skip to main content
OSTI.GOV title logo U.S. Department of Energy
Office of Scientific and Technical Information

Title: The role of deviatoric stress and dislocations on the α to ω phase transformation in Ti

Journal Article · · Acta Materialia
ORCiD logo [1]; ORCiD logo [1]; ORCiD logo [1]
  1. Los Alamos National Lab. (LANL), Los Alamos, NM (United States)
+ Show Author Affiliations

Under extreme conditions, α-Ti becomes unstable and transforms either into β-Ti at high temperature or into ω-Ti at high pressure. In what concerns the α to ω phase transformation (PT), there has been a wide range of experimentally reported transition pressures from approximately 2 to 15 GPa at room temperature. Deviatoric stresses and internal defects are often assumed to be the root cause of this variation. Here, in this study, these postulates are revisited using both continuum mechanics and molecular dynamics (MD) simulations. First, a simple continuum model, assuming linear elasticity and isotropic plasticity, is developed to describe the effects of applied stress and dislocations on the stability of an ω nucleus in an infinite α domain. Second, a new MD simulation method is developed to generate an ω nucleus in the α domain utilizing the displacement field identified from the topological analysis. Results from MD simulations show that despite the fact that phase diagrams typically delineate the limits between two phases in terms of only P and T, deviatoric stress promotes the α to ω phase transformation by reducing the critical radius above which an ω nucleus is stable. Furthermore, the required deviatoric stress to nucleate and stabilize a nanoscale ω nucleus is likely emanating from the internal stress of defects such as dislocations. The MD-informed micromechanics models are used to identify favorable configurations where dislocations help favor the α to ω transformation. These configurations show that the interaction with a basal or prismatic dislocation reduces the critical radius of a ω nucleus by about 10 or 16 %, respectively. In addition, prismatic edge dislocations are found to promote the growth of ω nucleus when interacting with the ($$\bar{1}$$$$\bar{1}$$20)α//(0001)ω interface. Importantly, a simple model of the arrival of dislocation at an ω nucleus suggests that PT does not necessarily require a pile-up to be present but could alternatively be mediated by a constant rapid flow of dislocations.

Research Organization:
Los Alamos National Laboratory (LANL), Los Alamos, NM (United States)
Sponsoring Organization:
USDOE Office of Science (SC), Basic Energy Sciences (BES); USDOE National Nuclear Security Administration (NNSA)
Grant/Contract Number:
89233218CNA000001; FWP 06SCPE401
OSTI ID:
1902096
Alternate ID(s):
OSTI ID: 1961277
Report Number(s):
LA-UR-22-25264
Journal Information:
Acta Materialia, Vol. 244; ISSN 1359-6454
Publisher:
ElsevierCopyright Statement
Country of Publication:
United States
Language:
English

References (45)

