Shyam Murli Manohar Dhar Dwivedi scite author profile

Shyam Murli Manohar Dhar Dwivedi

5Publications

50Citation Statements Received

43Citation Statements Given

How they've been cited

How they cite others

242

Affiliations

National Institute of Technology Durgapur

Publications

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Detailed investigation of defect states in Erbium doped In2O3 thin films

Ghosh

Dwivedi

Chakrabartty

et al. 2018

Materials Research Bulletin

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Highlights SIMS analysis confirmed the doping of Er into the In2O3 TF  I-V loop analysis gives reduced current memory window for In2O3:Er TF based device  High ideality factor was determined at low temperature and explained  Defect related photoconductivity was confirmed from low temperature measurement  10 K temporal response of the Au/In2O3:Er/Si confirmed removal of oxygen defects

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Enhancing responsivity and detectivity in broadband UV–VIS photodetector by ex-situ UV–ozone annealing technique

Murkute

Ghadi

Sushama

et al. 2020

Superlattices and Microstructures

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Experimental and theoretical study of capacitive memory of metal-oxide-semiconductor devices based on Er-doped In2O3 nano-column arrays

Ghosh

Lahiri

Dwivedi

et al. 2020

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The enhanced electronic memory performance of glancing angle deposited erbium-doped indium oxide (In2O3:Er) transparent nano-column (NCol) based metal-oxide-semiconductor (MOS) structured memory devices is reported. The fabricated MOS devices are Au/In2O3/p-Si, Au/0.26 at. % In2O3:Er/p-Si, and Au/0.48 at. % In2O3:Er/p-Si. The capacitance–voltage (C–V), conductance–voltage (G–V), C–V hysteresis, endurance, and retention properties from the cyclic current–voltage (I–V) curve of the fabricated devices were investigated in detail. The overall interface state density (Dit) for the devices at the different applied frequency (f) decreases with the increase in Er doping. The observations obtained from C–V, G–V, and Dit–f curves were theoretically explained considering a modified delta depletion model. It was found that Au/0.48 at. % In2O3:Er/p-Si does not go to inversion even at a high applied voltage. The constant capacitive memory window (MW) for Au/In2O3/p-Si is ∼1 V at the depletion region. MW increases from ∼0.6 V (sweep voltage ±6 V) to ∼2.5 V (sweep voltage ±16 V) and ∼1.4 V (sweep voltage ±6 V) to ∼6.8 V (sweep voltage ±16 V), respectively, for Au/0.26 at. % In2O3:Er/p-Si and Au/0.48 at. % In2O3:Er/p-Si. The increased MWs despite reduced Dit is explained in detail by primarily considering increased polarization switching of the In-O-Er material, asymmetric charge injection from the top electrode, and the presence of the oxygen-rich environment. The I–V hysteresis performance of the devices under a reverse bias was also improved with Er doping due to the migration of O2− inside the oxide layer. The whole analysis indicates that the gate-controlled Au/0.48 at. % In2O3:Er/p-Si MOS device is appropriate for capacitive memory applications.

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Performance of Erbium-doped TiO2 thin film grown by physical vapor deposition technique

et al. 2017

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Oblique angle deposited InN quantum dots array for infrared detection

Dwivedi

Ghosh

Ghadi

et al. 2018

Journal of Alloys and Compounds

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