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The martensite transformation in steels with low stacking fault energy
THE
MARTENSITE LOW
TRANSFORMATION STACKING FAULT
IN STEELS ENERGY*
WITH
P. M. KELLY? The martensitic y to c( transformation in two high alloy steels with low stacking fault energy has been investigated using transmission electron microscopy. In a 12 y0 Mn-10 o/0Cr-4 o/oNi steel the cc-martensite formed as laths, which were always contained within { 11lJy bands of almost perfect hexagonal E. The long direction of these laths was parallel to (11O)r and the habit plane was close to a { 112}, plane, which was perpendicular to the a-bands. The orientation relationships between the three phases y, E and a were determined to within *2” using selected area electron diffraction and in suitable cases to within &p using Kikuchi line patterns. The transformation in a 17 % Cr-9 “/9Ni steel was also examined and found to be essentially similar to the transformation in the Mn-Cr-Ni steel. The Bowles-MacKenzie theory has been applied to this martensite transformation, assuming a (lll),[I2f], lattice invariant shear system, instead of the (11O)J 1101, system used to account for the more familiar transformation to internally twinned martensite, and the theoretical predictions were found to be in good agreement with the experimental results. LA
TRANSFORMATION MARTENSITIQUE ENERGIE DE FAUTE
DANS DES D’EMPILEMENT
ACIERS
A FAIBLE
A l’aide de la microscopic Blectronique par transmission l’auteur a Btudie la transformation martensitique y --f a dans deux aciers allies Q faible Bnergie de faute d’empilement. Dans l’acier a 12:/, Mn-10% Cr-4% Ni, la martensite a apparait sous forme de baguettes qui sont toujours contenues dans des bandes {l 1l}r de la phase 8 hexagonale quasi parfaite. Le grand axe de ces baguettes est parallele aux directions (1 lo), et le plan d’habitat est proche du plan {112},, lui-meme perpendiculaire aux bandes E. Les relations d’orientation entre les trois phases y, E, a ont Qte d&ermin&ss a & 2” en utilisant la diffraction Blectronique selective et dans oertains cas favorables a & p par interpretation des lignes de Kikuchi. La transformation martensitique d’un acier a 17y. Cr-9 y. Ni est similaire a celle de l’acier Mn-Cr-Ni. La theorie de Bowles-MacKenzie a Bti: appliquee & o$te transformation martensitique en faisant l’hypothese que le systeme de oisaillement est (lll)y[121], au lieu du systeme classique (llO),[liO], choisi pour interpreter la plupart des transformations prodmsant une martensite ma&e interieurement. Dans ces conditions, un bon accord est obtenu entre les previsions theoriques et les resultats experimentaux. DIE
MARTENSITUMWANDLUNG IN STAHLEN STAPELFEHLERENERGIE
MIT
NIEDRIGER
Mit Hilfe des Elektronenmikroskops wurde die Martensitumwandlung in zwei hochlegierten Stahlen mit niedriger Stapelfehlerenergie untersucht. In einem Stahl mit 12% Mn-10% Cr-4% Ni bildete sioh u-Martensit in Form von Nadeln, die stets in {lll}r-Blndern der fast idealen hexagonalen s-Phase enthalten waren. Die Langsrichtung dieser Nadeln war parallel zu (110)~ und die Habitusebene war nahe {112},, senkrecht zu den &-Bandren. Die Orientierungsbeziehungen zwischen den drei Phasen y, s und c( wurden mittels Elektronenbeugung in ausgewiihlten Gebieten auf f 2” genau bestimmt, sowie in Die Umwandlung in einem 17% Cr-9% geeigneten Fallen auf )” genau mittels Kikuchi-Linienmustern. Ni-Stahl wurde ebenfalls untersucht und erwies sich als iihnlich der Umwandlung in dem Mn-Cr-Ni-Stahl. Die Bowles-MacKenzie-Theorie wurde auf diese Martensitumwandlung angewandt unter der Annahme anstelle des zur Beschreibung der bekannteren eines gitterinvarianten (lll)y[121]y-Schubsystems, Umwandlung in innerlich verzwillingten Martensit benutzten (1 lO)r[liO],Systems. Die theoretische Vorhersagen und die experimentellen Resultate stimmten gut tiberein.
INTRODUCTION
an
In a number of highly alloyed steels, notably containing
appreciable
hexagonal
e-martensite
amounts is found
the b.c.c. a-martensite.‘l-g)
of
Cr or
in association
those Mn,
a
with
This type of a-martensite,
18-8
stainless
deformed
steel is quenched
at this temperature,
formed parallel to (1 lo),
to -196”C,
martensite
(i.e. (111 ),).
The dislocation
density in these needles was relatively was no sign of the internal
or
needles are
twinning
high, but there found
in high
which appears to form only in low stacking fault energy austenites, has been studied using X-ray diffraction on both optical and electron micros-
The needles often lay in sheets parallel to {ill}, (i.e. (lol},) and adjacent needles in the sheets were generally twin-related. No E was
c~py.(~-~~) Kelly and Nuttingos)
detected in this steel, but isolated stacking faults and fault bundles were observed. The orientation relationship between tc and y was determined using electron
reported that when
* Received September 11, 1964. t Department of Metallurgy, Yorkshire, England. ACTA METALLURGICA,
VOL.
Leeds University, 13, JUNE
1965
Leeds 2,
carbon
martensites.
diffraction 635
and within
the limited
accuracy
of this
ACTA
636
technique
appeared
jumov-Sachs
to be consistent
relationship.
was formed
E and b.c.c.
by stacking
with the Kurd-
After
similar steel in tension at -196’C, both hexagonal
METALLURGICA,
deforming
a
Venables(5) found
u. The hexagonal
faults over-lapping
phase
to form
sheets of more or less perfect E. The u-martensite always associated
was
with one or more of these c-sheets
and the intersection
of two such sheets on different
{ 11 l}? planes was a favoured tc. The orientation
site for the nucleation
relationships
between
of
the three
13,
consequence
1965
of the shears involved
found
that in an Fe-15.1 y0 Cr-11.7%
one transformation
temperature
three different techniques.
which
for
the
ii woi, and
a
relationship.
The
cooling.
y is the
In
same
y
to
E
steels
the
with
studied two and after
a-martensite In
one steel
in
(llO),
the martensite
directions
although
their
evidence
relationship
techniques,
and
plates
single
were elongated
surface
trace
analysis
was
using X-ray
a to y relationship
was
to the {ill},
that
but single some
of
the
a-martensite
pl ane of the band.
Lagenborgu’)
{ill),
bands,
rather
than
to
the
related
e-phase in the austenite,
and
proposed a nucleation mechanism for the a-martensite in terms
showed
planes inclined at 60”
this {225}, habit plane to the hexagonal
partials.
to {ill},,
appeared
The {225}, martensite showed
of slip on two {llO},
associated
with sheets parallel
with the (11 l}, plane of the band.
in the other steel, however,
to each other, one of these (1 lo}, planes being parallel
about 4” away from the exact Kurdjumov-Sachs relationship. The u-martensite in this case was again analysis
both
to have a {259}, habit.
Kurdjumov-Sachs
by Breedis and Robertson@)
trace
Lagneborg@‘)
formed on cooling lay in bands parallel to (11 l}y.
The martensite
IIWI,
determined
surface
Ni alloy only
was detected
18-8 stainless steels both after deformation sub-zero
a large angle (ri85”)
Wl), II(OOOl), IIW), m,
in forming a. This
proposal was later supported by Goldman et ~2.o~) who
showed that the habit plane was a {225}, plane making
:
phases were found to be
VOL.
of the atomic
configuration
at Shockley
The aim of the present investigation
was to deter-
plates could have a habit plane near to (2251,. Reed t7) showed that in 18-8 stainless steels the a-martensite was in the form of plates and not
two steels of low stacking fault energy and in partic-
needles,
as suggested
ular to establish
number
of
these
directions
and
by Kelly
plates
single
were
surface
and Nutting.(lO) elongated trace
consistent with a {225}, habit plane. were elongated
in a direction,
12” from (llo),,
by
analysis
was
Half of the plates
and the habit planes of these plates
a-martensite
bounded
A
(110),
which deviate by up to
were found not to be consistent The
in
plates
{ill},
with a (2251, habit.
always
planes
and
appeared the
in sheets
direction
of
elongation
was always parallel to or close to a (1 lo),
direction,
which
lay in the bounding
{ill},
plane.
mine, as accurately orientation
relationships
determined
Other features, such as the relationship E, the substructure the morphology experimental
an a-martensite plane (ill), would have
results
habit
plane.
Dash
Thus, by the
using transmission
in sheets of faulted
hexagonal
E.
They
disagreed, however, with the suggestion, made by several previous workers, that E nucleates u and instead
proposed
that
the
formation
of
E
was
a
laths and The
in terms
of the
of martensite
trans-
invariant
shear on (11 l)?
WI,. The variant relationship
of the Kurdjumov-Sachs
used by Bowles
orientation
and MacKenzie;05)
ii m,
electron microscopy to study the martensite in 18-12 stainless steel, confirmed a number of the results of earlier investigations and showed that the a-martensite is contained
theory
using a lattice
mi,
in the direction [liO],, plane and not a (225),
and Otte,(s)
are analysed
habit plane
plate lying in a sheet bounded
and elongated a (225), habit
within the a-martensite
IIWL
with the plane of the (11 l}? sheet.
relationship. between a and
of these laths, were also studied.
Bowles-Mackenzie(13-15) formations
laths in
the habit plane, which is associated
(ill),
was always the (225}, plane which made the greatest angle (~85”)
of the a-martensite
(1 lo),
with a particular
the habit plane and
with a specific variant of the orientation
Reed pointed out that, although there are two planes of the type {225}, associated direction, the experimentally
as possible,
i.e.
is taken as the standard variant in the present paper and whenever particular, as opposed to general, indices of planes and directions text
they
are mentioned
refer to this variant.
Jawson-Wheeler(16)
correspondence
The
in the
appropriate
matrices are given
in Table 3. EXPERIMENTAL
The compositions
METHODS
of the two steels investigated
given in Table 1. The steels were rolled into strips 200-300 annealed
are
,U thick,
at 1000°C in argon for one hour and then Partial transformation to quenched into water.
KELLY:
MARTENSITE
TRANSFORMATION
637
FIG. 1. Mn-Cr-Ni steel quenched to -196°C showing a number of large c-bands
(B) containing a-martensite laths. The positions of these laths are indicated by the large arrows and the projected width of the cc-martensitehabit plane interface is visible at A. x 12,000 TABLE 1. Composition Main alloying elements
Cast number
of the steels used
Compo~~;t. Cr
C
-
%) Yi
a-matrensite
17.2
0.04
9.0
-
-
x
and quenched by chemically
samples to - 196°C. electron
polishing
Thin foils suitable
microscopy
min in a 10: 1 acetic:perchloric finally electro-thinning The orientation
relationships
line pattern@) trace analysis
&2’)
for 1 to 2
solution
and
electrolyte,
or the Bollmann
dc, y and E were determined (accuracy
acid
in a chromic-acetic
using either the “window”
between
technique. the phases
using electron diffraction
and where possible Kikuchi
(accuracy
*_t”).
As single surface
does not give a unique
result for the
procedure mal.
(which
gives
to those of a two surface analysis)
was adopted to determine the habit plane of the x-martensite laths. From the traces and projected widths of the numerous stacking faults on (1 ll}, in the austenite, a value of the foil thickness in the area of interest was obtained.
it was found that only one solution was the
same in all cases. EXPERIMENTAL
Mn-Cr-Ni this
Using this value of the foil
thickness and the projected width of the a-martensite habit plane interface (see for example Fig. 1) the angle
RESULTS
steel. The most characteristic
steel,
after
quenching
presence of numerous
to
feature of
--196”C,
bands on {ill},
was
that these bands were hexagonal not
perfect
faults,
and
although
sufficient
to lead
displacement
contained the
to any
of
of
e-bands
and
stacking
faulting
appreciable
was
streaking
of the hexagonal reflections.
to these broad c-bands,
showed
E. The bands were
a number
degree
the
planes in the
austenite (see Fig. 1). Selected area diffraction
formed
procedure
gave two solutions for the habit plane nor-
however,
microscope,
following
trace
Once a number of habit planes had been analysed
narrow
the
by single surface
Since the sense of the tilt of the
habit plane with respect to the foil was not known, this
habit plane of a planar feature and true two surface analysis is not possible with a thin foil in the electron results equivalent
circle determined
analysis was found.
were prepared
the strips down to 50 p in a
mixed acid solution,(17) then electropolishing
patterns
0.010
was achieved by cooling the austenitised
for transmission
In this way the position of the habit plane normal on the great
RM 3827 Mn-Cr-Ni 0.028 10.50 4.10 12.15 0.37 0.016 RM 3897 Cr-Ni
between the habit plane and the foil was calculated.
not or
In addition
a number of fault bundles or single
austenite were observed.
stacking
faults
The a-martensite
in the
laths were
within these E-bands (see Figs. 1 and 2) and
were limited
in size by the width of the bands.
