miscellaneous), Materials Chemistry, Charge carrier, 0210 nano-technology, Host (network), Fluoride

Abstract

An energy storage paradigm orthogonal to Li-ion battery chemistries can be conceptualized by employing anions as the primary charge carriers. F-ion conversion chemistries show promise but have limi...

Published

2020

4. Reversible Mg-Ion Insertion in a Metastable One-Dimensional Polymorph of V2O5

Author

Sarbajit Banerjee, David Prendergast, Jordi Cabana, Arijita Mukherjee, Justin L. Andrews, Robert F. Klie, Hyun Deog Yoo, Abhishek Parija, Peter M. Marley, and Sirine C. Fakra

Subjects

Battery (electricity), Materials science, General Chemical Engineering, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, Electrochemistry, 01 natural sciences, Biochemistry, Ion, law.invention, Divalent, law, Formula unit, Materials Chemistry, Environmental Chemistry, chemistry.chemical_classification, X-ray absorption spectroscopy, Magnesium, Biochemistry (medical), General Chemistry, 021001 nanoscience & nanotechnology, Cathode, 0104 chemical sciences, Crystallography, chemistry, 0210 nano-technology

Abstract

Summary The Li-ion paradigm of battery technology is constrained by the monovalency of the Li ion. A straightforward solution is to transition to multivalent-ion chemistries, where Mg 2+ is the most obvious candidate because of its size and mass. The realization of Mg batteries has faced myriad obstacles, including a sparse selection of cathode materials demonstrating the ability to reversibly insert divalent ions. Here, we provide evidence of reversible topochemical and electrochemical insertion of Mg 2+ into a metastable one-dimensional polymorph of V 2 O 5 up to a capacity of 0.33 Mg 2+ per formula unit. An electrochemical capacity of 90 mA hr g −1 was retained after 100 cycles with an average operating potential of 1.65 V versus Mg 2+ /Mg 0 . Not only does ζ-V 2 O 5 represent a rare addition to the pantheon of functional Mg battery cathode materials, but it is also distinctive in exhibiting a combination of high stability, high specific capacity, and moderately high operating voltage.

Published

2018

5. Electronic structure modulation of MoS2 by substitutional Se incorporation and interfacial MoO3 hybridization: Implications of Fermi engineering for electrocatalytic hydrogen evolution and oxygen evolution

Author

Theodore E. G. Alivio, Sirine C. Fakra, Mohammed Al-Hashimi, Wasif Zaheer, Abhishek Parija, Sarbajit Banerjee, David Prendergast, and Junsang Cho

Subjects

Materials science, chemistry, Chemical physics, Oxygen evolution, Water splitting, chemistry.chemical_element, Heterojunction, Reactivity (chemistry), General Medicine, Electronic structure, Overpotential, Platinum, Catalysis

Abstract

The design of earth-abundant electrocatalysts that can facilitate water splitting at low overpotentials, provide high current densities, and enable prolonged operational lifetimes is central to the production of sustainable fuels. The distinctive atomistic and electronic structure characteristics of the edges of MoS2 imbue high reactivity toward the hydrogen evolution reaction. MoS2 is nevertheless characterized by significantly high overpotentials as compared to platinum. Here, we demonstrate that modulation of the electronic structure of MoS2 through interfacial hybridization with MoO3 and alloying of selenium on the anion sublattice allows for systematic lowering of the conduction band edge and raising of the valence band edge, respectively. The former promotes enhanced electrocatalytic activity toward hydrogen evolution, whereas the latter promotes enhanced activity toward the oxygen evolution reaction. Such alloyed heterostructures prepared by sol-gel reactions and hydrothermal selenization expose a high density of edge sites. The alloyed heterostructures exhibit low overpotential, high current density, high turnover frequency, and prolonged operational lifetime. The mechanistic origins of catalytic activity have been established based on electronic structure calculations and x-ray absorption and emission spectroscopy probes of electronic structure, which suggest that interfacial hybridization at the MoO3 interface yields low-lying conduction band states that facilitate hydrogen adsorption. In contrast, shallow Se 4p-derived states give rise to a raised effective valence band maximum, which facilitates adsorption of oxygen intermediates and engenders a low overpotential for the oxygen evolution reaction. The findings illustrate the use of electronic structure modulation through interfacial hybridization and alloying to systematically improve electrocatalytic activity.

