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Polarity of work-hardening
LETTERS
anelastic
loops.
The lower
the true lattice frictional
value
TO
is believed
THE
EDITOR
849
to be
stress, and the higher value,
the sum of lattice frictional
stress and the drag due to
jogs.
The extrapolated value for 7F at zero strain is ~0.8 kg/mm2, which is about 50 percent of the initial flow stress. The interrupted stress/strain curves of the crystals
show transient
effects
that are not
found in crystals pulled continuously. on reloading
the
ordered
crystal,
commences
in a discontinuous
propagation
of a new Liiders band;
is ~5
percent.
diffusion
controlled
responsible It
The evidence locking to
plastic
manner
flow
re-
and by the
the Liiders strain
points to some kind of mechanism
for the anomalous
is a pleasure
In particular,
reloading
as
being
FIG. 1
effect.
acknowledge
the
valuable
which a dislocation
came before it was stored.
assistance given by Mr. J. Zeiger, and the support of --
this is not an unreasonable
the Office if Naval Research.
incorporated
_
B. H. KEAR
Pratt & Whitney Aircraft
A result of special work-hardening be
References 1. B. H. KEAR, Acla Met. 12, 555 (1964). 2. A. H. COTTRELL,Dislocations and Plastic Flow of Crystals D. 111. Clarendon Press. Oxford (19531. 3. 3. M. ROBERTS and N. BROWN, ‘TY&. Met. Sot. AIME 218, 454 (1960). 4. P. R. STRUTT and B. H. KEAR (to be published). 5. J. C. FISHER, Acta Met. 2, 9 (19.54). 6. A. E. VIDOZ and L. M. BROWN, Phil. Mug. 7, 1167 (1962).
* Received Januctry 7, 1964.
repeatedly
hardening
progress
in each secondary
deformation
out of a previously these.
All experiments rate
previous
latent
slip system after plastic slices, at various angles,
compressed
cube, and then com-
The orientation
axis is kept constant, strain
the
of the compression
10” from
(110) towards
(211).
are done at room temperature,
of 2 % per minute.
observations
at a
As deduced
from
by different experimental
tech-
niques, (l) the flow stress in the new system is between 1.1 and 1.3 times the flow stress of the old system (1 kg/mm2).
The
slip systems
will be reported
results
have,
details
however,
for
work-hardening
later.
emerged
new light on the mechanism It was observed
all specific
secondary
Some
which
general
may
throw
of work-hardening.
that the flow stress and the initial
slope in the secondary
slip system
depend
on the direction
in which this secondary
system
is strained.
must
formation
is retained
a work-hardened
It
be
concluded
in the dislocation
specimen
about
slip
that
in-
structure
of
the direction
from
has
been
mechanism
is that the initial
system,
of secondary
tests
test is in the A direction,
hardening
slope is negative,
Since why
(but
Figure 1 shows the orientation
secondary
test (0) and (A, B):
if the
the initial work-
if it is in the B direction,
as usual.
behavior
may
be at the root
dependence
cross-slip
important
may
only
and only if
axis in the primary
in the two types
system
observed
so) in the cross-slip
strained in one sense.
orientation
by single slip into stage III of aluminum.
This is done by spark-cutting pressing
of
This
of the compression
This
in
significance
slope in the secondary
negative.
it is positive
Polarity of work-hardening* are
in any of the work-hardening
currently discussed.
North Haven, Connecticut
Determinations
While
result, it is a feature not
is
of the
of work-hardening
generally
strong
in stage III.
assumed
to
be
very
at these large strains, it has not been clear
orientations
with
zero
external
resolved
shear
stress on the cross-slip plane did not form an extreme of the band of stress-strain tions. ence
curves for various orienta-
The observed trend in the orientation is consistent
with
the
new
particular, the extremely low work-hardening crystals
follows
in a straightforward
the mutual work-softening slip systems.
In
of (100)
manner
of the primary
The question
depend-
observation.
from
and cross-
remains why one combi-
nation of signs of primary and cross-slip leads to mutual work-softening while the other leads to mutual hardening. U. F. KOCKS Division
of Engineering
and Applied Physics Harvard University Cambridge, Massachusetts Reference 1. U. F. KOCKS, Trans. Met. Sot. AIME, * Received January 22, 1964.
in press.
anelastic
loops.