No
cr-martensite laths, which were not associated with these e-bands were ever observed. The cc-martensite showed no evidence of internal twinning and contained very few dislocations. The electron diffraction containing reflections
patterns from the e-bands
a-martensite were complicated, since from all three phases--y, F and a-were
ACTA
638
METALLURGICA,
VOL.
13,
1965
FIG. 2. (a) Bright field micrograph of the Mn-Cr-Ni steel quenched to - 196°C. The E appears as dark bands running approximately horizontally and the cr.martensitelaths are contained within these bands. Retained au&mite between the E-bands is shown at A. x 22,000 (b) Dark field micrograph of the same area taken with a {loil}, reflection. The s-bands now appear light while both the cr.martensite and the austenite are dark. x 17.600
generally
present.
technique
of selecting a diffracted beam as an imaging
By
using the simple
beam, it was possible to determine
dark
which phase gave
rise to a particular
spot on the composite
(see Figs.
2(b)).
2(a)
produced
and
adjacent these
In addition,
by the double diffraction
was diffracted
pattern
reflections
and then in the
second phase could be distinguished. electron
orientation
relationship
determined
to within 12’.
were consistent
diffraction
From
patterns
the
between the three phases was All the patterns analysed
with the relationships
:
although
relationship
0.4”
from
(ill),
[lli],
0.5”
from
[iTo],
Unfortunately
would not
Despite
which
could
to be the plane, e-band.
which
addition,
The degree of
identify
the
particular
relationship
In two cases Kikuchi phases were obtained
was not obeyed in this
line patterns and from
of two of the
these patterns
the
Kikuchi
of the orientstion electron Kikuchi
was in every case found
was faulted
of u-martensite
approximately
diffraction lines, much
from these patterns.
This was true even when In
the Nishiyama steel.
i
plane, which is approximately
parallel to (OOOl), and (lOl),
e-band.
was, however, always sufficient to show that
show
be obtained
orientation
accuracy
from
did not
of
relationship.
and (OOl),
satisfactory
accuracy
determined
could not be distinguished the Greninger-Troiano
with
the limited
have been outside the range of accuracy. In these cases the Kurdjumov-Sachs orientation relationship from the same variant
i (ill),
lying between
pattern from all three phases in the same area.
For example the {ill},
of up to two or
(lOl),
patterns
another
austenite:
lines were rare and it was not possible to get such a
information
three degrees from these exact relationships
between
lath and the adjacent
(lOl),
patterns
IIU~101, II[lm,
in some cases deviations
orientation
u-martensite
relationships
(1111, II(OOOl),IIW), WI,
while the second set of Kikuchi line patterns gave the following
of a beam, which
first in one phase
composite
field
it
to produce
the
more
one
was present was
(llO),
always direction
parallel to a (11 l),
more that one a-martensite
than
in a single possible that
direction.
lath was observed
to was
When in a
single E-band their orientations were either the same or represented two of the six Kurdjumov-Sachs variants associated with the (11 l)y plane of the band (see Fig. 6).
orientation relationships were determined to an accuracy of **O. One set of Kikuchi line patterns
In the latter case the two variants distinguished.
‘came from an u-martensite lath and the surrounding e-band and gave the following orientation relationship :
The cc-martensite within the e-bands was in the form of laths, so possessing both a long direction, which is usually associated with a rod or needle-like
(lOI),
0.9”
from
(OOOl),
[lli],
1.0”
from
[1210],
structure, of a plate.
could always be
and a habit plane, which is characteristic The long direction
of the lath always lay
KELLY:
MARTENSITE
639
TRANSFORMATION
cases where no satisfactory
diffraction
patterns were
obtained from the cr-martensite, the habit plane could not of course be related to a particular
variant of the
However, orientation relationship. results indicated that an u-martensite with an e-band on say (III), relationship
as
the
other
lath associated
must have an orientation
which is one of the six variants associated
with the plane of the band (i.e. one of the six variants shown
in Fig.
relative
6), the position
of the habit
plane
to the plane of the band could be inferred.
In all these cases the habit plane was found
to be
close to a {112}, plane, which was perpendicular
to the
(11 l)y plane of the band. FIG. 3. Stereographic projection showing the poles of the habit plane normals of a-martensite laths in the Mn_cr-Ni steel. All the laths analysed were in the standard variant of the orientation relationship i.e. (ill),
II(OOOl)EII(1Ol)a
Although
the greater part of the work steel some observa-
tions were also made on a Cr-Ni steel to compare the transformation
behaviour in a material that is thought
to have a higher stacking fault energy.
[iioly 11 pie], 11liiild
crystallographic
and were contained within E-bands parallel to (11 l),.
The maximum scatter in the results is about four times greater than the experimental error. The variation of habit plane with Ba for a (1 ll), [121]~ lattice invariant shear is shown as a dotted line. in the E-bands and could
Cr-iVi steel.
was carried out on the Mn-Cr-Ni
be considered
as the inter-
Cr-Ni
In general the
features of the transformation
steel and confirmed stainless steels. in which
the
previous
observations
There was however Cr-Ni
martensite
cr-martensite in the Mn-Cr-Ni
differed
were very imperfect and should probably as irregular
direction
reflections
fault
in the electron
results on martensite in Cr-Ni steels. Since a particular
not as common
variant
observed
of
the
distinguished
orientation
whenever
relationship
satisfactory
could
diffraction
terns from the u and y or E were obtained, direction
be pat-
the long
of the lath could be related to this variant.
bundles
reflections, disorder.
again
diffraction
they were streaked
the stacking always
the
be described
(see Fig. 4).
as in the Mn-Cr-Ni
the austenite
from
steel. First, the e-bands
Single surface
that this long with previous
on 18-8
several respects
section of the habit plane with the plane of the band. trace analysis showed was (1 lo), in agreement
in the
steel were similar to those of the Mn-Cr-Ni
Hexagonal
patterns
were
steel and when
and displaced
towards
as would be expected
from
The cr-matrensite laths were
associated
with
these imperfect
e or
In every case analysed the (1 lo), long direction proved
fault bundles, but in some cases the width of the lath
to be the same (llO),
was greater than the width of its fault bundle
direction
mately parallel to (111 ),-i.e. used
in the present
which was approxi-
in terms of the variant
paper
the long
always [ilo],. The habit plane of the martensite mined
to
described those
within
about
above.
where the habit
martensite
lath
52”
The most
direction
4).
number with
laths was deter-
using
the procedure
significant
results were
plane was determined
of known
was
Fig.
orientation
for a
relationship.
The of
fault
cr-martensite
previous
twin-related. twinning
work,
but
the
agreement
The
results
of
shown in Fig. 3.
fourteen
orientation such
relationship.
determinations
For the variant
are
of the orientation
relationship used in the present paper, the habit plane was always found to be near to (ii2),. These results are in agreement with those of Reed(‘) and Lagneborg’s) to the extent that the habit plane makes an angle of approximately
90” to the (ill),
plane of the e-band,
but differ from them in that the habit plane results are significantly closer to (112), than to (‘225),. In the
and,
adjacent
a
in agreement
laths
were
often
dislocation
density
within
the
higher
The results of the present analysis of the cr-marten-
particular
the
laths,
(see
contained
u-martensite was on the whole considerably than in the Mn-Cr-Ni martensite. site in the Mn-Cr-Ni
of
generally
Again there was no evidence of internal
In these cases the habit plane could be related to a variant
bundles
steels.
with
and the Cr-Ni steels are in good
previous
The results
work
on
18-8
on the transformation
steels, whose common
feature appears to be that the
austenite has a low stacking summarised as follows :
(1) The a-martensite
stainless in these
fault
energy,
is not internally
can be
twinned
and
the only form of internal substructure is dislocations. The dislocation density is not the same in the two steels and in some cases regular arrangements of dislocations are observed.
640
ACTA
METALLURGICA,
VOL.
13,
1965
FIG. 4. Cr-Hi steel quenched to -196°C showing three E-bands containing cc-martensitelaths. The orientation is such that the long direction of the laths is perpendicular to the foil. The z-bands are very imperfect, particularly at A. Note the high dislocation density in the rx-martensiteand that the twinrelated laths at B are somewhat wider than their associated E-bands. X 28,000.
The u-martens&e is always associated with bands of hexagonal E or faulted sustenite and the width of the lath is restricted to a considerable extent by the width of the band. (3)The orientation relationships between the three phases is spproximately :
(1111, II(OOO~L IIW),
(4)The habit plane of the a-martensite laths is near to a (112) plane which is perpendicular to the {Ill), plane of the faulted bundle or e-band. For the variant of the orient&tion relationship given above the habit plane is (1124. (5)The long direction of the a-martensite laths is [liO], in terms of the standard variant of the orientation relationship. (6)When more than one m&r~nsite lath is formed in a given band, adjacent laths are often twin Twin-related laths have identical related. habit planes and the same long direction. (7)In it given s-band, six variants of the orientation relationship are possible. These consist of three twin-pairs. In terms of the standard variant (112),. (121), and (2ii),, are the habit planes for the three pairs of twin-related laths in a (11 l)y band, while the relevant long directions are [ITO],, [iOl], and [Oli], respectively.
DISCUSSION
When the features of the martensite tr&nsform&tion in Mn-Cr-Ni and Cr-Ni steels are compared with those of the more familiar transformation in Fe-C, Fe-Cr-C, Fe-Ni, and Fe-Ni-C, which generally leads to internally twinned plates, certain fundamental differences, which distinguish this u-martensite from the inte~ally twinned variety, become apparent . The absence of internal twinning is not unduly significant, since the complementary strain could be accommodated by slip as well as by twinning, and portions of such martensite plates, which are free of twins, have been observed. The association with E or faulted y is a more ~h~r~~teristi~ distinguishing feature, while the most important difference between the cc-martensite in these Mn-Cr-Ni and Cr-Ni steels and internally twinned martensite is the habit plane. Admittedly the habit plane is close to a plane of the type (225), and the Bowles-MacKenzie theory of the m~rtensite transformation, as applied to internally twinned martensite,06) predicts a (225), habit at maximum dilatation. In terms of the variant of the orientation relationship used in the present paper, however, the internally twinned martensite should have s (2251, habit, while for the same variftnt of the orientation relationship the a-martensite laths in the Mn-Cr-Ni steel have it (ifa), habit plane, which is a few degrees from (2%5), not (225), (see Fig. 3). Hence, although the Bowles-MacKenzie theory, when applied to the y to OLtransformation with a lattice invariant
KELLY: TABLE
2.
MARTENSITE
Values of the magnitude of the lattice invariant shear 9 and the shear component of the shape strains for the three (11 l}Y( 112)Y lattice invariant shear systems?)
Case no.
Lattice invariant shear svstem in anntenite
1
(111),[121lY
(lol),[roll,
2
(111M1121,
(101),[13i1,
3
(111):~[2rr],
(101),[1371,
* Negative
shear on (llO), martensite, Cr-Ni
Magnitude of lattice invariant shear o(at S = 1.000)
Corresponding shear svstem in mnrtensite
(a) (b) (a) (b)
Magnitude of the shape strain s(at zi = 1.000)
+0.284 +0.423 -0.279* +1.548
0.219 0.219 0.398 1.861
Crystallographically
equivalent
to Case 2 above
values for 9 indicate that the shear is in the opposite direction to that given in the table.
