The mechanical behavior of a commercially pure titanium (CP-Ti) is systemat
ically investigated in quasi-static (Instron, servohydraulic) and dynamic (
UCSD's recovery Hopkinson) compression. Strains over 40% are achieved in th
ese tests over a temperature range of 77-1000 K and strain rates of 10(-3)-
8000/s. At the macroscopic level, the flow stress of CP-Ti, within the plas
tic deformation regime, is strongly dependent on the temperature and strain
rate, and displays complex variations with strain, strain rate, and temper
ature. In particular, there is a three-stage deformation pattern at a tempe
rature range from 296 to 800 K, the specific range depending on the strain
rate. In an effort to understand the underlying mechanisms, a number of int
errupted tests involving temperature jumps are performed, and the resulting
microstructures are characterized using an optical microscope. Based on th
e experimental results and simple estimates, it is concluded that the three
-stage pattern of deformation at temperatures from 296 to 800 K, is a resul
t of dynamic strain aging, through the directional diffusion of dislocation
-core point defects with the moving dislocation at high strain rates, altho
ugh the usual dynamic strain aging by point defects segregating outside the
dislocation core through volume diffusion is also observed at low strain r
ates and high temperatures. The microscopic analysis shows that there is su
bstantial deformation twinning which cannot be neglected in modeling the pl
astic how of CP-Ti. The density of twins increases markedly with increasing
strain rate, strain, and decreasing temperature. Twin intersections occur,
and become more pronounced at low temperatures or high strain rates. In su
m, the true stress-true strain curves of CP-Ti show two stages of deformati
on pattern at low temperatures, three stages at temperatures above 296 K, a
nd only one stage at temperatures exceeding 800 K, although all three stage
s may exist even at 1000 K for very high strain rates, e.g. 8000/s While th
e dislocation motion is still the main deformation mechanism for plastic fl
ow, the experimental results suggest that dynamic strain aging should be ta
ken into account, as well as the effect of deformation twinning. (C) 1999 A
cta Metallurgica Inc. Published by Elsevier Science Ltd. All rights reserve
d.