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Singh, Dhananjay
- Together we can Together we will!
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1 All India Management Association, IN
1 All India Management Association, IN
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Review of Professional Management- A Journal of New Delhi Institute of Management, Vol 7, No 1 (2009), Pagination: 105-106Abstract
No Abstract.- Insights into the Great Mw 7.9 Nepal Earthquake of 25 April 2015
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Authors
Affiliations
1 Department of Applied Geophysics, Indian Institute of Technology (Indian School of Mines), Dhanbad 826 007, IN
2 Life, Environmental and Earth Sciences Division, University of Bucharest, RO
1 Department of Applied Geophysics, Indian Institute of Technology (Indian School of Mines), Dhanbad 826 007, IN
2 Life, Environmental and Earth Sciences Division, University of Bucharest, RO
Source
Current Science, Vol 113, No 10 (2017), Pagination: 2014-2020Abstract
The 2015 Mw 7.9 earthquake occurred in the Nepal Himalaya between the Indian and Asian plates. The gravity modelling has been carried out along a 2D trench-orthogonal profile passing through the epicentre of this earthquake. The projections of mainshocks and aftershocks show their major confinement around the bending segment of the Indian upper crust (IUC). The operative shallowly plunging maximum compressive stress led to the accumulation of strain energy around the bending zone of the IUC, and triggered thrust-dominated southward movement of the Indian crustal block along a shallowly, dipping shear plane in the anisotropic layer. This can be broadly explained by three-stage rupture processes: the first one was associated with slow nucleation and rupture growth for early ~15 sec, the second one migrated upward, rupturing the uppermost part of the IUC for the next ~10 sec, and the third one propagated very fast during deformation for the remaining ~25 sec till the fracture- tip reached the overlying brittle Asian crust.Keywords
2015 Nepal Earthquake, Frictional Sliding, Gravity Modelling, Indian Upper Crust.References
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- Elastic and Thermo-Acoustic Study of YM Intermetallics
Abstract Views :230 |
PDF Views:1
Authors
Aftab Khan
1,
Chandreshvar Prasad Yadav
1,
Dharmendra Kumar Pandey
1,
Dhananjay Singh
2,
Devraj Singh
3
Affiliations
1 Department of Physics, P.P.N. (P.G.) College, Kanpur-208001, IN
2 Department of Chemistry, P.P.N. (P.G.) College, Kanpur-208001, IN
3 Amity Institute of Applied Sciences, Amity University, Noida-201313, IN
1 Department of Physics, P.P.N. (P.G.) College, Kanpur-208001, IN
2 Department of Chemistry, P.P.N. (P.G.) College, Kanpur-208001, IN
3 Amity Institute of Applied Sciences, Amity University, Noida-201313, IN
Source
Journal of Pure and Applied Ultrasonics, Vol 41, No 1 (2019), Pagination: 1-8Abstract
The work involves estimation of elastic, ultrasonic and thermo-physical properties of YM (Y: Yttrium, M=Zn, Cu, Ag) intermetallics at 300 K. Initially, second order elastic constants and elastic modulus of chosen intermetallics are determined in temperature range 300K-1200K under potential model approach. Later, the ultrasonic velocities are calculated using second order elastic constants and densities for wave propagation along <100>, <110> and <111> crystallographic directions. Additionally, Debye temperature, specific heat at constant volume, thermal conductivity and thermal relaxation time are also calculated. The analysis reveals that compound YCu incorporates better mechanical and thermal properties than the other two compounds.Keywords
Intermetallics, Elastic Properties, Ultrasonic Velocity, Thermal Relaxation Time, Thermal Conductivity.References
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- Wu Y., Hu W. and Han S., First principle calculation of the elastic constants, the electronic density of the states and the ductility mechanism of the intermetallic compounds: YAg, YCu and YRh, Physica B 403 (2008) 3792-3797.
- Wang R., Wang S. and Xiaozhi Wu., On third-order elastic constants for ductile rare-earth intermetallic compounds: A first-principles study, Intermetallics 18 (2010) 1653-1658.
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- Bhalla V., Singh D., Jain S. K. and Kumar R., Ultrasonic attenuation in rare-earth monoarsenides, Pramana 86 (2016) 1355-1367.
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- Yadav A. K., Yadav R. R., Pandey D. K. and Singh D., Ultrasonic study of fission products precipitated in the nuclear field, Mat. Lett., 62 (2008) 3258-3261.
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- An ultrasonic exploration of physico-chemical properties for mixtures of dichloroacetyl chloride with polar, non-polar and polymers at 300 K
Abstract Views :83 |
PDF Views:0
Authors
Mahendra Kumar
1,
Chandreshvar Prasad Yadav
1,
Dharmendra Kumar Pandey
1,
Dhananjay Singh
2,
Renuka Arora
1
Affiliations
1 Department of Physics, P.P.N. (P.G.) College, Kanpur-208 001, Uttar Pradesh, India., IN
2 Department of Chemistry, P.P.N. (P.G.) College, Kanpur-208 001, Uttar Pradesh, India., IN
1 Department of Physics, P.P.N. (P.G.) College, Kanpur-208 001, Uttar Pradesh, India., IN
2 Department of Chemistry, P.P.N. (P.G.) College, Kanpur-208 001, Uttar Pradesh, India., IN
Source
Journal of Pure and Applied Ultrasonics, Vol 44, No 1-2 (2022), Pagination: 17-27Abstract
The present study is oriented towards the demonstration of physico-chemical properties and molecular interactions of the prepared binary mixture of Dichloroacetyl chloride (DCAC) with methanol/ethanol/CCl 4 / PEGs through ultrasonic non-destructive characterization. The intermolecular interaction, structural ordering, and corrosiveness aspects of prepared binary mixtures have been interpreted on the basis of measured (density, viscosity, ultrasonic velocity) and estimated thermo-physical quantities (compressibility, free length, free volume, Gibb's free energy, thermal relaxation time, and ultrasonic absorption) at 300K. All binary mixtures have been received to undergo exothermic reaction during preparation while mixture DCAC + methanol has been found to produce excessive heat and harmful odour vapour. The study confirms that DCAC+CCl 4 consist of least intermolecular interaction while mixture DCAC with PEG600 possesses strong molecular interaction among constituents accomplished by intense hydrogen bonding and physical forces. It also concludes that DCAC + PEG600 shall be highly viscous and least corrosive in comparison to other prepared mixtures. The present study provides new dimension for applicability of hazardous chemical DCAC in mixture form toward herbicides, pesticides, and fertilizers industries.Keywords
Binary Liquid Mixture, Intermolecular Interaction, Physico-Chemical Properties, Ultrasonic Parameters.References
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