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Alexander M. Korsunsky
Researcher at University of Oxford
Publications - 509
Citations - 10943
Alexander M. Korsunsky is an academic researcher from University of Oxford. The author has contributed to research in topics: Residual stress & Eigenstrain. The author has an hindex of 43, co-authored 476 publications receiving 8888 citations. Previous affiliations of Alexander M. Korsunsky include University of New Mexico & University of Newcastle.
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On the hardness of coated systems
TL;DR: In this article, the hardness of a number of coated systems has been measured using a variety of experimental techniques ranging from traditional macro-Vickers indentation to ultra-low-load depth-sensing nanoindentation.
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Solution of Crack Problems: The Distributed Dislocation Technique
TL;DR: In this paper, the authors introduce the concept of Dislocation Influence Functions for Plane and Ring Dipole Influence Functions (DIF) and derive the solution of Axi-Symmetric Crack Problems.
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Ultrafast three-dimensional imaging of lattice dynamics in individual gold nanocrystals
Jesse N. Clark,Loren Beitra,Gang Xiong,Andrew Higginbotham,David Fritz,Henrik T. Lemke,Diling Zhu,M. Chollet,Garth J. Williams,Marc Messerschmidt,Brian Abbey,Ross Harder,Alexander M. Korsunsky,Justin Wark,Ian K. Robinson +14 more
TL;DR: Three-dimensional imaging of the generation and subsequent evolution of coherent acoustic phonons on the picosecond time scale within a single gold nanocrystal by means of an x-ray free-electron laser is reported, providing insights into the physics of this phenomenon.
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3D-printed PEEK-carbon fiber (CF) composites: Structure and thermal properties
А.А. Stepashkin,D.I. Chukov,Fedor Senatov,A.I. Salimon,A.I. Salimon,Alexander M. Korsunsky,Alexander M. Korsunsky,Sergey Kaloshkin +7 more
TL;DR: In this article, 3D-printed CF-PEEK composites were compared with their cast counterparts and the characterization of composite thermal properties in the range 25-300°C revealed that 3-D-print composites manifest 25-30% lower thermal conductivity than cast composites.