[liO],,
is very successful in accounting
of the lattice invariant. shear g and the shear compo-
features of internally twinned
nent of the shape strains in f.c.c. to b.c.c. transforma-
for the crystallographic features
641
TRANSFORMATION
it is not
of
the
steels.
consistent
with
transformation
The success
the observed
in Mn-Cr-Ni
and
show internally
twinned
(225), or (259), plates, leads to the conclusion
that any
alterations
steels, which
required
to account
these (11 l}y (112), shear systems have
been calculated
by Wechsler et &(20)
These values of
g and s are shown in Table 2.
of the phenomenological
theories in dealing with the martensite transformation in the other
tions involving
for (112), martensite
Although
there
is very
little
difference
in the
smaller values of g for the two distinct cases 1 and 2, the values of the shape strain s differ considerably. The lattice invariant
shear system
(111),[121],
gives
laths should not be made to the theories themselves,
the smallest, value of s and hence on the grounds
but to one of the assumptions
minimum
theories to this particular The current
(a) the
transformation
product
of
are based on
between
the parent, and
parameters
of
the
two
phases,
shear system.
can only be altered slightly,
whether this alteration is acheived directly by alloying or indirectly
invariant
by the introduction
of a small uniform
as is done in the Bowles-MacKenzie
theory.
In any event a small change in these parameters
will
can
be
produced
by
System I: and System II:
only
that the (11 l}y (112),
stacking
fault shear
might be an appropriate
invariant shear system for the transformation steels.
In terms of the standard variant,
mental results show that the faulted
lattice in these
the experi-
plane is (ill),
and so the three shear systems involving a (112), dire&ion lying in (11 l)? must be considered. One of these
systems,
[iOl],
in the martensite
(ill),
[121],
corresponds
to
(lOl),
while the other two, (ill),
namely:
(112),[11T],
(111),[121],
i.e.
(lOl),[iOl],
Since no other shear system gives a lower value s, then, if the criterion of minimum ing the transformation shear system, should
strain energy accompany-
governs
martensite transformation.
system in austenite
systems, i.e.
shear system as the only alternative.
suggests
two
(llO),[liO],
lattice invariant
E or faulted y
plane or
shows that the smallest possible value of s
systems
steels the association
system in either
of two such systems with either a common
This leaves the choice of a different
and hexagonal
survey(21)
or to a simple shear composed
(259), to (112),.
and Cr-Ni
of
lattice
to either a simple
slip or twinning
invariant
between the u-martensite
likely
in the y to u marten-
is restricted
not shift the habit plane from the region of (225), and
In the Mn-Cr-Ni
more
A more extensive
shear system involved
shear on a normal
suggests that this cannot be altered.
The lattice parameters
dilatation,
shear system.
direction,
The first of these is well established and the agreement
is the
of the values of g and s, which result when the lattice
austenite or martensite
(c) the lattice invariant with experiment
energy
site transformation
phases,
lattice
strain
invariant
theories,(l3JV9)
input data :
correspondence
(b) the
the
transformation.
phenomenological
the au&en&e-martensite the following
used in applying
operate
in any
martensite
application
y to
M.
shear system used in
of theories to the familiar
transformation
and Fe-Ni-C
of these two
particular
The first of these systems
is of course the lattice invariant the successful
the choice of lattice
one or other
in Fe-C
Fe-Cr-C,
Fe-Ni
and System II will now be used as the
lattice invariant shear system in applying the BowlesMacKenzie
theory to the transformation
and Cr-Ni steels.
The notation
will be used in this application in Table 3. Figure 5 is a stereogram variation
of the habit
plane
in Mn-Cr-Ni
and input data which of the theory are given
showing with
the calculated 6J2 obtained
by
[112], and (ll!), [211],, correspond to (IOl), 11311, and (101), [131], respectively and so are crystallo-
applying the Bowles-MacKenzie theory to the transformation with a lattice invariant shear on (111 )Y
graphically
[121],.
equivalent
to each other.
The magnitude
For comparison
the variation
of habit plane
ACTA
642
METALLURGICA,
TABLE 3. Notation and input data used in the application of Bowles-MacKenzie theory Jaswon-Wheeler
correspondence matrices for the chosen standard variant : to a (directions)
VOL.
13,
1965
habit plane is exactly solutions
(112), and the two habit plane
reduce to one, since gi = g,.
of the habit plane normal
ship
P,
for the
formation
more
with a (llO),
familiar [liO],
case of the trans-
lattice invariant
is also plotted on the same stereogram.
shear,
the Kurdjumov-Sachs
relation-
: (ill), IIWL ml,
II[1lQ,
which is only 8” away from the orientation ship determined
from
Kikuchi
be the plane
(ill),
and so this must be the plane
which is faulted to produce predicted
relation-
line patterns.
The shear has been taken to
plane of the lattice invariant
The with
at 8 = 6 is in very good
agreement with the experimental results (compare Fig. 3 and Fig. 5). The orientation relationship at this value of O2 is exactly
Lattice invariant shear system: (lllh, [1211y c’]a’ = tetragonality of martensite = 1 (cubic martensite) C&= lattice parameter of austenite = 3.58 A a’ = lattice parameter of martensite = 2.87 A 6 = the dilatation parameter, which represents a small isotropic volume change. 19= 6(a’/a) (the maximum value of 19~for cubic martensite is 8). 8 = the shear component of the shape strain. g = the magnitude of the lattice invariant shear. In general there are two values of g. These will be represented as g, and g2 where g1 is less than g,.
The position
(ii2),
the band of hexagonal
habit
plane
is exactly
E.
per-
pendicular to this band, in agreement with the experimental results. As
The direction
e2 varies
calculated
the
curve
habit
either
plane
moves
towards
along
(ill),
for
the small
which is perpendicular to the shear plane [iOl],, normal (ill), and the shear direction [121],, is an axis
values of the lattice invariant shear g or towards (OOl),
of two fold symmetry
for large values of g. The variation of the orientation relationship with e2 is closely similar to the variation
unique
or contraction
tortion
[OIO],.
lattice
invariant
‘K-degenerate’(22) solutions
and is also perpendicular
to the
axis of the pure lattice
dis-
The
case of transformation with a _shear on (111),[121] is therefore and
is reduced
sponding to eachvalue
the number
from ofg.
four
of habit
to two,
one
with e2 when the lattice invariant [liO],.
shear is on (llO),
For example when 19~= 0.643 (6 = 1.000) the
plane
habit plane for g, (the smaller of the two values of g)
corre-
is near (334), and the orientation
At e2 = $(6 = 1.018) the
to the Greninger-Troiano
relationship
relationship.
is close
The values
of the shape strain s vary with e2 in exactly the same way as they do when the lattice invariant (llO,)[liO],.
At e2 = # the magnitude
strain
is 0.212
and
[-0.81,
0.47,
0.351,.
equivalent
its direction This
is approximately
shape
strain
is in fact
to a shear of 0.192 in the direction
plus an expansion
because
the
steel was associated give hexagonal tion between
[ilO],
of 0.089 normal to the habit plane
(112),. The lattice invariant chosen
shear is on
of the shape
shear system (1 ll),
cr-martensite
-[121], was
in the Mn-Cr-Ni
with faulting of the austenite to
8. In pursuing this apparent cc-martensite and faulting
connec-
of E forma-
tion great care must be exercised, since it is important to
distinguish
between
the
complementary
direction and the lattice invariant also between (loo)r
FIG. 5. Stereographic projection showing the theoretical variation of the habit plane with tP for the standard variant of the orientation relationship and a lattice invariant shear on (111)~ [121]r. The projection is plotted in the standard (001)~ orientation for austenite and the positions of the {lOO}a poles of the a-marten&e are indicated. For comparison, the habit plane variation with Befor the more familiar case of a (110)~ [ liO!y lattice invariant shear is shown as a dotted line.
opposite.
a stacking
shear
shear direction and
fault shear direction
and its
Stacking faults are formed in austenite by
displacing a {ill}, plane by 6(121), in relation to an adjacent {ill}, plane. If faulting occurs on every other {ill}, plane then hexagonal close packed E will be formed. If the E formation is homogeneous, the magnitude plane [lgl],,
of the shear involved
(ill), the possible [211], and [112],.
in 195’.
In the
faulting directions are The opposite direction
KELLY:
[T2T],,
[2ii],
directions
and
[ii2],
are not
since the displacement
over another in these directions
MARTENSITE
possible
643
TRANSFORMATION
forms within the band.
faulting
of one (11 l)? layer results in the atoms
In effect this means that, if
the E forms inhomogeneously,
as appears
to be the
case, then the e-band really represents a region of y
on adjacent layers being “pushed against one another”.
which has been subjected
The complementary
trans-
and the lattice
shear,
invariant plane strain (plus a slight “shuffle”
formation since
is the inverse of the lattice invariant
the
complementary
homogeneous lattice
strain
is regarded
as a
strain which distorts the lattice, and the
invariant
which
strain in the martensite
exactly
shear
cancels
is an inhomogeneous any shape displacement
that
It
is
therefore
important
to
of the complementary
invariant
shear direction
know
strain.
whether
is along a possible
direction in the transformation
faulting
being considered.
analysis is in fact based on the complementary being in a faulting
the
strain or the lattice
direction,
The strain
(OOOl),
planes)
Only
would
The
only
difference
interpretations
as an effect produced second case tively
This is
of atoms
therefore E to
these
by the formation
be
a.
two
possible
of c( and in the
is the cause of u formation.
E
the difference
time sequence, possibility
between
one further
is that in the first case the E is regarded
can be expressed
i.e. which
Alterna-
in terms of a
comes first u or
has its supporters.
Each
E.
Dash and Otte@) and
Goldman et a1.(12)take the view that E is a consequence and not a cause of tc formation
i.e. the complementary
strain is in the sense (1211, and not [121],.
adjacent
shears.
necessary to convert a portion of this
shear
would have been caused by the complementary direction
on
to both the complementary
invariant
and others+‘)
while Lagneborg@)
support the view that E forms before u.
borne out by the positive values of g when the lattice
There is no evidence in the present work to distinguish
invariant shear is chosen to be in the sense [121],.
between
leads to two possible interpretations between
cc-martensite
hexagonal
or E formation other
and
words
complementary
u-martensite
of M formation. forms
first and
of faulting.
complementary
into the austenite in the
If the value
(i.e. the a-martensite
of 02 is exactly
that, since the complementary
to the surroundThis implies
shear leading to E
then there is no need for the compensating
invariant
crystallographic
shear. theories
If this were so, then of
martensite
is inhomogeneous. formation would
the
formation
invariant plane.
have
an
If, on the other hand, the a-marten-
site and the surrounding
austenite
are subjected
to
applied.
possibility
macroscopic tion
between
distortion. a-bands
and would not lead to any
or faulting
it is unlikely that the
that of
in every case.
E
lath was formed
it is
laths could now form in
form
can form
form as a consequence
interpretation
the second
and cc-martensite would e-bands.
Irrespective
of the association
is correct, the theoretical
of
between
tc
analysis predicts that
at e2 = f the following relationships E
c-band
of u formation,
in the transformation
in these pre-existing E
in a given
even in a material where the
would be obeyed
between X, y and
should be observed: (ill),
II (OOOl), II (lOl),
PW, IIPm,
The austenite would still be faulted too, the
would be inhomogeneous
E
at a later stage
theories could still be
only difference being that in this case the e-formation
laths
Therefore,
first bands of
both the complementary strain and the lattice invariant shear the total strain would not be homogeneous and the crystallographic
of the lead to
if the first possibility
More u-martensite
of u-martensite
and
not
an e-band,
is
this c-band and it is well established that large numbers
homogeneous
would
the E formation
if an u-martensite
produce
correct.
both possibilities
In addition
of CI can precede
For example
which
as a result
of u is concerned,
the same results provided
would not longer apply as the total strain would be and
The controversy
one as it appears at
first sight, and as far as the crystallography formation
(see Fig. 4).
shear is accommodated
by the austenite as a homogeneous lattice
$
has a (112), habit) and all of the
strain is transmitted
ing y, a band of E should be produced.
formation,
In the
strain, instead of being confined to the
cr-martensite, is transmitted form
or
is that the faulting
is a consequence the
austenite
these two possibilities.
not, however, such a fundamental
of the association
faulted
The first possibility
E.
