Supriya Saha
Supriya Saha
Scientist, CSIR-AMPRI, Bhopal, India
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Understanding the interaction of DNA–RNA nucleobases with different ZnO nanomaterials
S Saha, P Sarkar
Physical Chemistry Chemical Physics 16 (29), 15355-15366, 2014
Tuning the energy levels of ZnO/ZnS core/shell nanowires to design an efficient nanowire-based dye-sensitized solar cell
S Saha, S Sarkar, S Pal, P Sarkar
The Journal of Physical Chemistry C 117 (31), 15890-15900, 2013
A complete set of self‐consistent charge density‐functional tight‐binding parametrization of zinc chalcogenides (ZnX; X= O, S, Se, and Te)
S Saha, S Pal, P Sarkar, AL Rosa, T Frauenheim
Journal of Computational Chemistry 33 (12), 1165-1178, 2012
Electronic structure of Thiol-capped CdTe quantum dots and CdTeQD–carbon nanotube nanocomposites
S Sarkar, S Saha, S Pal, P Sarkar
The Journal of Physical Chemistry C 116 (40), 21601-21608, 2012
Quantum Chemical Simulation of Carbon Nanotube Nucleation on Al2O3 Catalysts via CH4 Chemical Vapor Deposition
AJ Page, S Saha, HB Li, S Irle, K Morokuma
Journal of the American Chemical Society 137 (29), 9281-9288, 2015
Tuning the HOMO–LUMO gap of SiC quantum dots by surface functionalization
S Saha, P Sarkar
Chemical Physics Letters 536, 118-122, 2012
Electronic structure and bandgap engineering of CdTe nanotubes and designing the CdTe nanotube–fullerene hybrid nanostructures for photovoltaic applications
S Sarkar, S Saha, S Pal, P Sarkar
RSC Advances 4 (28), 14673-14683, 2014
A ferrocene functionalized Schiff base containing Cu (II) complex: synthesis, characterization and parts-per-million level catalysis for azide alkyne cycloaddition
FR Gayen, AA Ali, D Bora, S Roy, S Saha, L Saikia, RL Goswamee, ...
Dalton Transactions 49 (20), 6578-6586, 2020
Controlling the electronic energy levels of ZnO quantum dot using mixed capping ligands
S Saha, P Sarkar
RSC Adv. 4 (4), 1640-1645, 2014
Electronic structure of ZnO/ZnS core/shell quantum dots
S Saha, P Sarkar
Chemical Physics Letters 555, 191-195, 2013
Ligand mediated tuning of the electronic energy levels of ZnO nanoparticles
S Saha, S Sarkar, S Pal, P Sarkar
RSC advances 3 (2), 532-539, 2013
Oxidative dehydrogenation of propane on the oxygen adsorbed edges of boron nitride nanoribbons
B Rajbanshi, S Saha, C Fricke, SC Ammal, A Heyden
Catalysis Science & Technology 10 (15), 5181-5195, 2020
Comparative study on the photovoltaic properties of ZnX (X= S, Se, Te) QD/CNT inorganic/organic hybrid nanocomposites
M Kar, S Saha, R Sarkar, S Pal, P Sarkar
The Journal of Physical Chemistry C 124 (14), 7652-7660, 2020
The influence of magnetic moment on carbon nanotube nucleation
S Saha, AJ Page
Carbon 105, 136-143, 2016
2D-double transition metal MXenes for spintronics applications: Surface functionalization induced ferromagnetic half-metallic complexes
KD Dihingia, S Saikia, N Yedukondalu, S Saha, GN Sastry
Journal of Materials Chemistry C 10 (47), 17886-17898, 2022
Speedy one-pot electrochemical synthesis of giant octahedrons from in situ generated pyrrolidinyl PAMAM dendrimer
A Singhania, M Dutta, S Saha, P Sahoo, B Bora, S Ghosh, D Fujita, ...
Soft Matter 16 (39), 9140-9146, 2020
Size-dependent electronic structure of semiconductor nanoparticles
S Pal, S Sarkar, S Saha, P Sarkar
Chemical Modelling, 135-167, 2012
Sequential oxidation of sulfur annulated perylenediimide: an efficient strategy to generate ultra-stable radical anions and dianions
A Khan, A Agrahari, S Saha, AL Koner
Journal of Materials Chemistry C 10 (39), 14480-14487, 2022
An Inbuilt Electronic Pawl Gates Orbital Information Processing and Controls the Rotation of a Double Ratchet Rotary Motor
A Singhania, S Chatterjee, S Kalita, S Saha, P Chettri, FR Gayen, B Saha, ...
ACS Applied Materials & Interfaces 15 (12), 15595-15604, 2023
Bandgap engineering of ZnX (X= O, S, Se, Te) QDs/Graphene nanocomposites: Towards the designing of a highly efficient light-harvesting device
KD Dihingia, S Saha, GN Sastry
Journal of Physics and Chemistry of Solids 167, 110717, 2022
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