What is he best known for?
The fields of study he is best known for:
- Composite material
- Mathematical analysis
- Vibration
Vibration, Composite material, Boundary value problem, Nanoshell and Composite number are his primary areas of study.
Hamed Safarpour combines subjects such as Mechanics and Equations of motion with his study of Vibration.
He works mostly in the field of Composite material, limiting it down to topics relating to Foundation and, in certain cases, Graphene nanoplatelet, Exfoliated graphite nano-platelets, Dynamics, Axial load and Couple stress, as a part of the same area of interest.
His Boundary value problem research focuses on Nyström method in particular.
His work investigates the relationship between Composite number and topics such as Graphene that intersect with problems in Strain gradient and Nanostructure.
His work carried out in the field of Porosity brings together such families of science as Length scale and Continuum mechanics.
His most cited work include:
- Influence of surface effects on vibration behavior of a rotary functionally graded nanobeam based on Eringen's nonlocal elasticity (83 citations)
- Extremely large oscillation and nonlinear frequency of a multi-scale hybrid disk resting on nonlinear elastic foundation (78 citations)
- Multilayer GPLRC composite cylindrical nanoshell using modified strain gradient theory (70 citations)
What are the main themes of his work throughout his whole career to date?
Hamed Safarpour spends much of his time researching Vibration, Composite material, Boundary value problem, Mechanics and Nyström method.
His work deals with themes such as Functionally graded material, Shear and Couple stress, which intersect with Vibration.
Composite number, Shell, Material properties, Buckling and Porosity are the core of his Composite material study.
He interconnects Natural frequency, Angular velocity, Piezoelectricity, Length scale and Equations of motion in the investigation of issues within Boundary value problem.
His Mechanics study frequently involves adjacent topics like Tension.
His Nyström method study combines topics in areas such as Discretization, Finite element method and Viscoelasticity.
He most often published in these fields:
- Vibration (44.44%)
- Composite material (40.28%)
- Boundary value problem (40.28%)
What were the highlights of his more recent work (between 2020-2021)?
- Nyström method (30.56%)
- Viscoelasticity (25.00%)
- Mechanics (38.89%)
In recent papers he was focusing on the following fields of study:
Hamed Safarpour mainly investigates Nyström method, Viscoelasticity, Mechanics, Boundary value problem and Length scale.
His study looks at the intersection of Nyström method and topics like Composite number with Frequency analysis.
His Viscoelasticity study integrates concerns from other disciplines, such as Classical mechanics and Dynamics.
His Mechanics research includes themes of Vibration and Kinematics.
His research ties Equations of motion and Boundary value problem together.
His Length scale research includes elements of Strain gradient, Stress and Buckling.
Between 2020 and 2021, his most popular works were:
- Frequency characteristics of a viscoelastic graphene nanoplatelet–reinforced composite circular microplate: (46 citations)
- Non-polynomial framework for stress and strain response of the FG-GPLRC disk using three-dimensional refined higher-order theory (23 citations)
- On the dynamics of a curved microtubule-associated proteins by considering viscoelastic properties of the living biological cells (14 citations)
In his most recent research, the most cited papers focused on:
- Composite material
- Mathematical analysis
- Classical mechanics
His scientific interests lie mostly in Viscoelasticity, Nyström method, Graphene nanoplatelet, Classical mechanics and Dynamic modelling.
Mathematical analysis and Boundary value problem are the subject areas of his Nyström method study.
Research on Composite material and Composite number is a part of his Graphene nanoplatelet study.
His work in the fields of Classical mechanics, such as Dynamics, intersects with other areas such as Field, Microtubule-associated protein and Medical science.
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