Published

2021

6. Mapping Catalytically Relevant Edge Electronic States of MoS2

Author

Zhuotong Liu, Abhishek Parija, Yun-Hyuk Choi, Sirine C. Fakra, Sarbajit Banerjee, David Prendergast, Luis R. De Jesus, Justin L. Andrews, James D. Batteas, and Mohammed Al-Hashimi

Subjects

Materials science, Nanostructure, Absorption spectroscopy, General Chemical Engineering, 02 engineering and technology, General Chemistry, Electronic structure, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Catalysis, Chemistry, chemistry.chemical_compound, Transition metal, chemistry, Chemical physics, Yield (chemistry), Chemical Sciences, Reactivity (chemistry), 0210 nano-technology, QD1-999, Molybdenum disulfide

Abstract

© 2018 American Chemical Society. Molybdenum disulfide (MoS2) is a semiconducting transition metal dichalcogenide that is known to be a catalyst for both the hydrogen evolution reaction (HER) as well as for hydro-desulfurization (HDS) of sulfur-rich hydrocarbon fuels. Specifically, the edges of MoS2nanostructures are known to be far more catalytically active as compared to unmodified basal planes. However, in the absence of the precise details of the geometric and electronic structure of the active catalytic sites, a rational means of modulating edge reactivity remain to be developed. Here we demonstrate using first-principles calculations, X-ray absorption spectroscopy, as well as scanning transmission X-ray microscopy (STXM) imaging that edge corrugations yield distinctive spectroscopic signatures corresponding to increased localization of hybrid Mo 4d states. Independent spectroscopic signatures of such edge states are identified at both the S L2,3and S K-edges with distinctive spatial localization of such states observed in S L2,3-edge STXM imaging. The presence of such low-energy hybrid states at the edge of the conduction band is seen to correlate with substantially enhanced electrocatalytic activity in terms of a lower Tafel slope and higher exchange current density. These results elucidate the nature of the edge electronic structure and provide a clear framework for its rational manipulation to enhance catalytic activity.

Published

2018

7. Mapping polaronic states and lithiation gradients in individual V2O5 nanowires

Author

Sarbajit Banerjee, Gregory A. Horrocks, Jian Wang, Cherno Jaye, David Prendergast, Linda Wangoh, Louis F. J. Piper, Abhishek Parija, Yufeng Liang, Luis R. De Jesus, and Daniel A. Fischer

Subjects

Phase transition, Materials science, Science, Nanowire, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, Electron, 010402 general chemistry, Polaron, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Ion, law.invention, law, Multidisciplinary, Charge density, General Chemistry, 021001 nanoscience & nanotechnology, Cathode, Electron localization function, 0104 chemical sciences, Chemical physics, 0210 nano-technology

Abstract

The rapid insertion and extraction of Li ions from a cathode material is imperative for the functioning of a Li-ion battery. In many cathode materials such as LiCoO2, lithiation proceeds through solid-solution formation, whereas in other materials such as LiFePO4 lithiation/delithiation is accompanied by a phase transition between Li-rich and Li-poor phases. We demonstrate using scanning transmission X-ray microscopy (STXM) that in individual nanowires of layered V2O5, lithiation gradients observed on Li-ion intercalation arise from electron localization and local structural polarization. Electrons localized on the V2O5 framework couple to local structural distortions, giving rise to small polarons that serves as a bottleneck for further Li-ion insertion. The stabilization of this polaron impedes equilibration of charge density across the nanowire and gives rise to distinctive domains. The enhancement in charge/discharge rates for this material on nanostructuring can be attributed to circumventing challenges with charge transport from polaron formation., Rapid insertion and extraction of lithium ions from a cathode material is imperative for lithium-ion battery function. Here, the authors present evidence of inhomogeneities in charge localization, local structural distortions and polaron formation induced upon lithiation using scanning transmission X-ray microscopy.

Published

2016

8. Mechanism of catalytic functionalization of primary C-H bonds using a silylation strategy

Author

Raghavan B. Sunoj and Abhishek Parija

Subjects

Silylation, Organic Chemistry, Cyclohexanol, Activation, Alcohol, Ligands, Photochemistry, Biochemistry, Medicinal chemistry, Carbon, Reductive elimination, Cross-Coupling Reactions, Catalysis, chemistry.chemical_compound, Monomer, Complexes, chemistry, Density Functionals, Surface modification, Density functional theory, Physical and Theoretical Chemistry

Abstract

The mechanism of Ir-catalyzed gamma-functionalization of a primary sp(3)(C-H) bond in 2-methyl cyclohexanol is examined using the density functional theory (M06). The nature of the active catalyst for the initial silylation of alcohol is identified as the monomer derived from [Ir(cod)OMe](2) while that for gamma-sp(3)(C-H) activation leading to oxasilolane is (IrH(nbe)(phen)]. The rate-determining step is found to involve Si-C coupling through reductive elimination.

Published

2013