Mohammad Taghi Ahmadian

What is he best known for?

The fields of study he is best known for:

• Composite material
• Mechanical engineering
• Electrical engineering

Mohammad Taghi Ahmadian mainly focuses on Boundary value problem, Classical mechanics, Beam, Mathematical analysis and Timoshenko beam theory. Mohammad Taghi Ahmadian has included themes like Geometry, Structural mechanics, Graphene and Differential equation in his Boundary value problem study. His Classical mechanics research integrates issues from Finite element method, Galerkin method, Nonlinear system and Mechanics.

Mohammad Taghi Ahmadian has researched Mechanics in several fields, including Vibration and Voltage. The various areas that Mohammad Taghi Ahmadian examines in his Beam study include Cantilever, Stiffness and Deflection. The Timoshenko beam theory study combines topics in areas such as Hamilton's principle and Microbeam.

His most cited work include:

• A nonlinear Timoshenko beam formulation based on the modified couple stress theory (315 citations)
• On the size-dependent behavior of functionally graded micro-beams (307 citations)
• The modified couple stress functionally graded Timoshenko beam formulation (245 citations)

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

Mohammad Taghi Ahmadian focuses on Mechanics, Nonlinear system, Vibration, Classical mechanics and Finite element method. In his study, Carbon nanotube, Differential equation and Elasticity is inextricably linked to Boundary value problem, which falls within the broad field of Mechanics. His Nonlinear system study combines topics in areas such as Gyroscope and Microbeam.

Mohammad Taghi Ahmadian interconnects Beam, Structural engineering and Equations of motion in the investigation of issues within Vibration. His research investigates the connection between Beam and topics such as Stiffness that intersect with issues in Cantilever and Sensitivity. His study in Classical mechanics is interdisciplinary in nature, drawing from both Mathematical analysis, Instability, Deflection, Length scale and Capillary action.

He most often published in these fields:

• Mechanics (32.05%)
• Nonlinear system (28.53%)
• Vibration (26.60%)

What were the highlights of his more recent work (between 2015-2021)?

• Mechanics (32.05%)
• Finite element method (20.19%)
• Nonlinear system (28.53%)

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

Mohammad Taghi Ahmadian spends much of his time researching Mechanics, Finite element method, Nonlinear system, Vibration and Hyperelastic material. His Mechanics study integrates concerns from other disciplines, such as Natural frequency, Energy harvesting, Boundary value problem and Viscoelasticity. His Finite element method research includes elements of Normal mode, Mathematical analysis and Biomedical engineering.

His work on Galerkin method as part of general Nonlinear system study is frequently linked to Focal point, therefore connecting diverse disciplines of science. Mohammad Taghi Ahmadian has researched Vibration in several fields, including Functionally graded material, Structural engineering, Voltage, Length scale and Equations of motion. His studies examine the connections between Length scale and genetics, as well as such issues in Classical mechanics, with regards to Beam.

Between 2015 and 2021, his most popular works were:

• Electromechanical modeling and analytical investigation of nonlinearities in energy harvesting piezoelectric beams (20 citations)
• Characterization of a nonlinear MEMS-based piezoelectric resonator for wideband micro power generation (19 citations)
• Magneto-mechanical stability of axially functionally graded supported nanotubes (17 citations)

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

• Composite material
• Mechanical engineering
• Electrical engineering

Nonlinear system, Mechanics, Piezoelectricity, Constitutive equation and Vibration are his primary areas of study. The concepts of his Nonlinear system study are interwoven with issues in Bioheat transfer, Heat transfer, Ultrasonic sensor, Transducer and Biomedical engineering. His research on Piezoelectricity also deals with topics like

• Energy harvesting which is related to area like Frequency response, Electronic engineering, Cantilever, High harmonic generation and Electromechanical coupling coefficient,
• Wideband, which have a strong connection to Natural frequency, Partial differential equation, Control theory, Unimorph and Acoustics.

His research in Constitutive equation intersects with topics in Micromechanics, Hyperelastic material and Viscoelasticity. His Vibration research incorporates elements of Resonance, Functionally graded material and Voltage. His Voltage study incorporates themes from Flexural strength, Finite element method, Inertia, Curvature and Normal mode.

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