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Strength of zirconium--titanium martensites and deformation behaviour

Journal Article · · Acta Metall.; (United States)
; ;

The deformation behavior of pure zirconium and of zirconium--titanium alloys containing 5, 10, 15 and 20 wt % titanium was studied in two heat treated conditions: furnace cooled and water quenched from the ..beta.. phase field. By comparing the flow stresses of the furnace cooled ..cap alpha.. and the water quenched ..cap alpha..' (martensite) structures it was possible to isolate the strengthening contributions of the martensitic structure (comprising the contributions due to the small size of the martensite units and to the distributions of defects like dislocations and internal twins) from those arising from the solid solution. The internally twinned plate martensite structure in the Zr--15% Ti and the Zr--20% Ti alloys was responsible for a significant increase in strength, while the strengthening due to the dislocated lath martensite structure in the more dilute alloys was only marginal. Stress relaxation experiments revealed that strengthening associated with the martensite structure was mainly due to an increase in the athermal component of the flow stress. The effectiveness of the lath boundaries and the (10 anti 11) twin boundaries in offering resistance to an approaching deformation front (either slip or twin) was examined. While the lath boundaries were found to be transparent with respect to the propagation of slip dislocations and deformation twins, a majority of plate as well as twin boundaries were effective barriers against their propagation. TEM observations showed an extensive accumulation of geometrically necessary dislocations in the plastically deformed twinned martensites. Enhanced work hardening was related to the geometric slip distances in these structures in accordance with Ashby's one parameter work hardening theory for plastically inhomogeneous materials. The effect of the martensite structure on different components of the flow stress (dependent on or independent of grain size and strain) was discussed.

Research Organization:
Bhabha Atomic Research Centre, Bombay, IN
OSTI ID:
6344816
Journal Information:
Acta Metall.; (United States), Journal Name: Acta Metall.; (United States) Vol. 26:12; ISSN AMETA
Country of Publication:
United States
Language:
English

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Related Subjects

36 MATERIALS SCIENCE
360102 -- Metals & Alloys-- Structure & Phase Studies
360103* -- Metals & Alloys-- Mechanical Properties
ALLOYS
CARBON ADDITIONS
COOLING
CRYSTAL DEFECTS
CRYSTAL STRUCTURE
CRYSTAL-PHASE TRANSFORMATIONS
DEFECTS
DEFORMATION
DISLOCATIONS
ELEMENTS
GRAIN SIZE
HARDENING
HEAT TREATMENTS
IRON ALLOYS
LINE DEFECTS
MARTENSITE
MECHANICAL PROPERTIES
METALLURGICAL EFFECTS
METALS
MICROSTRUCTURE
PHASE TRANSFORMATIONS
PLASTICITY
QUENCHING
SIZE
SLIP
STRAIN HARDENING
STRESS RELAXATION
TITANIUM ALLOYS
TRANSITION ELEMENTS
TWINNING
ZIRCONIUM
ZIRCONIUM ALLOYS
ZIRCONIUM BASE ALLOYS