Reinhard Pippan

What is he best known for?

The fields of study he is best known for:

• Composite material
• Metallurgy
• Thermodynamics

His primary areas of study are Composite material, Metallurgy, Microstructure, Severe plastic deformation and Tungsten. His work deals with themes such as Torsion and Homogeneity, which intersect with Composite material. His study in Torsion is interdisciplinary in nature, drawing from both Shear and Austenite.

As part of his studies on Microstructure, Reinhard Pippan frequently links adjacent subjects like Transmission electron microscopy. His Severe plastic deformation research incorporates elements of Nanocomposite, Solid solution, Nanostructure, Forging and Nanocrystalline material. His studies deal with areas such as Nuclear engineering, Divertor, Fusion power and Brittleness as well as Tungsten.

His most cited work include:

• Mechanical properties, microstructure and thermal stability of a nanocrystalline CoCrFeMnNi high-entropy alloy after severe plastic deformation (519 citations)
• Recent progress in research on tungsten materials for nuclear fusion applications in Europe (451 citations)
• A further step towards an understanding of size-dependent crystal plasticity: In situ tension experiments of miniaturized single-crystal copper samples (392 citations)

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

Reinhard Pippan mainly investigates Composite material, Metallurgy, Microstructure, Severe plastic deformation and Torsion. His Composite material study frequently draws parallels with other fields, such as Nanocrystalline material. In Metallurgy, Reinhard Pippan works on issues like Scanning electron microscope, which are connected to Copper.

The study incorporates disciplines such as Alloy, Transmission electron microscopy, Annealing and Ultimate tensile strength in addition to Microstructure. His Severe plastic deformation research is multidisciplinary, incorporating elements of Nanocomposite, Solid solution, Deformation, Coercivity and Amorphous metal. His Torsion research is multidisciplinary, relying on both Shear, Anisotropy, Nickel and Shear stress.

He most often published in these fields:

• Composite material (52.89%)
• Metallurgy (35.74%)
• Microstructure (32.02%)

What were the highlights of his more recent work (between 2019-2021)?

• Composite material (52.89%)
• Microstructure (32.02%)
• Severe plastic deformation (25.21%)

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

Reinhard Pippan focuses on Composite material, Microstructure, Severe plastic deformation, Nanocrystalline material and Torsion. His Composite material study frequently involves adjacent topics like Nickel. His Microstructure study combines topics from a wide range of disciplines, such as Ball mill, Lamellar structure, Annealing, Alloy and Yield.

He interconnects Nanocomposite, Ferromagnetism, Deformation, Coercivity and Anisotropy in the investigation of issues within Severe plastic deformation. His research in Nanocrystalline material intersects with topics in Crystal twinning, Solid solution and Phase diagram. He combines subjects such as Slip, Crystallization, Scanning electron microscope and Martensite with his study of Torsion.

Between 2019 and 2021, his most popular works were:

• Hydrogen Trapping in bcc Iron. (9 citations)
• Combined Fe and O effects on microstructural evolution and strengthening in Cu–Fe nanocrystalline alloys (6 citations)
• Fatigue crack growth in full-scale railway axles – Influence of secondary stresses and load sequence effects (6 citations)

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

• Composite material
• Thermodynamics
• Electron

Reinhard Pippan mostly deals with Composite material, Microstructure, Torsion, Nanocrystalline material and Paris' law. His studies in Microstructure integrate themes in fields like Coercivity, Nickel and Anisotropy. His work in Torsion addresses subjects such as Condensed matter physics, which are connected to disciplines such as Grain growth.

Reinhard Pippan has researched Nanocrystalline material in several fields, including Solid solution, Crystal twinning, Annealing, Supersaturation and Dislocation. His Paris' law study integrates concerns from other disciplines, such as Residual stress, Stress intensity factor and Plasticity. His Severe plastic deformation research incorporates themes from Isotropy, Strain rate and Grain Boundary Sliding.

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