Ricardo A. Lebensohn

What is he best known for?

The fields of study he is best known for:

• Composite material
• Thermodynamics
• Geometry

His scientific interests lie mostly in Viscoplasticity, Anisotropy, Deformation, Crystal twinning and Metallurgy. Ricardo A. Lebensohn interconnects Texture, Transverse plane, Structural material, Simple shear and Microscopy in the investigation of issues within Viscoplasticity. His Anisotropy study combines topics from a wide range of disciplines, such as Orthotropic material, Misorientation, Electron backscatter diffraction, Fourier transform and Mineralogy.

The study incorporates disciplines such as Plasticity, Finite element method, Condensed matter physics, Crystallite and Mechanics in addition to Deformation. Ricardo A. Lebensohn has researched Crystal twinning in several fields, including Slip, Hardening and Zirconium. His work on Zirconium alloy as part of general Metallurgy research is frequently linked to Critical resolved shear stress, bridging the gap between disciplines.

His most cited work include:

• A self-consistent anisotropic approach for the simulation of plastic deformation and texture development of polycrystals : application to zirconium alloys (1468 citations)
• A model for texture development dominated by deformation twinning: Application to zirconium alloys (429 citations)
• N-site modeling of a 3D viscoplastic polycrystal using Fast Fourier Transform (358 citations)

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

His primary scientific interests are in Viscoplasticity, Anisotropy, Composite material, Microstructure and Mechanics. His research in Viscoplasticity intersects with topics in Grain boundary, Homogenization, Deformation, Crystallite and Slip. The concepts of his Anisotropy study are interwoven with issues in Crystal twinning, Geometry, Finite element method, Mineralogy and Isotropy.

Crystal twinning is a subfield of Metallurgy that Ricardo A. Lebensohn investigates. His Microstructure research includes themes of Condensed matter physics, Diffraction and Texture. The Mechanics study combines topics in areas such as Plasticity, Stress, Strain rate, Constitutive equation and Forensic engineering.

He most often published in these fields:

• Viscoplasticity (31.25%)
• Anisotropy (27.08%)
• Composite material (25.83%)

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

• Dislocation (6.67%)
• Composite material (25.83%)
• Plasticity (20.83%)

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

Ricardo A. Lebensohn mostly deals with Dislocation, Composite material, Plasticity, Slip and Microstructure. Ricardo A. Lebensohn has included themes like Hardening, Mechanics, Classical mechanics and Homogenization in his Plasticity study. His Mechanics research is multidisciplinary, incorporating elements of Fast Fourier transform, Work, Finite element method and Crystallite.

His work in Crystallite addresses subjects such as Condensed matter physics, which are connected to disciplines such as Anisotropy, Lattice and Resonant ultrasound spectroscopy. His biological study spans a wide range of topics, including Viscoplasticity and Dynamic recrystallization. His studies deal with areas such as Crystal twinning and Neutron diffraction as well as Texture.

Between 2018 and 2021, his most popular works were:

• Modelling recrystallization textures driven by intragranular fluctuations implemented in the viscoplastic self-consistent formulation (25 citations)
• A fast Fourier transform-based mesoscale field dislocation mechanics study of grain size effects and reversible plasticity in polycrystals (17 citations)
• Assessing the reliability of fast Fourier transform-based crystal plasticity simulations of a polycrystalline material near a crack tip (14 citations)

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

• Composite material
• Thermodynamics
• Geometry

Fast Fourier transform, Viscoplasticity, Composite material, Slip and Mechanics are his primary areas of study. His research integrates issues of Supercomputer, Solver and Computational science in his study of Fast Fourier transform. His Viscoplasticity research incorporates elements of Misorientation, Grain boundary, Structural geology, Recrystallization and Shear.

He works mostly in the field of Slip, limiting it down to topics relating to Hardening and, in certain cases, Ductility, Diffusionless transformation, Deformation mechanism and Work hardening, as a part of the same area of interest. His Mechanics research is multidisciplinary, relying on both Plasticity, Stress, Finite difference, Point and Augmented Lagrangian method. His Finite difference study which covers Dislocation that intersects with Micromechanics, Texture, Crystal twinning and Thermodynamics.

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