This
The
association
hexagonal
E
between
II[IlU, the
cc-martensite
and
may have an effect on the position of the
Examination
of the interac-
martensite
and
scratches
experimental results, the habit planes in the Mn-Cr-Ni steel cluster round (112), and not round the (22~5)~
surface
and
between e-bands on different planes shows that the F formation is apparently inhomogeneous. The second possible explanation of the association between ct-martensite and E or faulted austenite is that the e-band forms first and the cc-martensite then
habit
plane.
Despite
the scatter
in the
habit determined by Reed(‘) and by Lagneborg,t9) who both used single surface trace analysis. More important,
the experimental
habit plane results lie some
15” from the habit plane predicted
for zero dilatation
ACTA
644
(02 = 0.643, 6 =
between
1965
the theoretical
(e2 = Q, 6 = 1.018).
interest to note that the maximum is also required
of this 1.8% dilatation
It is of
value of the dilata-
to produce
habit found in plain carbon steels. the Mr-Cr-Ni
13,
habit planes occurs at the maximum
value of the dilatation tion parameter
VOL.
1.000). Consequently in the Mn-Cr-
Ni steel the best agreement and experimental
METALLURGICA,
the (225),
The introduction
to explain the
(ii2), habit in
steel seems to be supported
by the fact
that at this value of ti2 the complementary
shear is
exactly that required to produce E from y and at some other value of e2 the complementary give rise to perfect for example,
E. When
the complementary
strain should result
in imperfect E containing approximately ten
(OOOl), planes.
perfect
the
stable
to expect
than imperfect
E, the
at S = 1.018 (e2 = $), which
be associated to
one fault every
As it is reasonable
E to be more
transformation
shear will not
6 = 1.000 (e2 = 0.643)
would
with perfect E, may occur in preference
transformation
at
which would be associated
6 = 1.000
Pm. 6. Stereoeraohic oroiection showine the theoretical variation of the habit *plaAe with Oafor?he six variants of the orientation relationship that have (111 by 11(101)~. The lattice invariant shear is on (111)~ in every case and the uositions of the C-axis of the cc-martensitefor each variant are shown bv the black souare8. The variants with the same subscript (e.g. XI a;d Ys) comprise a twinrelated Kurdjumov-Sachs pair when Be = #. YB is the standard variant used in the paper.
(es = 0.643),
with imperfect
E.
In addition to the effect on the position of the habit plane,
the
association
hexagonal site
between
E also determines
grains.
This
type
u-martensite
of
cr-martensite
has
described by previous workers both as needlea plates.’ the
and
the shape of the martenbeen and as
Neither of these terms give a true picture of
shape
described
of
the
martensite,
as a lath.
morphology
which
The reason
can
best
be
for this lath-like
is that the growth of the martensite is to a
large extent
restricted
by the width
The habit plane of the martensite the band and growth
is perpendicular
to
along the normal to the band
would require further faulting of the band.
of the E-band.
to increase the width
This restriction does not apply to growth
in the direction
[lie],, which lies in the plane of
line.
These six habit lines are in fact three pairs, each
pair touching at a pole of the type {112}, when e2 = Q. The
two
orientation
Sachs variants. comprise
corresponding touch habit so
habit
at (112)
that
two
lattice invariant orientation plane.
shear.
relationship
There are six variants of the associated with a given
The position of the martensite
six variants in each case.
j] [lOl),
The standard variant considered
when
e2 = #.
to X,
workers.@@))
(lgi),.
pair
these
two
This
These
therefore and
the
variants
common
(112)
in the martensite,
laths
with
would
related laths with their common plane
twin
to (12i),
and Y,
Kurdjumov-
and Y,
orientations
appear as twin-
habit plane being the
twin-related
laths
have
in the present work and by previous The shape strain for the lath in orienta-
tion Y, can be regarded as a shear on the habit plane (ii2) in the direction [ilO], plus an expansion
(11l)y normal to the habit, while for the lath in the X,
c axis for these
is shown in Fig. 6 where (ill),
8,
for
a-martensite
corresponding
been observed using a (111),[121],
lines
plane is parallel
plane. point emerges from the theoret-
The variants
a Kurdjumov-Sachs
twin
Another important
at this common
point of each pair consist of twin-related
the band and, as a result, the u-martensite forms as a lath with a [liO], long direction and a (112), habit
ical analysis of this transformation
relationships
so far
orientation
the shear component
is in the direction therefore
[liO],.
of the shape strain
These twin-related
have shear components
laths will
of their respective
has been that denoted by Y, in Fig. 6, where the lattice invariant shear direction was taken to be [i2i],. By selecting the appropriate (112), direction lying in (ill), for each variant of the six orientation
shape strains that are exactly opposite. This should lead to a pair of these twin-related laths forming next
relationships
theoretical
associated
with
(ill),,
the
six habit
plane lines shown in Fig. 6 are obtained. The variant corresponding to each habit line is marked next to the
to one another, so that the shear components of their shape strains could cancel each other. Finally the analysis
predicts
that three such sets of
twin related laths with habit planes (ii2),, (2iijy and (121)could occur in a given (ill), sheet of faulted y
KELLY:
of hexagonal
MARTENSITE
TRANSFORMATION
E. Cases of more than one set of twin-
related laths occurring
in the same (11 l)? sheet have
645
should
form
energy
is low enough
in austenites
where the stacking
to make
been reported.(8y10)
&(110) dislocations
Dash and Otte’s) and Lagneborg@) observed that in the a-martensite formed in stainless steels there was
occurrence.
evidence
will be difficult and transformation
state
of slip on {llO),
that
planes.
Dash and Otte(s)
three
sets of dislocations are observed w found only two. Examination of while Lagneborg the published indicates
that
predominate. is parallel (liO),,
to
photographs
while alloys
and
the other
appears
to be
There is little evidence
shear is
This would
bands on (lol),.
lead to
This suggestion
that in the Mn-Cr-Ni
is
steel
the E formation
is
nearly perfect and few dislocations
are observed in the
a-martensite,
steel the e is less
while in the Cr-Ni
and the dislocation
density
in the u-marten-
site is high. The presence of dislocations on (liO), cannot be explained in this way. This may be evidence of the operation of a second lattice invariant shear system as suggested by Lagneborg.@)
Another
is that the apparent slip on (liO), represents
accommodation
fortunately,
of
the
shape
strain.
until the surface tilts associated
transformation
in these steels have
and
with
compared
the
values
Unwith the
been measured
predicted
by
the
theory, this latter suggestion cannot be tested experimentally. The found
differences
between
in the Mn-Cr-Ni
found in Fe-C,
Fe-Ni-C
the
a-martensite
steel and in 18-8
steels and the internally
appreciable fault
twinned and Fe-Ni
laths
energies
and form
lath martensite
associated
CONCLUSIONS
The
results
formation
of the investigation
in the
Mn-Cr-Ni
using
transmission
electron
listed
at the end
of
The
results. MacKenzie lattice
theory
invariant
lattice
twinning
for
of u-martensite
and
the
Cr-Ni
steel
microscopy
have
been
section
on
made
the
by
case
experimental the
Bowles-a (111),[121],
of
shear are entirely
these experimental follows : (1) The
the
predictions
consistent
invariant
shear
system
internal twinning
should be observed.
the transformation
to a-martensite
(2) The martensite
habit
plane, for the standard at
82 = i.
to
This habit
plane is perpendicular
the (ill), band of the E or faulted y associated with the a-martensite. (3) The orientation
relationships
between the three
phrases at e2 = # are: (Ill),
II (OOOlL II W),
[1W, IIWOI, IIWlQ (4) When
6 = 1.018
(e2 = #),
the
cc-martensite
MacKenzie
the
be associated
with imperfect
further
may explain
why the transformation
features
of these
emphasises magnitude
the
two
types
distinction
predict
of martensite between
of the shape strains involved
them.
The
are exactly
the same in both cases so that, on strain energy considerations alone, one transformation is just as likely to occur as the other. The difference between the lattice invariant shear systems does, however, provide a possible means of deciding which transformation will occur in a given alloy. The lath martensite, which -has a lattice invariant shear on (ill), in [121],, 5
be
variant used in the present paper, is (ii2),
alloys are suffi-
to
Instead
with faulting or E formation.
should be associated
treatment
a
and no should
of martensite formation. The fact that different lattice invariant shears must be used in the Bowlestheoretical
as
is not
in the a-martensite
associated
with
results and can be summarised
system
plates
cient to show that these represent two distinct modes
containing
of Cr or Mn have low stacking
with faulting or E formation.
stainless
martensite
energy,
amounts
which is 10” from
to be non-uniform. by the fact
possibility
The
evidence available to date supports this, alloys have a relatively
studied in the present investigation
some
should occur via shear system.
fault
dense dislocation
perfect
experimental
lattice invariant and Fe-Ni-C
and as a result the lattice invariant
supported
the (llO),[liO], as the Fe-Ni
The slip on (101), can easily be explained in these alloys the faulting is by no means
also likely
high stacking fault energy this dissociation
high stacking
for slip on the third plane (Oil),
uniform
On the other hand in a material with a
relatively
these references
which is 5’ from (OOl),.
(Ill),. since
of
into &( 112) partials a fairly common
two slip planes, rather than three, One of these is the plane (101), at which (ill),
in both
fault
the dissociation
with perfect E while, when
6 = 1.000 (e2 = 0.643), the a-martens&
mum dilatation formation (5) The
should
or faulted E. This
occurs in preference
at maxito trans-
at zero dilatation.
a-martensite
is in the
form
of
a lath
because its growth into a true plate is restricted by the width of the e-band. In terms of the standard variant the long direction of the lath is [lie],. (6) At e2 = $ twin-related a-martensite laths with the same habit plane may be formed next to one
ACTA
646
METALLURGICA,
another. In fact, in a given (ill>, band three such sets of twin-related laths are possible, each lath following a variant of the KurdjumovSachs orientation relationship associated with the particular (11 l}, plane. ACKNOWLEDGMENTS
The author would like to thank Professor J. S. Bowles for a number of valuable comments and constructive criticisms and for the many stimulating discussions during the preparation of the manuscript. The author is also indebted to the United Steel Companies for supplying samples of the two steels investigated. REFERENCES 1. B. CINA, J. Iron. St. Inst. 177, 406 (1954). 2. B. CINA, J. Iron. St. Inet. 179,230 (1955). 3. B. CINA, Acta Met. 8, 748 (1958). 4. G. P. SANDERSON and R. W. K. HONEYCOMBE, J. Iron et. Inst. Q0Q, 934 (1962). 5. J. A. VENABLES, Phil. Msg. 7,35 (1962). 6. J. F. BREEDIS and W. D. ROBERTSON,Acta Met. lo,1077
(1962).
VOL.
13, 1965
7. R. P. REED, Acta Met. 10,865 (1962). 8. J. DASH 8nd H. M. OTTE, Actcc Met. 11, 1169 (1963). 9. R. LAQNEBORQ,Acta. Met. 12,823 (1964). 10. P. M. KELLY and J. NUTTINQ, J. Iron St. Inst. 197,199
(1961).
Institute of Metals 11. B. A. BILBY and J. W. CHRIST-, Monograph No. 18 Mechanism of Phase Tramformatione in Metals p. 121 (1955). 12. A. J. GOLD-, W. D. ROBERTSON and D. A. Koss Trans. Amer. In&. Min. (Met&?.) Engw 280, 240 (1964). 13. J. S. BOWLES and J. K. MACKENZIE, Actu Met. 2, 129 (1954). 14. J. K. MACKENZIE and J. S. BOWLES, Acta Met. 2, 138 (1954). 15. J. S. BOWLES and J. K. MACKENZIE, Acta Met. 2, 224 (1954). 16. M. A. JASWON and J. A. WHEELER, Acta Cyst. 1, 216 119481. 17. S. R. KEOWN and F. B. PICKERINQ, J. Iron St. Inst. QQQ, 757 (1962). 18. H. ik OT~E, J. DASH and H. F. SCHAAKE,Phys. Stat. Sol. 5, 527 (1964). 19. M. S. WECHSLER, D. S. LIEBERMAN and T. A. READ, T~ans. Amer. Iat. Min. (Metall.) Engrs 197, 1503 (1963). 20. M. S. WECHSLER, T. A. READ and D. S. LIEBERMAN, Trans. Amer. Inst. Min. (Metall.) Engr8 218,202 (1960). 21. P. M. KELLY, MetallurgicaZ DeveZopmente in High Alloy ~Y~e~~S.I./B.I.S.R.A. Conference Scarborough (1964). \----I
22. M. S.
W~CHSLER,
Acta Met. 7,793 (1959).
