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Morphology and crystal structure of carbides precipitated from solid solution in alpha iron
MORPHOLOGY PRECIPITATES
AND CRYSTAL STRUCTURE OF CARBIDES FROM SOLID SOLUTION IN ALPHA IRON*
W, C. LESLIE,P
R
M. FISHER?
and N. SENf
The carbides precipitated from solid solution in high-purity iron-carbon alloys, in two low-carbon steels and in an iron-carbon-3.25% silicon allay were studied by electron microscopy and diffraction. In the iron-carbon alloy and in the two low-carbon steels the carbide precipitates in a dendritic form during aging following quenching. In specimens quenched directly to the aging temperature oblong plates appeared, along with dendrites. Both of these forms are cementite (FE&) and no diffraction evidence of precipitation of epsilon carbide was found. The time required for formation of identi~able particles at 260°C corresponds to the time reported by others for 76 per cent aompbtion of the precipitation reaction, as memured by internal friction. At 150°C the time required for form&ion of such particles was much longer t&m the time for completion of precipitation, as measured by internal friction. The dendritic carbides in Fe-C alloys &ppea,rto p~cipitat~ on (110) planes of ferrite, with brnnches along (11 I> directions. In the iron-3.25% silicon alloy the carbides take t,he form of lentieular disks precipitated on
ET STRUCTURE CRISTALLINE DES CARBURES PARTIR D’UNE SOLUTION SOLIDE DE FER cc
PRECIPITES
A
-4 l’aide de la microscopic et de la diffraction Blectroniques, les auteurs ant etudie les carbures preeipitbs & pertir de la solution solids dans des a&ages fer-carbone de t&s haute pm&+, dans deuaz zmicrsk bas carbone et dans un &age fer-carbone-3,25% silicium. Dsns l’&sge Fe-C et dens les deux seiors It bas earbone, Its carbums pritcipitent sous une form% dendritique pendttnt le vieiflissement ~pr&s trempe. Dans tes Bchantillons tramp& directement B la temperature de vieilfissement, epparaissent des plaquettee oblongues en m&me temps que des dendrites. Ces deux formes sont const&ubes par la c&nentite (Fe&) et b diffraction ne r&v&? aucune trace de carbure E. Le temps necessaire 8, la, formation de psxticules identi~abl0a k 25O’C correspond au temps mesu& pm frnttement interne et requis pour que la precipitation soit r&&s& ii 76 per cent. Au contraire 2r 156”C, 1%temps r&&if k la formation de ces particules est beaucoup plus long que eelui indique par le frottement interne pour le d~roulem~nt eomplet de la pr&ipitation. Len carbures dendritiques dans les allixges Fe-C precipitent sur fes plans {l 101 de la ferrite, &vec des ramifications le long des directions {ill). Dans l’alliage Fe-C-3,255(/, Si, les carbures prennent la forme de disques lenticulniresprecipitant sur les plans (100) de la matrice ferritique. La structure cristalline bien que non d&ermintie, ne peut etre celle du citrbura E ni de la cementite. Au come d’un vieillissement prolong& ces disques sont deplaces par des films de cementite le long des joints de grains. ~~ORPHOL~GIE
UND KRISTALLS~~UKT~~ VON KA~,~ID~~USS~H~IDUNGEN A~P~A~~ISEN-MIS~HK~ISTAL~~N
-4US
Die K~rbid~usseheidungen sue ~is~hkrist&llen von hu~ll~einen risen-Kohlensto~egierun~en, zwei kohl~~toffarInen Stithlen und einer Eisen-Kohlenstoff-3,25°/~ Silizium-Le~~~g wurden mit dem ~lektronenmikroskop und mit ~lektronen~u~ng untsrsucht. Aus der Eisen-KohlenstoffLegierung und mxsden zwei kohlanstoffa,rmen Stiihlen scheidet sich das Karbid w&hrend des Auslagerns nach dem Absehreeken in dendritisaher Form aus. In Proben, die direkt auf die Auslagerungstemperatur abgesehreckt worden waren, erschienen l&ngliehe Pliittehen ~~~~rnrnenmit Dendriten. Bcide Formen sind Zementit (Fe&) und die Bougungs~ufnahmeu g&en keinen Hinweis auf die Ausseheidung von Epsilon-Karbid. Die Zeit, die bei 250°C notwendig ist, damit sich identifizierbare Teilcben bildan, entspricht der von anderen mitgeteilten Zeit, in der die Ausscheidungsresktion nach Ausweis von Dtlmpfungsmessuugen zu 70% abgelaufen ist. Bei 156°C WRPdie zur Bildung solcher Teilchen notwondigo Zeit vie1 liinger als die &it, in der die Ausscheidung nach Ausweis van DBmpfungsmessungen vollstiindig abgelaufen ist. Die dendritischen Karbide der Fe-C-Legierungen scheinen sich auf den jli6)-Ebenen des Ferrits auszusaheiden mit Asten ltings { 111 )-Richtungen. In der Eisen-3,250& Sifizium-tegieruug s&&den sich die Karbide in der Form van Iinsenf&migen Seheiben auf den {106)-Ebenen der Ferritmatrix aus. Die Kristallstruktur dieser Ksrbide wurde nicht bestimmt, sie ist aber weder Epsilon no& Zementit. Nach Itigerem Ausfagern werden diese Sehciben durch ~o~~en~enzementit ersetzt. * Received November 13, 1958. t Edgar C. Brain Laboratory for Fundamental Research, United St&es Steel Corporation Research Center, Monroeville, Pennsylvania. ACTA METALLURGICA,
VOL. 7, SEPTEMBER
I359
632
LESLIE,
FISHER
SEN:
AND
MORPHOLOGY
AND
INTRODUCTION
CRYSTAL
STRUCTURE
micrograph*
of Fig.