The lower
the true lattice frictional
value
TO
is believed
THE
EDITOR
849
to be
stress, and the higher value,
the sum of lattice frictional
stress and the drag due to
jogs.
The extrapolated value for 7F at zero strain is ~0.8 kg/mm2, which is about 50 percent of the initial flow stress. The interrupted stress/strain curves of the crystals
show transient
effects
that are not
found in crystals pulled continuously. on reloading
the
ordered
crystal,
commences
in a discontinuous
propagation
of a new Liiders band;
is ~5
percent.
diffusion
controlled
responsible It
The evidence locking to
plastic
manner
flow
re-
and by the
the Liiders strain
points to some kind of mechanism
for the anomalous
is a pleasure
In particular,
reloading
as
being
FIG. 1
effect.
acknowledge
the
valuable
which a dislocation
came before it was stored.
assistance given by Mr. J. Zeiger, and the support of --
this is not an unreasonable
the Office if Naval Research.
incorporated
_
B. H. KEAR
Pratt & Whitney Aircraft
A result of special work-hardening be
References 1. B. H. KEAR, Acla Met. 12, 555 (1964). 2. A. H. COTTRELL,Dislocations and Plastic Flow of Crystals D. 111. Clarendon Press. Oxford (19531. 3. 3. M. ROBERTS and N. BROWN, ‘TY&. Met. Sot. AIME 218, 454 (1960). 4. P. R. STRUTT and B. H. KEAR (to be published). 5. J. C. FISHER, Acta Met. 2, 9 (19.54). 6. A. E. VIDOZ and L. M. BROWN, Phil. Mug. 7, 1167 (1962).
* Received Januctry 7, 1964.
repeatedly
hardening
progress
in each secondary
deformation
out of a previously these.
All experiments rate
previous
latent
slip system after plastic slices, at various angles,
compressed
cube, and then com-
The orientation
axis is kept constant, strain
the
of the compression
10” from
(110) towards
(211).
are done at room temperature,
of 2 % per minute.
observations
at a
As deduced
from
by different experimental
tech-
niques, (l) the flow stress in the new system is between 1.1 and 1.3 times the flow stress of the old system (1 kg/mm2).
The
slip systems
will be reported
results
have,
details
however,
for
work-hardening
later.
emerged
new light on the mechanism It was observed
all specific
secondary
Some
which
general
may
throw
of work-hardening.
that the flow stress and the initial
slope in the secondary
slip system
depend
on the direction
in which this secondary
system
is strained.
must
formation
is retained
a work-hardened
It
be
concluded
in the dislocation
specimen
about
slip
that
in-
structure
of
the direction
from
has
been
mechanism
is that the initial
system,
of secondary
tests
test is in the A direction,
hardening
slope is negative,
Since why
(but
Figure 1 shows the orientation
secondary
test (0) and (A, B):
if the
the initial work-
if it is in the B direction,
as usual.
behavior
may
be at the root
dependence
cross-slip
important
may
only
and only if
axis in the primary
in the two types
system
observed
so) in the cross-slip
strained in one sense.
orientation
by single slip into stage III of aluminum.
This is done by spark-cutting pressing
of
This
of the compression
This
in
significance
slope in the secondary
negative.
it is positive
Polarity of work-hardening* are
in any of the work-hardening
currently discussed.
North Haven, Connecticut
Determinations
While
result, it is a feature not
is
of the
of work-hardening
generally
strong
in stage III.
assumed
to
be
very
at these large strains, it has not been clear
orientations
with
zero
external
resolved
shear
stress on the cross-slip plane did not form an extreme of the band of stress-strain tions. ence
curves for various orienta-
The observed trend in the orientation is consistent
with
the
new
particular, the extremely low work-hardening crystals
follows
in a straightforward
the mutual work-softening slip systems.
In
of (100)
manner
of the primary
The question
depend-
observation.
from
and cross-
remains why one combi-
nation of signs of primary and cross-slip leads to mutual work-softening while the other leads to mutual hardening. U. F. KOCKS Division
of Engineering
and Applied Physics Harvard University Cambridge, Massachusetts Reference 1. U. F. KOCKS, Trans. Met. Sot. AIME, * Received January 22, 1964.
in press.