2005 - Member of the National Academy of Engineering For research on high-temperature materials, superplasticity, and ancient steels and for leadership in national defense and science programs.
2002 - Fellow of the American Association for the Advancement of Science (AAAS)
Jeffrey Wadsworth focuses on Metallurgy, Superplasticity, Strain rate, Composite material and Microstructure. His Metallurgy research focuses on Grain size, Grain boundary, Deformation, Carbide and Ceramic. In his research, Cubic zirconia is intimately related to Grain growth, which falls under the overarching field of Superplasticity.
His research integrates issues of Alloy and Ductility in his study of Strain rate. His study in the fields of Amorphous metal, Creep and Grain Boundary Sliding under the domain of Composite material overlaps with other disciplines such as Cell morphology. Jeffrey Wadsworth focuses mostly in the field of Microstructure, narrowing it down to topics relating to Elongation and, in certain cases, Tetragonal crystal system, Yttria-stabilized zirconia, Deformation and Cavitation.
Jeffrey Wadsworth mainly investigates Metallurgy, Superplasticity, Composite material, Microstructure and Strain rate. His study in Grain boundary, Grain size, Deformation, Ceramic and Deformation mechanism are all subfields of Metallurgy. He interconnects Composite number, Elongation, Grain growth and Flow stress in the investigation of issues within Superplasticity.
His research brings together the fields of Amorphous solid and Composite material. His studies in Microstructure integrate themes in fields like Ductility, Nanocrystalline material and Intermetallic. Jeffrey Wadsworth has included themes like Plasticity, Melting point, Cavitation, Newtonian fluid and High strain in his Strain rate study.
Jeffrey Wadsworth mostly deals with Metallurgy, Composite material, Amorphous metal, Crystallography and Amorphous solid. In general Metallurgy, his work in Superplasticity, Microstructure and Grain boundary is often linked to Context and Hydrogen linking many areas of study. His study in Superplasticity is interdisciplinary in nature, drawing from both Bronze Age, Toughness and Iron Age.
His Grain boundary study combines topics from a wide range of disciplines, such as Slip and Creep. His Amorphous metal research includes elements of Plasticity, Zirconium alloy, Nanoindentation, Deformation and Strain rate. The study incorporates disciplines such as Supercooling and Serration in addition to Strain rate.
His primary areas of investigation include Composite material, Metallurgy, Amorphous metal, Plasticity and Strain rate. His research in Composite material tackles topics such as Amorphous solid which are related to areas like Tension and Nucleation. His Diffusion creep, Slip, Creep, Grain Boundary Sliding and Grain boundary investigations are all subjects of Metallurgy research.
His biological study spans a wide range of topics, including Indentation, Nanoindentation and Deformation. Jeffrey Wadsworth has researched Strain rate in several fields, including Supercooling and Serration. The various areas that Jeffrey Wadsworth examines in his Supercooling study include Ductility, Mineralogy, Newtonian fluid and Deformation.
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Superplasticity in metals and ceramics
T. G. Nieh;Jeffrey Wadsworth;Oleg D. Sherby.
Hall-petch relation in nanocrystalline solids
T.G. Nieh;J. Wadsworth.
Scripta Metallurgica Et Materialia (1991)
Superplasticity—Recent advances and future directions
Oleg D. Sherby;Jeffrey Wadsworth.
Progress in Materials Science (1989)
Mechanical behaviour of laminated metal composites
D. R. Lesuer;C. K. Syn;O. D. Sherby;J. Wadsworth.
International Materials Reviews (1996)
Superplasticity at high strain rates in a SiC Whisker reinforced A1 alloy
T.G. Nieh;C.A. Henshall;J. Wadsworth.
Scripta Metallurgica (1984)
Effect of cell morphology on the compressive properties of open-cell aluminum foams
T.G. Nieh;K. Higashi;J. Wadsworth.
Materials Science and Engineering A-structural Materials Properties Microstructure and Processing (2000)
Superelastic behaviour of a fine-grained, yttria-stabilized, tetragonal zirconia polycrystal (Y-TZP)
T.G. Nieh;J. Wadsworth.
Acta Metallurgica Et Materialia (1990)
High strain rate superplasticity in a continuously recrystallized Al-6%Mg-0.3%Sc alloy
T.G. Nieh;L.M. Hsiung;J. Wadsworth;R. Kaibyshev.
Acta Materialia (1998)
Flow serration in a Zr-based bulk metallic glass in compression at low strain rates
Shuangxi Song;Hongbin Bei;J. Wadsworth;Tai-Gang Nieh.
Extended ductility at high strain rates in a mechanically alloyed aluminum alloy
T.G. Nieh;P.S. Gilman;J. Wadsworth.
Scripta Metallurgica (1985)
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