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Design of metastable β-Ti alloys with enhanced mechanical properties by coupling αS precipitation strengthening and TRIP effect.
- Source :
-
Materials Science & Engineering: A . Feb2022, Vol. 835, pN.PAG-N.PAG. 1p. - Publication Year :
- 2022
-
Abstract
- A strain-transformable microstructure was successfully designed in a metastable β Ti–7Mo–3Nb–3Cr–3Al alloy with enhanced mechanical properties, by introducing ∼28% α precipitates coupled with the TRIP effect, overcoming the traditional trade-off dilemma between strength and ductility in most metastable β-Ti alloys. The as-designed lamellar microstructure was predominantly deformed by stress-induced martensitic (SIM α") phase transformations, martensitic twinning and dislocation slip of the parent β grains and α laths. The β→α" transformation followed the [113] β //[112] α" //[-310] α" //[1-21] α" orientation relationship, with the {133} β habit plane predicted by the Phenomenological Theory of Martensite Crystallography (PTMC). A novel <211> α" type II martensitic twinning mode was also found, in addition to the {111} α" type I mode at SIM α"/α impinging region. The results show that, not only the lamellar α precipitates play a major role in precipitation strengthening, but they can also effectively block SIM α" propagation at the initial stages of deformation. However, SIM α" transmission across the α laths was also observed for large strains. Moreover, < c + a > pyramidal slip and shear of the α laths also contributed to the accommodation of internal stresses. Therefore, the origin of the enhanced tensile mechanical properties can be attributed to the combined effects of α precipitation strengthening coupled with the TRIP softening effect and the extra interaction stresses introduced by the α laths and other deformation products, validating the design concept. The current investigation may provide a novel strategy for designing new high-performance metastable β-Ti alloys. • A strain-transformable microstructure was successfully designed in a metastable β-Ti alloy. • The designed microstructure is deformed by stress-induced martensitic (SIM α") phase transformation and dislocation slip. • The β→α" transformation follows [113] β //[112] α" //[-310] α" //[1-21] α" orientation relationship and {133} β habit plane. • A novel <211> α" type II twinning mode has been observed at SIM α"/α impinging region for the first time. • The α precipitates could deform compatibly with the SIM α". [ABSTRACT FROM AUTHOR]
- Subjects :
- *MECHANICAL alloying
*PHASE transitions
*MICROSTRUCTURE
*MARTENSITE
Subjects
Details
- Language :
- English
- ISSN :
- 09215093
- Volume :
- 835
- Database :
- Academic Search Index
- Journal :
- Materials Science & Engineering: A
- Publication Type :
- Academic Journal
- Accession number :
- 154995795
- Full Text :
- https://doi.org/10.1016/j.msea.2022.142696