Ali Farajpour

What is he best known for?

The fields of study he is best known for:

• Classical mechanics
• Mechanics
• Composite material

Ali Farajpour mostly deals with Classical mechanics, Boundary value problem, Buckling, Nyström method and Mechanics. His studies deal with areas such as Vibration and Nanorod as well as Classical mechanics. His research on Boundary value problem frequently links to adjacent areas such as Graphene.

The various areas that Ali Farajpour examines in his Buckling study include Continuum mechanics and Rotational symmetry. He combines subjects such as Composite material, Material properties and Orthotropic material with his study of Nyström method. His Mechanics research includes themes of Nanoscopic scale, Galerkin method and Differential equation.

His most cited work include:

• AXIAL VIBRATION ANALYSIS OF A TAPERED NANOROD BASED ON NONLOCAL ELASTICITY THEORY AND DIFFERENTIAL QUADRATURE METHOD (133 citations)
• Buckling of orthotropic micro/nanoscale plates under linearly varying in-plane load via nonlocal continuum mechanics (130 citations)
• A higher-order nonlocal strain gradient plate model for buckling of orthotropic nanoplates in thermal environment (120 citations)

What are the main themes of his work throughout his whole career to date?

His primary areas of investigation include Mechanics, Vibration, Boundary value problem, Galerkin method and Classical mechanics. His Mechanics study combines topics in areas such as Nanofluid, Bifurcation, Buckling, Differential equation and Viscoelasticity. His work on Plate theory as part of general Vibration research is frequently linked to Work, thereby connecting diverse disciplines of science.

His work in the fields of Boundary value problem, such as Nyström method, intersects with other areas such as Scale. His work carried out in the field of Galerkin method brings together such families of science as Discretization, Elasticity, Elasticity and Nanotube. His work in the fields of Classical mechanics, such as Surface stress, overlaps with other areas such as Molecular dynamics.

He most often published in these fields:

• Mechanics (60.71%)
• Vibration (38.10%)
• Boundary value problem (34.52%)

What were the highlights of his more recent work (between 2018-2021)?

• Mechanics (60.71%)
• Galerkin method (32.14%)
• Viscoelasticity (21.43%)

In recent papers he was focusing on the following fields of study:

Ali Farajpour spends much of his time researching Mechanics, Galerkin method, Viscoelasticity, Nanofluid and Vibration. His Mechanics study incorporates themes from Transverse plane, Nanotube, Buckling and Bifurcation. His research integrates issues of Discretization and Composite material, Elasticity in his study of Galerkin method.

Carbon nanotube is closely connected to Hamilton's principle in his research, which is encompassed under the umbrella topic of Viscoelasticity. His Vibration research integrates issues from Boundary value problem, Classical mechanics and Continuum. Ali Farajpour interconnects Bending, Curvature and Inertia in the investigation of issues within Boundary value problem.

Between 2018 and 2021, his most popular works were:

• A review on the mechanics of functionally graded nanoscale and microscale structures (111 citations)
• Global dynamics of fluid conveying nanotubes (43 citations)
• Influence of initial edge displacement on the nonlinear vibration, electrical and magnetic instabilities of magneto-electro-elastic nanofilms (35 citations)

In his most recent research, the most cited papers focused on:

• Mechanics
• Stiffness
• Composite material

Ali Farajpour mainly focuses on Mechanics, Galerkin method, Viscoelasticity, Buckling and Microscale chemistry. He performs multidisciplinary study on Mechanics and Quantum nonlocality in his works. His Buckling research includes elements of Nanostructure, Continuum mechanics, Couple stress and Nonlinear vibration.

Microscale chemistry overlaps with fields such as Boundary value problem, Microtechnology and Nanoscopic scale in his research. His study in Boundary value problem is interdisciplinary in nature, drawing from both Curvature, Bifurcation and Inertia. His Microsystem research is multidisciplinary, incorporating perspectives in Vibration, Constitutive equation and Shear.

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