MARTENSITE LOW
TRANSFORMATION STACKING FAULT
IN STEELS ENERGY*
WITH
P. M. KELLY? The martensitic y to c( transformation in two high alloy steels with low stacking fault energy has been investigated using transmission electron microscopy. In a 12 y0 Mn-10 o/0Cr-4 o/oNi steel the cc-martensite formed as laths, which were always contained within { 11lJy bands of almost perfect hexagonal E. The long direction of these laths was parallel to (11O)r and the habit plane was close to a { 112}, plane, which was perpendicular to the a-bands. The orientation relationships between the three phases y, E and a were determined to within *2” using selected area electron diffraction and in suitable cases to within &p using Kikuchi line patterns. The transformation in a 17 % Cr-9 “/9Ni steel was also examined and found to be essentially similar to the transformation in the Mn-Cr-Ni steel. The Bowles-MacKenzie theory has been applied to this martensite transformation, assuming a (lll),[I2f], lattice invariant shear system, instead of the (11O)J 1101, system used to account for the more familiar transformation to internally twinned martensite, and the theoretical predictions were found to be in good agreement with the experimental results. LA
TRANSFORMATION MARTENSITIQUE ENERGIE DE FAUTE
DANS DES D’EMPILEMENT
ACIERS
A FAIBLE
A l’aide de la microscopic Blectronique par transmission l’auteur a Btudie la transformation martensitique y --f a dans deux aciers allies Q faible Bnergie de faute d’empilement. Dans l’acier a 12:/, Mn-10% Cr-4% Ni, la martensite a apparait sous forme de baguettes qui sont toujours contenues dans des bandes {l 1l}r de la phase 8 hexagonale quasi parfaite. Le grand axe de ces baguettes est parallele aux directions (1 lo), et le plan d’habitat est proche du plan {112},, lui-meme perpendiculaire aux bandes E. Les relations d’orientation entre les trois phases y, E, a ont Qte d&ermin&ss a & 2” en utilisant la diffraction Blectronique selective et dans oertains cas favorables a & p par interpretation des lignes de Kikuchi. La transformation martensitique d’un acier a 17y. Cr-9 y. Ni est similaire a celle de l’acier Mn-Cr-Ni. La theorie de Bowles-MacKenzie a Bti: appliquee & o$te transformation martensitique en faisant l’hypothese que le systeme de oisaillement est (lll)y[121], au lieu du systeme classique (llO),[liO], choisi pour interpreter la plupart des transformations prodmsant une martensite ma&e interieurement. Dans ces conditions, un bon accord est obtenu entre les previsions theoriques et les resultats experimentaux. DIE
MARTENSITUMWANDLUNG IN STAHLEN STAPELFEHLERENERGIE
MIT
NIEDRIGER
Mit Hilfe des Elektronenmikroskops wurde die Martensitumwandlung in zwei hochlegierten Stahlen mit niedriger Stapelfehlerenergie untersucht. In einem Stahl mit 12% Mn-10% Cr-4% Ni bildete sioh u-Martensit in Form von Nadeln, die stets in {lll}r-Blndern der fast idealen hexagonalen s-Phase enthalten waren. Die Langsrichtung dieser Nadeln war parallel zu (110)~ und die Habitusebene war nahe {112},, senkrecht zu den &-Bandren. Die Orientierungsbeziehungen zwischen den drei Phasen y, s und c( wurden mittels Elektronenbeugung in ausgewiihlten Gebieten auf f 2” genau bestimmt, sowie in Die Umwandlung in einem 17% Cr-9% geeigneten Fallen auf )” genau mittels Kikuchi-Linienmustern. Ni-Stahl wurde ebenfalls untersucht und erwies sich als iihnlich der Umwandlung in dem Mn-Cr-Ni-Stahl. Die Bowles-MacKenzie-Theorie wurde auf diese Martensitumwandlung angewandt unter der Annahme anstelle des zur Beschreibung der bekannteren eines gitterinvarianten (lll)y[121]y-Schubsystems, Umwandlung in innerlich verzwillingten Martensit benutzten (1 lO)r[liO],Systems. Die theoretische Vorhersagen und die experimentellen Resultate stimmten gut tiberein.
INTRODUCTION
an
In a number of highly alloyed steels, notably containing
appreciable
hexagonal
e-martensite
amounts is found
the b.c.c. a-martensite.‘l-g)
of
Cr or
in association
those Mn,
a
with
This type of a-martensite,
18-8
stainless
deformed
steel is quenched
at this temperature,
formed parallel to (1 lo),
to -196”C,
martensite
(i.e. (111 ),).
The dislocation
density in these needles was relatively was no sign of the internal
or
needles are
twinning
high, but there found
in high
which appears to form only in low stacking fault energy austenites, has been studied using X-ray diffraction on both optical and electron micros-
The needles often lay in sheets parallel to {ill}, (i.e. (lol},) and adjacent needles in the sheets were generally twin-related. No E was
c~py.(~-~~) Kelly and Nuttingos)
detected in this steel, but isolated stacking faults and fault bundles were observed. The orientation relationship between tc and y was determined using electron
reported that when
* Received September 11, 1964. t Department of Metallurgy, Yorkshire, England. ACTA METALLURGICA,
VOL.
Leeds University, 13, JUNE
1965
Leeds 2,
carbon
martensites.
diffraction 635
and within
the limited
accuracy
of this
ACTA
636
technique
appeared
jumov-Sachs
to be consistent
relationship.
was formed
E and b.c.c.
by stacking
with the Kurd-
After
similar steel in tension at -196’C, both hexagonal
METALLURGICA,
deforming
a
Venables(5) found
u. The hexagonal
faults over-lapping
phase
to form
sheets of more or less perfect E. The u-martensite always associated
was
with one or more of these c-sheets
and the intersection
of two such sheets on different
{ 11 l}? planes was a favoured tc. The orientation
site for the nucleation
relationships
between
of
the three
13,
consequence
1965
of the shears involved
found
that in an Fe-15.1 y0 Cr-11.7%
one transformation
temperature
three different techniques.
which
for
the
ii woi, and
a
relationship.
The
cooling.
y is the
In
same
y
to
E
steels
the
with
studied two and after
a-martensite In
one steel
in
(llO),
the martensite
directions
although
their
evidence
relationship
techniques,
and
plates
single
were elongated
surface
trace
analysis
was
using X-ray
a to y relationship
was
to the {ill},
that
but single some
of
the
a-martensite
pl ane of the band.
Lagenborgu’)
{ill),
bands,
rather
than
to
the
related
e-phase in the austenite,
and
proposed a nucleation mechanism for the a-martensite in terms
showed
planes inclined at 60”
this {225}, habit plane to the hexagonal
partials.
to {ill},,
appeared
The {225}, martensite showed
of slip on two {llO},
associated
with sheets parallel
with the (11 l}, plane of the band.
in the other steel, however,
to each other, one of these (1 lo}, planes being parallel
about 4” away from the exact Kurdjumov-Sachs relationship. The u-martensite in this case was again analysis
both
to have a {259}, habit.
Kurdjumov-Sachs
by Breedis and Robertson@)
trace
Lagneborg@‘)
formed on cooling lay in bands parallel to (11 l}y.
The martensite
IIWI,
determined
surface
Ni alloy only
was detected
18-8 stainless steels both after deformation sub-zero
a large angle (ri85”)
Wl), II(OOOl), IIW), m,
in forming a. This
proposal was later supported by Goldman et ~2.o~) who
showed that the habit plane was a {225}, plane making
:
phases were found to be
VOL.
of the atomic
configuration
at Shockley
The aim of the present investigation
was to deter-
plates could have a habit plane near to (2251,. Reed t7) showed that in 18-8 stainless steels the a-martensite was in the form of plates and not
two steels of low stacking fault energy and in partic-
needles,
as suggested
ular to establish
number
of
these
directions
and
by Kelly
plates
single
were
surface
and Nutting.(lO) elongated trace
consistent with a {225}, habit plane. were elongated
in a direction,
12” from (llo),,
by
analysis
was
Half of the plates
and the habit planes of these plates
a-martensite
bounded
A
(110),
which deviate by up to
were found not to be consistent The
in
plates
{ill},
with a (2251, habit.
always
planes
and
appeared the
in sheets
direction
of
elongation
was always parallel to or close to a (1 lo),
direction,
which
lay in the bounding
{ill},
plane.
mine, as accurately orientation
relationships
determined
Other features, such as the relationship E, the substructure the morphology experimental
an a-martensite plane (ill), would have
results
habit
plane.
Dash
Thus, by the
using transmission
in sheets of faulted
hexagonal
E.
They
disagreed, however, with the suggestion, made by several previous workers, that E nucleates u and instead
proposed
that
the
formation
of
E
was
a
laths and The
in terms
of the
of martensite
trans-
invariant
shear on (11 l)?
WI,. The variant relationship
of the Kurdjumov-Sachs
used by Bowles
orientation
and MacKenzie;05)
ii m,
electron microscopy to study the martensite in 18-12 stainless steel, confirmed a number of the results of earlier investigations and showed that the a-martensite is contained
theory
using a lattice
mi,
in the direction [liO],, plane and not a (225),
and Otte,(s)
are analysed
habit plane
plate lying in a sheet bounded
and elongated a (225), habit
within the a-martensite
IIWL
with the plane of the (11 l}? sheet.
relationship. between a and
of these laths, were also studied.
Bowles-Mackenzie(13-15) formations
laths in
the habit plane, which is associated
(ill),
was always the (225}, plane which made the greatest angle (~85”)
of the a-martensite
(1 lo),
with a particular
the habit plane and
with a specific variant of the orientation
Reed pointed out that, although there are two planes of the type {225}, associated direction, the experimentally
as possible,
i.e.
is taken as the standard variant in the present paper and whenever particular, as opposed to general, indices of planes and directions text
they
are mentioned
refer to this variant.
Jawson-Wheeler(16)
correspondence
The
in the
appropriate
matrices are given
in Table 3. EXPERIMENTAL
The compositions
METHODS
of the two steels investigated
given in Table 1. The steels were rolled into strips 200-300 annealed
are
,U thick,
at 1000°C in argon for one hour and then Partial transformation to quenched into water.
KELLY:
MARTENSITE
TRANSFORMATION
637
FIG. 1. Mn-Cr-Ni steel quenched to -196°C showing a number of large c-bands
(B) containing a-martensite laths. The positions of these laths are indicated by the large arrows and the projected width of the cc-martensitehabit plane interface is visible at A. x 12,000 TABLE 1. Composition Main alloying elements
Cast number
of the steels used
Compo~~;t. Cr
C
-
%) Yi
a-matrensite
17.2
0.04
9.0
-
-
x
and quenched by chemically
samples to - 196°C. electron
polishing
Thin foils suitable
microscopy
min in a 10: 1 acetic:perchloric finally electro-thinning The orientation
relationships
line pattern@) trace analysis
&2’)
for 1 to 2
solution
and
electrolyte,
or the Bollmann
dc, y and E were determined (accuracy
acid
in a chromic-acetic
using either the “window”
between
technique. the phases
using electron diffraction
and where possible Kikuchi
(accuracy
*_t”).
As single surface
does not give a unique
result for the
procedure mal.
