Publication detail
Fractography of AlCoCrFeNiTi0.5 powder multi-principal-element alloy
MORAVČÍK, I. HANUSOVÁ, P. ČUPERA, J. ZAPLETAL, J. ČÍŽEK, J. DLOUHÝ, I.
English title
Fractography of AlCoCrFeNiTi0.5 powder multi-principal-element alloy
Type
conference paper
Language
en
Original abstract
Multi-principal element alloys are new class of materials forming single major multi element solid solutions phases. AlCoCrFeNiTi0.5 bulk alloy has been obtained by a combination of high-energy milling and spark plasma sintering. Three point bending test, Vickers microhardness test, X-ray diffraction (XRD) and scanning electron microscopy (SEM) methods were utilized to observe mechano-chemical reactions during milling, sintered bul alloy behavior and microstructures before and after annealing and mechanical performance. Bulk alloy consists of combination of four phases, namely major FCC and ordered B2 phase and minor σ and carbide phase with ultra-fine grains. Highest bending strength obtained was 1275 MPa with 97.52 GPa elastic modulus. Structure has been revealed to be somewhat brittle with low-energy brittle fracture with no apparent plastic deformation in fracture surfaces. This can be the result of synergic effect of extreme grain refinement and brittle ordered phases presence
English abstract
Multi-principal element alloys are new class of materials forming single major multi element solid solutions phases. AlCoCrFeNiTi0.5 bulk alloy has been obtained by a combination of high-energy milling and spark plasma sintering. Three point bending test, Vickers microhardness test, X-ray diffraction (XRD) and scanning electron microscopy (SEM) methods were utilized to observe mechano-chemical reactions during milling, sintered bul alloy behavior and microstructures before and after annealing and mechanical performance. Bulk alloy consists of combination of four phases, namely major FCC and ordered B2 phase and minor σ and carbide phase with ultra-fine grains. Highest bending strength obtained was 1275 MPa with 97.52 GPa elastic modulus. Structure has been revealed to be somewhat brittle with low-energy brittle fracture with no apparent plastic deformation in fracture surfaces. This can be the result of synergic effect of extreme grain refinement and brittle ordered phases presence
Keywords in English
multi-principal element alloy, mechanical alloying, powder metallurgy, bending
Released
03.06.2016
Location
Brno
ISBN
978-80-214-5358-6
Book
MULTI- SCALE DESIGN OF ADVANCED MATERIALS. 2016
Edition number
2
Pages from–to
25–29
Pages count
86
BIBTEX
@inproceedings{BUT130750,
author="Igor {Moravčík} and Petra {Hanusová} and Jan {Čupera} and Josef {Zapletal} and Jan {Čížek} and Ivo {Dlouhý},
title="Fractography of AlCoCrFeNiTi0.5 powder multi-principal-element alloy",
booktitle="MULTI- SCALE DESIGN OF ADVANCED MATERIALS. 2016",
year="2016",
month="June",
pages="25--29",
address="Brno",
isbn="978-80-214-5358-6"
}