What is he best known for?
The fields of study he is best known for:
- Composite material
- Metallurgy
- Alloy
María Teresa Pérez-Prado mainly focuses on Metallurgy, Composite material, Microstructure, Grain size and Electron backscatter diffraction.
His Metallurgy study focuses mostly on Slip, Recrystallization, Alloy, Severe plastic deformation and Accumulative roll bonding.
His biological study deals with issues like Deformation mechanism, which deal with fields such as Creep.
His Composite material study combines topics from a wide range of disciplines, such as Nanomaterials and Nanocrystalline material.
His study looks at the relationship between Microstructure and fields such as Split-Hopkinson pressure bar, as well as how they intersect with chemical problems.
His study in Electron backscatter diffraction is interdisciplinary in nature, drawing from both Strain rate and Grain boundary.
His most cited work include:
- Microstructural evolution in adiabatic shear localization in stainless steel (339 citations)
- Texture evolution during large-strain hot rolling of the Mg AZ61 alloy (244 citations)
- Mechanical behavior and microstructural evolution of a Mg AZ31 sheet at dynamic strain rates (228 citations)
What are the main themes of his work throughout his whole career to date?
His primary scientific interests are in Metallurgy, Composite material, Microstructure, Alloy and Slip.
His is involved in several facets of Metallurgy study, as is seen by his studies on Recrystallization, Deformation mechanism, Grain boundary, Crystal twinning and Superplasticity.
As a member of one scientific family, María Teresa Pérez-Prado mostly works in the field of Grain boundary, focusing on Deformation and, on occasion, Shear band.
His Microstructure research incorporates themes from Annealing and Grain size.
María Teresa Pérez-Prado has researched Alloy in several fields, including Texture, Aluminium, Deformation and Anisotropy.
His Slip research includes elements of Creep, Precipitation hardening and Magnesium alloy.
He most often published in these fields:
- Metallurgy (76.55%)
- Composite material (49.66%)
- Microstructure (42.76%)
What were the highlights of his more recent work (between 2015-2021)?
- Composite material (49.66%)
- Slip (29.66%)
- Alloy (30.34%)
In recent papers he was focusing on the following fields of study:
María Teresa Pérez-Prado focuses on Composite material, Slip, Alloy, Microstructure and Metallurgy.
His Composite material study combines topics in areas such as Nanotechnology and Solid solution.
His Slip research integrates issues from Plasticity, Crystal twinning, Deformation mechanism, Dislocation and Grain size.
His Grain size research includes themes of Strain rate and Extrusion.
His Microstructure research is multidisciplinary, incorporating elements of Texture, Laser and Surface stress.
By researching both Metallurgy and Degradation, María Teresa Pérez-Prado produces research that crosses academic boundaries.
Between 2015 and 2021, his most popular works were:
- Precipitation strengthening and reversed yield stress asymmetry in Mg alloys containing rare-earth elements: a quantitative study (85 citations)
- Effect of lamellar orientation on the strength and operating deformation mechanisms of fully lamellar TiAl alloys determined by micropillar compression (59 citations)
- Origin of the low precipitation hardening in magnesium alloys (38 citations)
In his most recent research, the most cited papers focused on:
- Composite material
- Alloy
- Metallurgy
His primary areas of study are Composite material, Slip, Deformation mechanism, Alloy and Lamellar structure.
Many of his studies on Composite material apply to Metallurgy as well.
In his study, Diffraction is strongly linked to Solid solution, which falls under the umbrella field of Slip.
Deformation mechanism is a subfield of Microstructure that María Teresa Pérez-Prado tackles.
His Lamellar structure research is multidisciplinary, relying on both Nanoscopic scale, Quenching, Compression and Nanometre.
The study incorporates disciplines such as Ultimate tensile strength and Yield in addition to Crystal twinning.
This overview was generated by a machine learning system which analysed the scientist’s
body of work. If you have any feedback, you can
contact us
here.