(which
gives
to those of a two surface analysis)
was adopted to determine the habit plane of the x-martensite laths. From the traces and projected widths of the numerous stacking faults on (1 ll}, in the austenite, a value of the foil thickness in the area of interest was obtained.
it was found that only one solution was the
same in all cases. EXPERIMENTAL
Mn-Cr-Ni this
Using this value of the foil
thickness and the projected width of the a-martensite habit plane interface (see for example Fig. 1) the angle
RESULTS
steel. The most characteristic
steel,
after
quenching
presence of numerous
to
feature of
--196”C,
bands on {ill},
was
that these bands were hexagonal not
perfect
faults,
and
although
sufficient
to lead
displacement
contained the
to any
of
of
e-bands
and
stacking
faulting
appreciable
was
streaking
of the hexagonal reflections.
to these broad c-bands,
showed
E. The bands were
a number
degree
the
planes in the
austenite (see Fig. 1). Selected area diffraction
formed
procedure
gave two solutions for the habit plane nor-
however,
microscope,
following
trace
Once a number of habit planes had been analysed
narrow
the
by single surface
Since the sense of the tilt of the
habit plane with respect to the foil was not known, this
habit plane of a planar feature and true two surface analysis is not possible with a thin foil in the electron results equivalent
circle determined
analysis was found.
were prepared
the strips down to 50 p in a
mixed acid solution,(17) then electropolishing
patterns
0.010
was achieved by cooling the austenitised
for transmission
In this way the position of the habit plane normal on the great
RM 3827 Mn-Cr-Ni 0.028 10.50 4.10 12.15 0.37 0.016 RM 3897 Cr-Ni
between the habit plane and the foil was calculated.
not or
In addition
a number of fault bundles or single
austenite were observed.
stacking
faults
The a-martensite
in the
laths were
within these E-bands (see Figs. 1 and 2) and
were limited
in size by the width of the bands.
No
cr-martensite laths, which were not associated with these e-bands were ever observed. The cc-martensite showed no evidence of internal twinning and contained very few dislocations. The electron diffraction containing reflections
patterns from the e-bands
a-martensite were complicated, since from all three phases--y, F and a-were
ACTA
638
METALLURGICA,
VOL.
13,
1965
FIG. 2. (a) Bright field micrograph of the Mn-Cr-Ni steel quenched to - 196°C. The E appears as dark bands running approximately horizontally and the cr.martensitelaths are contained within these bands. Retained au&mite between the E-bands is shown at A. x 22,000 (b) Dark field micrograph of the same area taken with a {loil}, reflection. The s-bands now appear light while both the cr.martensite and the austenite are dark. x 17.600
generally
present.
technique
of selecting a diffracted beam as an imaging
By
using the simple
beam, it was possible to determine
dark
which phase gave
rise to a particular
spot on the composite
(see Figs.
2(b)).
2(a)
produced
and
adjacent these
In addition,
by the double diffraction
was diffracted
pattern
reflections
and then in the
second phase could be distinguished. electron
orientation
relationship
determined
to within 12’.
were consistent
diffraction
From
patterns
the
between the three phases was All the patterns analysed
with the relationships
:
although
relationship
0.4”
from
(ill),
[lli],
0.5”
from
[iTo],
Unfortunately
would not
Despite
which
could
to be the plane, e-band.
which
addition,
The degree of
identify
the
particular
relationship
In two cases Kikuchi phases were obtained
was not obeyed in this
line patterns and from
of two of the
these patterns
the
Kikuchi
of the orientstion electron Kikuchi
was in every case found
was faulted
of u-martensite
approximately
diffraction lines, much
from these patterns.
This was true even when In
the Nishiyama steel.
i
plane, which is approximately
parallel to (OOOl), and (lOl),
e-band.
was, however, always sufficient to show that
show
be obtained
orientation
accuracy
from
did not
of
relationship.
and (OOl),
satisfactory
accuracy
determined
could not be distinguished the Greninger-Troiano
with
the limited
have been outside the range of accuracy. In these cases the Kurdjumov-Sachs orientation relationship from the same variant
i (ill),
lying between
pattern from all three phases in the same area.
For example the {ill},
of up to two or
(lOl),
patterns
another
austenite:
lines were rare and it was not possible to get such a
information
three degrees from these exact relationships
between
lath and the adjacent
(lOl),
patterns
IIU~101, II[lm,
in some cases deviations
orientation
u-martensite
relationships
(1111, II(OOOl),IIW), WI,
while the second set of Kikuchi line patterns gave the following
of a beam, which
first in one phase
composite
field
it
to produce
the
more
one
was present was
(llO),
always direction
parallel to a (11 l),
more that one a-martensite
than
in a single possible that
direction.
lath was observed
to was
When in a
single E-band their orientations were either the same or represented two of the six Kurdjumov-Sachs variants associated with the (11 l)y plane of the band (see Fig. 6).
orientation relationships were determined to an accuracy of **O. One set of Kikuchi line patterns
In the latter case the two variants distinguished.
‘came from an u-martensite lath and the surrounding e-band and gave the following orientation relationship :
The cc-martensite within the e-bands was in the form of laths, so possessing both a long direction, which is usually associated with a rod or needle-like
(lOI),
0.9”
from
(OOOl),
[lli],
1.0”
from
[1210],
structure, of a plate.
could always be
and a habit plane, which is characteristic The long direction
of the lath always lay
KELLY:
MARTENSITE
639
TRANSFORMATION
cases where no satisfactory
diffraction
patterns were
obtained from the cr-martensite, the habit plane could not of course be related to a particular
variant of the
However, orientation relationship. results indicated that an u-martensite with an e-band on say (III), relationship
as
the
other
lath associated
must have an orientation
which is one of the six variants associated
with the plane of the band (i.e. one of the six variants shown
in Fig.
relative
6), the position
of the habit
plane
to the plane of the band could be inferred.
In all these cases the habit plane was found
to be
close to a {112}, plane, which was perpendicular
to the
(11 l)y plane of the band. FIG. 3. Stereographic projection showing the poles of the habit plane normals of a-martensite laths in the Mn_cr-Ni steel. All the laths analysed were in the standard variant of the orientation relationship i.e. (ill),
II(OOOl)EII(1Ol)a
Although
the greater part of the work steel some observa-
tions were also made on a Cr-Ni steel to compare the transformation
behaviour in a material that is thought
to have a higher stacking fault energy.
[iioly 11 pie], 11liiild
crystallographic
and were contained within E-bands parallel to (11 l),.
The maximum scatter in the results is about four times greater than the experimental error. The variation of habit plane with Ba for a (1 ll), [121]~ lattice invariant shear is shown as a dotted line. in the E-bands and could
Cr-iVi steel.
was carried out on the Mn-Cr-Ni
be considered
as the inter-
Cr-Ni
In general the
features of the transformation
steel and confirmed stainless steels. in which
the
previous
observations
There was however Cr-Ni
martensite
cr-martensite in the Mn-Cr-Ni
differed
were very imperfect and should probably as irregular
direction
reflections
fault
in the electron
results on martensite in Cr-Ni steels. Since a particular
not as common
variant
observed
of
the
distinguished
orientation
whenever
relationship
satisfactory
could
diffraction
terns from the u and y or E were obtained, direction
be pat-
the long
of the lath could be related to this variant.
bundles
reflections, disorder.
again
diffraction
they were streaked
the stacking always
the
be described
(see Fig. 4).
as in the Mn-Cr-Ni
the austenite
from
steel. First, the e-bands
Single surface
that this long with previous
on 18-8
several respects
section of the habit plane with the plane of the band. trace analysis showed was (1 lo), in agreement
in the
steel were similar to those of the Mn-Cr-Ni
Hexagonal
patterns
were
steel and when
and displaced
towards
as would be expected
from
The cr-matrensite laths were
associated
with
these imperfect
e or
In every case analysed the (1 lo), long direction proved
fault bundles, but in some cases the width of the lath
to be the same (llO),
was greater than the width of its fault bundle
direction
mately parallel to (111 ),-i.e. used
in the present
which was approxi-
in terms of the variant
paper
the long
always [ilo],. The habit plane of the martensite mined
to
described those
within
about
above.
where the habit
martensite
lath
52”
The most
direction
4).
number with
laths was deter-
using
the procedure
significant
results were
plane was determined
of known
was
Fig.
orientation
for a
relationship.
The of
fault
cr-martensite
previous
twin-related. twinning
work,
but
the
agreement
The
results
of
shown in Fig. 3.
fourteen
orientation such
relationship.
determinations
For the variant
are
of the orientation
relationship used in the present paper, the habit plane was always found to be near to (ii2),. These results are in agreement with those of Reed(‘) and Lagneborg’s) to the extent that the habit plane makes an angle of approximately
90” to the (ill),
plane of the e-band,
but differ from them in that the habit plane results are significantly closer to (112), than to (‘225),. In the
and,
adjacent
a
in agreement
laths
were
often
dislocation
density
within
the
higher
The results of the present analysis of the cr-marten-
particular
the
laths,
(see
contained
u-martensite was on the whole considerably than in the Mn-Cr-Ni martensite. site in the Mn-Cr-Ni
of
generally
Again there was no evidence of internal
In these cases the habit plane could be related to a variant
bundles
steels.
with
and the Cr-Ni steels are in good
previous
The results
work
on
18-8
on the transformation
steels, whose common
feature appears to be that the
austenite has a low stacking summarised as follows :
(1) The a-martensite
stainless in these
fault
energy,
is not internally
can be
twinned
and
the only form of internal substructure is dislocations. The dislocation density is not the same in the two steels and in some cases regular arrangements of dislocations are observed.
640
ACTA
METALLURGICA,
VOL.
13,
1965
FIG. 4. Cr-Hi steel quenched to -196°C showing three E-bands containing cc-martensitelaths. The orientation is such that the long direction of the laths is perpendicular to the foil. The z-bands are very imperfect, particularly at A. Note the high dislocation density in the rx-martensiteand that the twinrelated laths at B are somewhat wider than their associated E-bands. X 28,000.
The u-martens&e is always associated with bands of hexagonal E or faulted sustenite and the width of the lath is restricted to a considerable extent by the width of the band. (3)The orientation relationships between the three phases is spproximately :
(1111, II(OOO~L IIW),
(4)The habit plane of the a-martensite laths is near to a (112) plane which is perpendicular to the {Ill), plane of the faulted bundle or e-band. For the variant of the orient&tion relationship given above the habit plane is (1124. (5)The long direction of the a-martensite laths is [liO], in terms of the standard variant of the orientation relationship. (6)When more than one m&r~nsite lath is formed in a given band, adjacent laths are often twin Twin-related laths have identical related. habit planes and the same long direction. (7)In it given s-band, six variants of the orientation relationship are possible. These consist of three twin-pairs. In terms of the standard variant (112),. (121), and (2ii),, are the habit planes for the three pairs of twin-related laths in a (11 l)y band, while the relevant long directions are [ITO],, [iOl], and [Oli], respectively.
DISCUSSION
When the features of the martensite tr&nsform&tion in Mn-Cr-Ni and Cr-Ni steels are compared with those of the more familiar transformation in Fe-C, Fe-Cr-C, Fe-Ni, and Fe-Ni-C, which generally leads to internally twinned plates, certain fundamental differences, which distinguish this u-martensite from the inte~ally twinned variety, become apparent . The absence of internal twinning is not unduly significant, since the complementary strain could be accommodated by slip as well as by twinning, and portions of such martensite plates, which are free of twins, have been observed. The association with E or faulted y is a more ~h~r~~teristi~ distinguishing feature, while the most important difference between the cc-martensite in these Mn-Cr-Ni and Cr-Ni steels and internally twinned martensite is the habit plane. Admittedly the habit plane is close to a plane of the type (225), and the Bowles-MacKenzie theory of the m~rtensite transformation, as applied to internally twinned martensite,06) predicts a (225), habit at maximum dilatation. In terms of the variant of the orientation relationship used in the present paper, however, the internally twinned martensite should have s (2251, habit, while for the same variftnt of the orientation relationship the a-martensite laths in the Mn-Cr-Ni steel have it (ifa), habit plane, which is a few degrees from (2%5), not (225), (see Fig. 3). Hence, although the Bowles-MacKenzie theory, when applied to the y to OLtransformation with a lattice invariant
KELLY: TABLE
2.
MARTENSITE
Values of the magnitude of the lattice invariant shear 9 and the shear component of the shape strains for the three (11 l}Y( 112)Y lattice invariant shear systems?)
Case no.
Lattice invariant shear svstem in anntenite
1
(111),[121lY
(lol),[roll,
2
(111M1121,
(101),[13i1,
3
(111):~[2rr],
(101),[1371,
* Negative
shear on (llO), martensite, Cr-Ni
Magnitude of lattice invariant shear o(at S = 1.000)
Corresponding shear svstem in mnrtensite
(a) (b) (a) (b)
Magnitude of the shape strain s(at zi = 1.000)
+0.284 +0.423 -0.279* +1.548
0.219 0.219 0.398 1.861
Crystallographically
equivalent
to Case 2 above
values for 9 indicate that the shear is in the opposite direction to that given in the table.
