2022 - Research.com Mechanical and Aerospace Engineering in United Kingdom Leader Award
Sondipon Adhikari spends much of his time researching Vibration, Classical mechanics, Mathematical analysis, Structural engineering and Energy harvesting. Sondipon Adhikari has researched Vibration in several fields, including Elasticity, Boundary value problem, Condensed matter physics, Mechanics and Stiffness. His Mathematical analysis research includes themes of Eigenvalues and eigenvectors, Eigenfunction and Control theory.
His work deals with themes such as Turbine and Wind power, which intersect with Structural engineering. His Energy harvesting research incorporates themes from Acoustics, Piezoelectricity and Nonlinear system. His studies in Graphene integrate themes in fields like Linear elasticity, Finite element method and Composite material.
Sondipon Adhikari mainly investigates Finite element method, Vibration, Mathematical analysis, Applied mathematics and Structural engineering. In his research on the topic of Finite element method, Graphene is strongly related with Composite material. His work in Vibration addresses subjects such as Classical mechanics, which are connected to disciplines such as Boundary value problem.
Modal analysis is closely connected to Control theory in his research, which is encompassed under the umbrella topic of Mathematical analysis. While the research belongs to areas of Applied mathematics, Sondipon Adhikari spends his time largely on the problem of Random matrix, intersecting his research to questions surrounding Matrix. He mostly deals with Stiffness in his studies of Structural engineering.
Sondipon Adhikari mostly deals with Finite element method, Vibration, Mathematical analysis, Monte Carlo method and Mathematical optimization. His Finite element method study is focused on Structural engineering in general. His Vibration research includes elements of Mechanics and Nonlinear system.
He combines subjects such as Beam, Timoshenko beam theory, Stiffness and Elastic modulus with his study of Mathematical analysis. Sondipon Adhikari works mostly in the field of Monte Carlo method, limiting it down to topics relating to Algorithm and, in certain cases, Simulation and Kriging. The various areas that Sondipon Adhikari examines in his Mathematical optimization study include Random field, Applied mathematics and Homogenization.
His scientific interests lie mostly in Finite element method, Mathematical optimization, Uncertainty quantification, Vibration and Elastic modulus. Sondipon Adhikari interconnects Piezoelectricity, Boron nitride, Material properties and Resistor in the investigation of issues within Finite element method. His Piezoelectricity study incorporates themes from Cantilever, Nanotechnology, Nanomaterials and Stiffness.
His research in Uncertainty quantification intersects with topics in Structural engineering, Probabilistic logic, Random variable and Metamodeling. His Vibration study integrates concerns from other disciplines, such as Viscoelasticity, Optoelectronics, Resonator, Mechanics and Nanosensor. His Elastic modulus research is multidisciplinary, incorporating perspectives in Classical mechanics, Statistical physics, Moduli and Hexagonal lattice.
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Effective elastic mechanical properties of single layer graphene sheets.
F Scarpa;S Adhikari;A Srikantha Phani.
Piezoelectric energy harvesting from broadband random vibrations
S Adhikari;M I Friswell;D J Inman;D J Inman.
Smart Materials and Structures (2009)
Identification of damping: Part 1, viscous damping
S. Adhikari;J. Woodhouse.
Journal of Sound and Vibration (2001)
Magnetopiezoelastic energy harvesting driven by random excitations
G. Litak;M. I. Friswell;S. Adhikari.
Applied Physics Letters (2010)
Non-linear piezoelectric vibration energy harvesting from a vertical cantilever beam with tip mass
Michael I Friswell;S Faruque Ali;Onur Bilgen;Sondipon Adhikari.
Journal of Intelligent Material Systems and Structures (2012)
Effective mechanical properties of hexagonal boron nitride nanosheets
L Boldrin;FL Scarpa;Chowdhury R;S Adhikari.
Damping modelling using generalized proportional damping
Journal of Sound and Vibration (2006)
Vibration of nonlocal Kelvin-Voigt viscoelastic damped Timoshenko beams
Y. Lei;S. Adhikari;M.I. Friswell.
International Journal of Engineering Science (2013)
Nonlocal transverse vibration of double-nanobeam-systems
T. Murmu;S. Adhikari.
Journal of Applied Physics (2010)
Dynamic Analysis of Wind Turbine Towers on Flexible Foundations
S. Adhikari;S. Bhattacharya.
Shock and Vibration (2012)
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