The orientation relationship between the α- and ω-phases of titanium and zirconium journal September 1973
Orientation relationship between α-phase and high-pressure ω-phase of pure group IV transition metals journal March 2015
Anisotropic shock response of titanium: Reorientation and transformation mechanisms journal February 2014
Unravelling the nucleation and growth of {11-2¯2} twins journal July 2022
New Mechanism for the α to ω Martensitic Transformation in Pure Titanium journal July 2003
Formation of the omega phase in titanium by hydrostatic pressure soaking journal April 1971
Microscopic and crystallographic aspects of retained omega phase in shock-loaded zirconium and its formation mechanism journal February 1995
Strain-induced multivariant martensitic transformations: A scale-independent simulation of interaction between localized shear bands and microstructure journal September 2020
Crystal structures of group IVa metals at ultrahigh pressures journal October 1990
On the kinetics of a Frank-Read source journal December 1979
The influence of oxygen content on the α to ω phase transformation and shock hardening of titanium journal July 2006
Hoover NPT dynamics for systems varying in shape and size journal February 1993
Omega phase embrittlement in aged Ti-V journal May 1970
An X-ray examination of the to phase in TiV, TiMo and TiCr alloys journal July 1958
Scale-Free Modeling of Coupled Evolution of Discrete Dislocation Bands and Multivariant Martensitic Microstructure journal November 2018
A study of the stress state associated with twin nucleation and propagation in anisotropic materials journal January 1993
Three-dimensional atomic scale characterization of { 11 2 ¯ 2 } twin boundaries in titanium journal April 2021
High-pressure mechanochemistry: Conceptual multiscale theory and interpretation of experiments journal November 2004
High-resolution electron microscopy study of the (1012) twin and defects analysis in deformed polycrystalline alpha titanium journal November 1996
A formulism of two-phase equilibrium and phase diagram for elastic-plastic deformed system under non-hydrostatic stress conditions: Formulations and verification journal May 2018
Shock loading characteristics of Zr and Ti metals using dual beam velocimeter journal August 2015
Visualization and analysis of atomistic simulation data with OVITO–the Open Visualization Tool journal December 2009
Deformation twinning journal January 1995
Nanoscale mechanisms for high-pressure mechanochemistry: a phase field study journal March 2018
The strengthening effect of voids journal August 1982
The displacement field of a triangular dislocation loop journal March 1985
Phase field simulations of plastic strain-induced phase transformations under high pressure and large shear journal December 2016
Characteristic boundaries associated with three-dimensional twins in hexagonal metals journal July 2020
Formation of {112¯2} contraction twins in titanium through reversible martensitic phase transformation journal April 2021
Orientation Relations During the α - ω Phase Transition of Zirconium: In Situ Texture Observations at High Pressure and Temperature journal November 2013
Mobility of dislocations in Aluminum: Faceting and asymmetry during nanoscale dislocation shear loop expansion journal April 2019
Edge dislocations bowing out from a row of collinear obstacles in Al journal October 2016
Crystal structures of Ti under high pressure: Theory journal April 2003
The kinetics of migration of point defects to dislocations journal January 1970
Phase transformations in nanograin materials under high pressure and plastic shear: nanoscale mechanisms journal January 2014
Crystallography and a model of the α → ω phase transformation in zirconium journal April 1981
Phase transformations and tensile properties of Ti-10V-2Fe-3AI journal December 1980
Machine learning models for predictive materials science from fundamental physics: An application to titanium and zirconium journal February 2022
An atomistic-to-microscale computational analysis of the dislocation pileup-induced local stresses near an interface in plastically deformed two-phase materials journal March 2022
Alpha to omega martensitic phase transformation pathways in pure Zr journal February 2014
Classical potential describes martensitic phase transformations between the α , β , and ω titanium phases journal August 2008
Omega phase in materials journal January 1982
The kinetics of the ω to α phase transformation in Zr, Ti: Analysis of data from shock-recovered samples and atomistic simulations journal September 2014
Collective nature of plasticity in mediating phase transformation under shock compression journal June 2014
Experimental and DFT characterization of interphase boundaries in titanium and the implications for ω-assisted α phase precipitation journal June 2018

Similar Records

First-principles study of crystallographic slip modes in ω-Zr
Journal Article · Mon Aug 21 00:00:00 EDT 2017 · Scientific Reports · OSTI ID:1902096
First-principles study of the α-ω phase transformation in Ti and Zr coupled to slip modes
Journal Article · Sun Jan 28 00:00:00 EST 2018 · Journal of Applied Physics · OSTI ID:1902096
Coupled nonlinear elasticity, plastic slip, twinning, and phase transformation in single crystal titanium for plate impact loading
Journal Article · Mon Mar 25 00:00:00 EDT 2019 · Journal of the Mechanics and Physics of Solids · OSTI ID:1902096
+4 more

Related Subjects

36 MATERIALS SCIENCE
Phase transformation
α-Ti
HCP
ω-Ti
Molecular dynamics simulations