[liO],,
is very successful in accounting
of the lattice invariant. shear g and the shear compo-
features of internally twinned
nent of the shape strains in f.c.c. to b.c.c. transforma-
for the crystallographic features
641
TRANSFORMATION
it is not
of
the
steels.
consistent
with
transformation
The success
the observed
in Mn-Cr-Ni
and
show internally
twinned
(225), or (259), plates, leads to the conclusion
that any
alterations
steels, which
required
to account
these (11 l}y (112), shear systems have
been calculated
by Wechsler et &(20)
These values of
g and s are shown in Table 2.
of the phenomenological
theories in dealing with the martensite transformation in the other
tions involving
for (112), martensite
Although
there
is very
little
difference
in the
smaller values of g for the two distinct cases 1 and 2, the values of the shape strain s differ considerably. The lattice invariant
shear system
(111),[121],
gives
laths should not be made to the theories themselves,
the smallest, value of s and hence on the grounds
but to one of the assumptions
minimum
theories to this particular The current
(a) the
transformation
product
of
are based on
between
the parent, and
parameters
of
the
two
phases,
shear system.
can only be altered slightly,
whether this alteration is acheived directly by alloying or indirectly
invariant
by the introduction
of a small uniform
as is done in the Bowles-MacKenzie
theory.
In any event a small change in these parameters
will
can
be
produced
by
System I: and System II:
only
that the (11 l}y (112),
stacking
fault shear
might be an appropriate
invariant shear system for the transformation steels.
In terms of the standard variant,
mental results show that the faulted
lattice in these
the experi-
plane is (ill),
and so the three shear systems involving a (112), dire&ion lying in (11 l)? must be considered. One of these
systems,
[iOl],
in the martensite
(ill),
[121],
corresponds
to
(lOl),
while the other two, (ill),
namely:
(112),[11T],
(111),[121],
i.e.
(lOl),[iOl],
Since no other shear system gives a lower value s, then, if the criterion of minimum ing the transformation shear system, should
strain energy accompany-
governs
martensite transformation.
system in austenite
systems, i.e.
shear system as the only alternative.
suggests
two
(llO),[liO],
lattice invariant
E or faulted y
plane or
shows that the smallest possible value of s
systems
steels the association
system in either
of two such systems with either a common
This leaves the choice of a different
and hexagonal
survey(21)
or to a simple shear composed
(259), to (112),.
and Cr-Ni
of
lattice
to either a simple
slip or twinning
invariant
between the u-martensite
likely
in the y to u marten-
is restricted
not shift the habit plane from the region of (225), and
In the Mn-Cr-Ni
more
A more extensive
shear system involved
shear on a normal
suggests that this cannot be altered.
The lattice parameters
dilatation,
shear system.
direction,
The first of these is well established and the agreement
is the
of the values of g and s, which result when the lattice
austenite or martensite
(c) the lattice invariant with experiment
energy
site transformation
phases,
lattice
strain
invariant
theories,(l3JV9)
input data :
correspondence
(b) the
the
transformation.
phenomenological
the au&en&e-martensite the following
used in applying
operate
in any
martensite
application
y to
M.
shear system used in
of theories to the familiar
transformation
and Fe-Ni-C
of these two
particular
The first of these systems
is of course the lattice invariant the successful
the choice of lattice
one or other
in Fe-C
Fe-Cr-C,
Fe-Ni
and System II will now be used as the
lattice invariant shear system in applying the BowlesMacKenzie
theory to the transformation
and Cr-Ni steels.
The notation
will be used in this application in Table 3. Figure 5 is a stereogram variation
of the habit
plane
in Mn-Cr-Ni
and input data which of the theory are given
showing with
the calculated 6J2 obtained
by
[112], and (ll!), [211],, correspond to (IOl), 11311, and (101), [131], respectively and so are crystallo-
applying the Bowles-MacKenzie theory to the transformation with a lattice invariant shear on (111 )Y
graphically
[121],.
equivalent
to each other.
The magnitude
For comparison
the variation
of habit plane
ACTA
642
METALLURGICA,
TABLE 3. Notation and input data used in the application of Bowles-MacKenzie theory Jaswon-Wheeler
correspondence matrices for the chosen standard variant : to a (directions)
VOL.
13,
1965
habit plane is exactly solutions
(112), and the two habit plane
reduce to one, since gi = g,.
of the habit plane normal
ship
P,
for the
formation
more
with a (llO),
familiar [liO],
case of the trans-
lattice invariant
is also plotted on the same stereogram.
shear,
the Kurdjumov-Sachs
relation-
: (ill), IIWL ml,
II[1lQ,
which is only 8” away from the orientation ship determined
from
Kikuchi
be the plane
(ill),
and so this must be the plane
which is faulted to produce predicted
relation-
line patterns.
The shear has been taken to
plane of the lattice invariant
The with
at 8 = 6 is in very good
agreement with the experimental results (compare Fig. 3 and Fig. 5). The orientation relationship at this value of O2 is exactly
Lattice invariant shear system: (lllh, [1211y c’]a’ = tetragonality of martensite = 1 (cubic martensite) C&= lattice parameter of austenite = 3.58 A a’ = lattice parameter of martensite = 2.87 A 6 = the dilatation parameter, which represents a small isotropic volume change. 19= 6(a’/a) (the maximum value of 19~for cubic martensite is 8). 8 = the shear component of the shape strain. g = the magnitude of the lattice invariant shear. In general there are two values of g. These will be represented as g, and g2 where g1 is less than g,.
The position
(ii2),
the band of hexagonal
habit
plane
is exactly
E.
per-
pendicular to this band, in agreement with the experimental results. As
The direction
e2 varies
calculated
the
curve
habit
either
plane
moves
towards
along
(ill),
for
the small
which is perpendicular to the shear plane [iOl],, normal (ill), and the shear direction [121],, is an axis
values of the lattice invariant shear g or towards (OOl),
of two fold symmetry
for large values of g. The variation of the orientation relationship with e2 is closely similar to the variation
unique
or contraction
tortion
[OIO],.
lattice
invariant
‘K-degenerate’(22) solutions
and is also perpendicular
to the
axis of the pure lattice
dis-
The
case of transformation with a _shear on (111),[121] is therefore and
is reduced
sponding to eachvalue
the number
from ofg.
four
of habit
to two,
one
with e2 when the lattice invariant [liO],.
shear is on (llO),
For example when 19~= 0.643 (6 = 1.000) the
plane
habit plane for g, (the smaller of the two values of g)
corre-
is near (334), and the orientation
At e2 = $(6 = 1.018) the
to the Greninger-Troiano
relationship
relationship.
is close
The values
of the shape strain s vary with e2 in exactly the same way as they do when the lattice invariant (llO,)[liO],.
At e2 = # the magnitude
strain
is 0.212
and
[-0.81,
0.47,
0.351,.
equivalent
its direction This
is approximately
shape
strain
is in fact
to a shear of 0.192 in the direction
plus an expansion
because
the
steel was associated give hexagonal tion between
[ilO],
of 0.089 normal to the habit plane
(112),. The lattice invariant chosen
shear is on
of the shape
shear system (1 ll),
cr-martensite
-[121], was
in the Mn-Cr-Ni
with faulting of the austenite to
8. In pursuing this apparent cc-martensite and faulting
connec-
of E forma-
tion great care must be exercised, since it is important to
distinguish
between
the
complementary
direction and the lattice invariant also between (loo)r
FIG. 5. Stereographic projection showing the theoretical variation of the habit plane with tP for the standard variant of the orientation relationship and a lattice invariant shear on (111)~ [121]r. The projection is plotted in the standard (001)~ orientation for austenite and the positions of the {lOO}a poles of the a-marten&e are indicated. For comparison, the habit plane variation with Befor the more familiar case of a (110)~ [ liO!y lattice invariant shear is shown as a dotted line.
opposite.
a stacking
shear
shear direction and
fault shear direction
and its
Stacking faults are formed in austenite by
displacing a {ill}, plane by 6(121), in relation to an adjacent {ill}, plane. If faulting occurs on every other {ill}, plane then hexagonal close packed E will be formed. If the E formation is homogeneous, the magnitude plane [lgl],,
of the shear involved
(ill), the possible [211], and [112],.
in 195’.
In the
faulting directions are The opposite direction
KELLY:
[T2T],,
[2ii],
directions
and
[ii2],
are not
since the displacement
over another in these directions
MARTENSITE
possible
643
TRANSFORMATION
forms within the band.
faulting
of one (11 l)? layer results in the atoms
In effect this means that, if
the E forms inhomogeneously,
as appears
to be the
case, then the e-band really represents a region of y
on adjacent layers being “pushed against one another”.
which has been subjected
The complementary
trans-
and the lattice
shear,
invariant plane strain (plus a slight “shuffle”
formation since
is the inverse of the lattice invariant
the
complementary
homogeneous lattice
strain
is regarded
as a
strain which distorts the lattice, and the
invariant
which
strain in the martensite
exactly
shear
cancels
is an inhomogeneous any shape displacement
that
It
is
therefore
important
to
of the complementary
invariant
shear direction
know
strain.
whether
is along a possible
direction in the transformation
faulting
being considered.
analysis is in fact based on the complementary being in a faulting
the
strain or the lattice
direction,
The strain
(OOOl),
planes)
Only
would
The
only
difference
interpretations
as an effect produced second case tively
This is
of atoms
therefore E to
these
by the formation
be
a.
two
possible
of c( and in the
is the cause of u formation.
E
the difference
time sequence, possibility
between
one further
is that in the first case the E is regarded
can be expressed
i.e. which
Alterna-
in terms of a
comes first u or
has its supporters.
Each
E.
Dash and Otte@) and
Goldman et a1.(12)take the view that E is a consequence and not a cause of tc formation
i.e. the complementary
strain is in the sense (1211, and not [121],.
adjacent
shears.
necessary to convert a portion of this
shear
would have been caused by the complementary direction
on
to both the complementary
invariant
and others+‘)
while Lagneborg@)
support the view that E forms before u.
borne out by the positive values of g when the lattice
There is no evidence in the present work to distinguish
invariant shear is chosen to be in the sense [121],.
between
leads to two possible interpretations between
cc-martensite
hexagonal
or E formation other
and
words
complementary
u-martensite
of M formation. forms
first and
of faulting.
complementary
into the austenite in the
If the value
(i.e. the a-martensite
of 02 is exactly
that, since the complementary
to the surroundThis implies
shear leading to E
then there is no need for the compensating
invariant
crystallographic
shear. theories
If this were so, then of
martensite
is inhomogeneous. formation would
the
formation
invariant plane.
have
an
If, on the other hand, the a-marten-
site and the surrounding
austenite
are subjected
to
applied.
possibility
macroscopic tion
between
distortion. a-bands
and would not lead to any
or faulting
it is unlikely that the
that of
in every case.
E
lath was formed
it is
laths could now form in
form
can form
form as a consequence
interpretation
the second
and cc-martensite would e-bands.
Irrespective
of the association
is correct, the theoretical
of
between
tc
analysis predicts that
at e2 = f the following relationships E
c-band
of u formation,
in the transformation
in these pre-existing E
in a given
even in a material where the
would be obeyed
between X, y and
should be observed: (ill),
II (OOOl), II (lOl),
PW, IIPm,
The austenite would still be faulted too, the
would be inhomogeneous
E
at a later stage
theories could still be
only difference being that in this case the e-formation
laths
Therefore,
first bands of
both the complementary strain and the lattice invariant shear the total strain would not be homogeneous and the crystallographic
of the lead to
if the first possibility
More u-martensite
of u-martensite
and
not
an e-band,
is
this c-band and it is well established that large numbers
homogeneous
would
the E formation
if an u-martensite
produce
correct.
both possibilities
In addition
of CI can precede
For example
which
as a result
of u is concerned,
the same results provided
would not longer apply as the total strain would be and
The controversy
one as it appears at
first sight, and as far as the crystallography formation
(see Fig. 4).
shear is accommodated
by the austenite as a homogeneous lattice
$
has a (112), habit) and all of the
strain is transmitted
ing y, a band of E should be produced.
formation,
In the
strain, instead of being confined to the
cr-martensite, is transmitted form
or
is that the faulting
is a consequence the
austenite
these two possibilities.
not, however, such a fundamental
of the association
faulted
The first possibility
E.
