On the nature of γ′ phase cutting and its effect on high temperature and low stress creep anisotropy of Ni-base single crystal superalloys

Jácome, L. A.; Nörtershäuser, P.; Somsen, C.; Dlouhý, Antonín; Eggeler, G.

doi:https://dx.doi.org/10.1016/j.actamat.2014.01.021

Number of the records: 1

On the nature of γ′ phase cutting and its effect on high temperature and low stress creep anisotropy of Ni-base single crystal superalloys

1.

SYSNO ASEP	0435446
Document Type	J - Journal Article
R&D Document Type	Journal Article
Subsidiary J	Článek ve WOS
Title	On the nature of γ′ phase cutting and its effect on high temperature and low stress creep anisotropy of Ni-base single crystal superalloys
Author(s)	Jácome, L. A. (DE) Nörtershäuser, P. (DE) Somsen, C. (DE) Dlouhý, Antonín (UFM-A)_{RID, ORCID} Eggeler, G. (DE)
Number of authors	5
Source Title	Acta Materialia. - : Elsevier - ISSN 1359-6454 Roč. 69, MAY (2014), s. 246-264
Number of pages	19 s.
Language	eng - English
Country	GB - United Kingdom
Keywords	Ni-base single crystal superalloys ; Creep ; Anisotropy ; Dislocation ; Rafting
Subject RIV	JG - Metallurgy
Institutional support	UFM-A - RVO:68081723
UT WOS	000335110000024
EID SCOPUS	84896704779
DOI	10.1016/j.actamat.2014.01.021
Annotation	The creep anisotropy of the single crystal superalloy LEK 94 deformed in tension along [001] and [110] directions at 1293 K and 160 MPa was investigated. Elementary microstructural processes which are responsible for a higher increase in creep rates with strain during [110] as compared to [001] tensile loading were identified. [110] tensile creep is associated with a higher number of gamma' phase cutting events, where two dislocations with equal Burgers vectors of type (110) jointly shear the gamma' phase. The resulting (220)-type superdislocation can move by glide. In contrast, during [001] tensile loading, two dislocations with different (110)-type Burgers vectors must combine for gamma' phase cutting. The resulting (200)-type superdislocations can only move by a combination of glide and climb. The evolution of dislocation networks during creep determines the nature of the gamma' phase cutting events. The higher [110] creep rates at strains exceeding 2% result from a combination of a higher number of cutting events (density of mobile dislocations in gamma') and a higher superdislocation mobility ((220) glide) in the gamma' phase.
Workplace	Institute of Physics of Materials
Contact	Yvonna Šrámková, sramkova@ipm.cz, Tel.: 532 290 485
Year of Publishing	2015

Number of the records: 1