This
The
association
hexagonal
E
between
II[IlU, the
cc-martensite
and
may have an effect on the position of the
Examination
of the interac-
martensite
and
scratches
experimental results, the habit planes in the Mn-Cr-Ni steel cluster round (112), and not round the (22~5)~
surface
and
between e-bands on different planes shows that the F formation is apparently inhomogeneous. The second possible explanation of the association between ct-martensite and E or faulted austenite is that the e-band forms first and the cc-martensite then
habit
plane.
Despite
the scatter
in the
habit determined by Reed(‘) and by Lagneborg,t9) who both used single surface trace analysis. More important,
the experimental
habit plane results lie some
15” from the habit plane predicted
for zero dilatation
ACTA
644
(02 = 0.643, 6 =
between
1965
the theoretical
(e2 = Q, 6 = 1.018).
interest to note that the maximum is also required
of this 1.8% dilatation
It is of
value of the dilata-
to produce
habit found in plain carbon steels. the Mr-Cr-Ni
13,
habit planes occurs at the maximum
value of the dilatation tion parameter
VOL.
1.000). Consequently in the Mn-Cr-
Ni steel the best agreement and experimental
METALLURGICA,
the (225),
The introduction
to explain the
(ii2), habit in
steel seems to be supported
by the fact
that at this value of ti2 the complementary
shear is
exactly that required to produce E from y and at some other value of e2 the complementary give rise to perfect for example,
E. When
the complementary
strain should result
in imperfect E containing approximately ten
(OOOl), planes.
perfect
the
stable
to expect
than imperfect
E, the
at S = 1.018 (e2 = $), which
be associated to
one fault every
As it is reasonable
E to be more
transformation
shear will not
6 = 1.000 (e2 = 0.643)
would
with perfect E, may occur in preference
transformation
at
which would be associated
6 = 1.000
Pm. 6. Stereoeraohic oroiection showine the theoretical variation of the habit *plaAe with Oafor?he six variants of the orientation relationship that have (111 by 11(101)~. The lattice invariant shear is on (111)~ in every case and the uositions of the C-axis of the cc-martensitefor each variant are shown bv the black souare8. The variants with the same subscript (e.g. XI a;d Ys) comprise a twinrelated Kurdjumov-Sachs pair when Be = #. YB is the standard variant used in the paper.
(es = 0.643),
with imperfect
E.
In addition to the effect on the position of the habit plane,
the
association
hexagonal site
between
E also determines
grains.
This
type
u-martensite
of
cr-martensite
has
described by previous workers both as needlea plates.’ the
and
the shape of the martenbeen and as
Neither of these terms give a true picture of
shape
described
of
the
martensite,
as a lath.
morphology
which
The reason
can
best
be
for this lath-like
is that the growth of the martensite is to a
large extent
restricted
by the width
The habit plane of the martensite the band and growth
is perpendicular
to
along the normal to the band
would require further faulting of the band.
of the E-band.
to increase the width
This restriction does not apply to growth
in the direction
[lie],, which lies in the plane of
line.
These six habit lines are in fact three pairs, each
pair touching at a pole of the type {112}, when e2 = Q. The
two
orientation
Sachs variants. comprise
corresponding touch habit so
habit
at (112)
that
two
lattice invariant orientation plane.
shear.
relationship
There are six variants of the associated with a given
The position of the martensite
six variants in each case.
j] [lOl),
The standard variant considered
when
e2 = #.
to X,
workers.@@))
(lgi),.
pair
these
two
This
These
therefore and
the
variants
common
(112)
in the martensite,
laths
with
would
related laths with their common plane
twin
to (12i),
and Y,
Kurdjumov-
and Y,
orientations
appear as twin-
habit plane being the
twin-related
laths
have
in the present work and by previous The shape strain for the lath in orienta-
tion Y, can be regarded as a shear on the habit plane (ii2) in the direction [ilO], plus an expansion
(11l)y normal to the habit, while for the lath in the X,
c axis for these
is shown in Fig. 6 where (ill),
8,
for
a-martensite
corresponding
been observed using a (111),[121],
lines
plane is parallel
plane. point emerges from the theoret-
The variants
a Kurdjumov-Sachs
twin
Another important
at this common
point of each pair consist of twin-related
the band and, as a result, the u-martensite forms as a lath with a [liO], long direction and a (112), habit
ical analysis of this transformation
relationships
so far
orientation
the shear component
is in the direction therefore
[liO],.
of the shape strain
These twin-related
have shear components
laths will
of their respective
has been that denoted by Y, in Fig. 6, where the lattice invariant shear direction was taken to be [i2i],. By selecting the appropriate (112), direction lying in (ill), for each variant of the six orientation
shape strains that are exactly opposite. This should lead to a pair of these twin-related laths forming next
relationships
theoretical
associated
with
(ill),,
the
six habit
plane lines shown in Fig. 6 are obtained. The variant corresponding to each habit line is marked next to the
to one another, so that the shear components of their shape strains could cancel each other. Finally the analysis
predicts
that three such sets of
twin related laths with habit planes (ii2),, (2iijy and (121)could occur in a given (ill), sheet of faulted y
KELLY:
of hexagonal
MARTENSITE
TRANSFORMATION
E. Cases of more than one set of twin-
related laths occurring
in the same (11 l)? sheet have
645
should
form
energy
is low enough
in austenites
where the stacking
to make
been reported.(8y10)
&(110) dislocations
Dash and Otte’s) and Lagneborg@) observed that in the a-martensite formed in stainless steels there was
occurrence.
evidence
will be difficult and transformation
state
of slip on {llO),
that
planes.
Dash and Otte(s)
three
sets of dislocations are observed w found only two. Examination of while Lagneborg the published indicates
that
predominate. is parallel (liO),,
to
photographs
while alloys
and
the other
appears
to be
There is little evidence
shear is
This would
bands on (lol),.
lead to
This suggestion
that in the Mn-Cr-Ni
is
steel
the E formation
is
nearly perfect and few dislocations
are observed in the
a-martensite,
steel the e is less
while in the Cr-Ni
and the dislocation
density
in the u-marten-
site is high. The presence of dislocations on (liO), cannot be explained in this way. This may be evidence of the operation of a second lattice invariant shear system as suggested by Lagneborg.@)
Another
is that the apparent slip on (liO), represents
accommodation
fortunately,
of
the
shape
strain.
until the surface tilts associated
transformation
in these steels have
and
with
compared
the
values
Unwith the
been measured
predicted
by
the
theory, this latter suggestion cannot be tested experimentally. The found
differences
between
in the Mn-Cr-Ni
found in Fe-C,
Fe-Ni-C
the
a-martensite
steel and in 18-8
steels and the internally
appreciable fault
twinned and Fe-Ni
laths
energies
and form
lath martensite
associated
CONCLUSIONS
The
results
formation
of the investigation
in the
Mn-Cr-Ni
using
transmission
electron
listed
at the end
of
The
results. MacKenzie lattice
theory
invariant
lattice
twinning
for
of u-martensite
and
the
Cr-Ni
steel
microscopy
have
been
section
on
made
the
by
case
experimental the
Bowles-a (111),[121],
of
shear are entirely
these experimental follows : (1) The
the
predictions
consistent
invariant
shear
system
internal twinning
should be observed.
the transformation
to a-martensite
(2) The martensite
habit
plane, for the standard at
82 = i.
to
This habit
plane is perpendicular
the (ill), band of the E or faulted y associated with the a-martensite. (3) The orientation
relationships
between the three
phrases at e2 = # are: (Ill),
II (OOOlL II W),
[1W, IIWOI, IIWlQ (4) When
6 = 1.018
(e2 = #),
the
cc-martensite
MacKenzie
the
be associated
with imperfect
further
may explain
why the transformation
features
of these
emphasises magnitude
the
two
types
distinction
predict
of martensite between
of the shape strains involved
them.
The
are exactly
the same in both cases so that, on strain energy considerations alone, one transformation is just as likely to occur as the other. The difference between the lattice invariant shear systems does, however, provide a possible means of deciding which transformation will occur in a given alloy. The lath martensite, which -has a lattice invariant shear on (ill), in [121],, 5
be
variant used in the present paper, is (ii2),
alloys are suffi-
to
Instead
with faulting or E formation.
should be associated
treatment
a
and no should
of martensite formation. The fact that different lattice invariant shears must be used in the Bowlestheoretical
as
is not
in the a-martensite
associated
with
results and can be summarised
system
plates
cient to show that these represent two distinct modes
containing
of Cr or Mn have low stacking
with faulting or E formation.
stainless
martensite
energy,
amounts
which is 10” from
to be non-uniform. by the fact
possibility
The
evidence available to date supports this, alloys have a relatively
studied in the present investigation
some
should occur via shear system.
fault
dense dislocation
perfect
experimental
lattice invariant and Fe-Ni-C
and as a result the lattice invariant
supported
the (llO),[liO], as the Fe-Ni
The slip on (101), can easily be explained in these alloys the faulting is by no means
also likely
high stacking fault energy this dissociation
high stacking
for slip on the third plane (Oil),
uniform
On the other hand in a material with a
relatively
these references
which is 5’ from (OOl),.
(Ill),. since
of
into &( 112) partials a fairly common
two slip planes, rather than three, One of these is the plane (101), at which (ill),
in both
fault
the dissociation
with perfect E while, when
6 = 1.000 (e2 = 0.643), the a-martens&
mum dilatation formation (5) The
should
or faulted E. This
occurs in preference
at maxito trans-
at zero dilatation.
a-martensite
is in the
form
of
a lath
because its growth into a true plate is restricted by the width of the e-band. In terms of the standard variant the long direction of the lath is [lie],. (6) At e2 = $ twin-related a-martensite laths with the same habit plane may be formed next to one
ACTA
646
METALLURGICA,
another. In fact, in a given (ill>, band three such sets of twin-related laths are possible, each lath following a variant of the KurdjumovSachs orientation relationship associated with the particular (11 l}, plane. ACKNOWLEDGMENTS
The author would like to thank Professor J. S. Bowles for a number of valuable comments and constructive criticisms and for the many stimulating discussions during the preparation of the manuscript. The author is also indebted to the United Steel Companies for supplying samples of the two steels investigated. REFERENCES 1. B. CINA, J. Iron. St. Inst. 177, 406 (1954). 2. B. CINA, J. Iron. St. Inet. 179,230 (1955). 3. B. CINA, Acta Met. 8, 748 (1958). 4. G. P. SANDERSON and R. W. K. HONEYCOMBE, J. Iron et. Inst. Q0Q, 934 (1962). 5. J. A. VENABLES, Phil. Msg. 7,35 (1962). 6. J. F. BREEDIS and W. D. ROBERTSON,Acta Met. lo,1077
(1962).
VOL.
13, 1965
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Institute of Metals 11. B. A. BILBY and J. W. CHRIST-, Monograph No. 18 Mechanism of Phase Tramformatione in Metals p. 121 (1955). 12. A. J. GOLD-, W. D. ROBERTSON and D. A. Koss Trans. Amer. In&. Min. (Met&?.) Engw 280, 240 (1964). 13. J. S. BOWLES and J. K. MACKENZIE, Actu Met. 2, 129 (1954). 14. J. K. MACKENZIE and J. S. BOWLES, Acta Met. 2, 138 (1954). 15. J. S. BOWLES and J. K. MACKENZIE, Acta Met. 2, 224 (1954). 16. M. A. JASWON and J. A. WHEELER, Acta Cyst. 1, 216 119481. 17. S. R. KEOWN and F. B. PICKERINQ, J. Iron St. Inst. QQQ, 757 (1962). 18. H. ik OT~E, J. DASH and H. F. SCHAAKE,Phys. Stat. Sol. 5, 527 (1964). 19. M. S. WECHSLER, D. S. LIEBERMAN and T. A. READ, T~ans. Amer. Iat. Min. (Metall.) Engrs 197, 1503 (1963). 20. M. S. WECHSLER, T. A. READ and D. S. LIEBERMAN, Trans. Amer. Inst. Min. (Metall.) Engr8 218,202 (1960). 21. P. M. KELLY, MetallurgicaZ DeveZopmente in High Alloy ~Y~e~~S.I./B.I.S.R.A. Conference Scarborough (1964). \----I
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