1.
OF
Electron
The precipitation of carbon from super-saturated ferrite during quench-aging has been a subject of
several years ago of an extraction
considerable
as
interest
for
a number
of
years.
A
Fro. I. Carbides precipitated in 0.02yJ C rimmed steel held 10 min at 705”C, quenched to 425”C, aged 10 min. brinequenched. Picral etch. x 1000.
aged low-carbon plates
actually
a number of discrepancies
In addition,
be resolved. calculated
For example,
to be spherical from
dependence
calculations must
be
appear
of the time during
micrographs purporting to been publish~.(3) Similar
plate-like(4~6~ and electron micrographs to support this view have been pre-
sented.(59g)
reports
been
have been made to show that the particles
which
solution
analysis
have
of the change of internal friction
aging(l12) and electron show this shape have
carbide
t#he carbides
It has been claimed
are precipitated
from
that two forms
super-saturated
in alpha
iron. f7*8~9$3) According cementite (Fe,C) forms during
of
633
mi~ro~aphs
made
replica of a quenchthat
in optical
what
appeared
nlicro~aphs
were
Fm. 2. Grain boundary and dispersed carbides in 0.047& C rimmed steel held 20 min at 72O”C, quenched to S15”C, aged 20 min, brine-quenched. Extraction replica. x 20,000.
review of the numerous papers on this topic shows that have arisen whioh need to
steel showed
or needles
CARBIDES
more complex
shapes,
the electron
particles extracted not compatible
as shown in Fig, 2.
diffraction
patterns
from
from a number of specimens were
with the crystal
strrrcture of epsilon
carbide. These observations, and the conflicting claims in the literature, provided the impetus for a more thorough
investigation
carbon from super-saturated
of the precipitation
of
alpha iron.
As will be described later, improvements in techniques of electron microscopy and diffraction now make it possible to determine
solid
structure
to these aging at
certainty.
of
the
precipitated
the shape and crystal carbides
with
more
about 200°C or above whereas at lower temperatures
In a paper published after this work was completed, Pitsch and Sehrader(20) have reported results similar
epsilon
to part of the work reported here.
(Fe,,,C)
measurements
occurs. indicate
However,
internal
that
precipitation
the
frietion of
carbon from solid solution in ferrite is a single-stage process.(lJ0J” Also, a recent analysis by Harn(l@) has shown precipitation shape
that in general reaction
providing
geometrically
the
the time rate law of a
does not depend upon particle precipitated
particle
similar, in contradiction
remains
to the earlier
suggestion by Zener(lg) which was used in the calculations previously mentioned.
2. MATERIALS
AND
PROCEDURES
The ~ompo~it,ions of the materials used are listed in Table 1. The high-purity iron was obtained in the form of a 25 lb ingot from National poration.
The major
impurity
Research
was 0.033%
Cor-
silicon.
Steel I was an enameling iron in the form of hot-rolled sheet, 0.140 in. thick. Steel P was hot-rolled lowcarbon sheet 0.127 in. thick. Steel A was a hot-rolled silicon steel in the form of sheet 0.110 in. thick.
Many observations, made at this laboratory, of the carbides precipitated in low-carbon steel during quench-aging indicated that these carbides were
A + in. thick slice was cut, perpendicular to the long axis of the high-purity iron ingot, then cold
certainly not spherical (12) but rather, seemed to taka the form of plates or needles, as shown in the optical
* All micrographs reduced approximately ductions.
50% in repro-
ACTA
METALLUXGICA,
TABLE 1. % Composition of materials used
VOL.
Electron
7,
1959
diffraction
patterns
were
obtained
from
particles on these replicas. 3. RESULTS
A.
Precipitate
AND
DISCUSSIONS
morphology
The extraction
replica technique
of electron micro-
scopy is very well suited to the determination _.--
---
--
shape and crystal
* Al. 0.001; N, 0.0013; 0, 0.0057; MO, 0.003.
precipitated
structure
from
solid
solution.
particles are not obscured
of the
of very small particles Details
by shadowing
of
the
and electron
rolled to a thickness of 0.035 in. Strips 1 in. wide were annealed in dry, purified hydrogen at 740°C for
diffraction patterns can be obt,ained without interference from the matrix or from thin surface films.
6 h, then cooled in hydrogen
in the cold zone of the
There are a few inherent
furnace.
carburized
should
They
were
then
in
Hs-CH,
be
limitations,
recognized.
During
the
however,
that
second
etch,
PIG. 3. Dendritic carbides precipitated during aging of Fe-0.014C alloy,brine quenched from 74O"C, aged as noted. Extraction replicas. ~40.000.
mixtures
at 740°C to carbon
0.009 to 0.014%, furnace.
The nitrogen
was 0.0003°/0.
specimens solution
contents
in the range
and cooled in the cold zone of the content
after this treatment
After cutting into smaller sections, the
were sealed treated
at
into
740°C
evacuated for l/2
silica tubes,
hr, then
brine
through the replica, the replica.
More particles
brine quenching.
to use extraction
tion-treated
steels were solu-
for 20 min at 72O”C, then either
quenched to room temperature aging temperature, or quenched
brine
and reheated to the directly to the aging
temperature. The specimens were brine quenched at the end of the aging period. Observations of the microstructure
were made as soon as possible
after
and etched surface,
so
that attempts to determine the density of precipitate from extraction replicas are not justified. During the separation,
low-carbon
sur-
appear than can be seen
on an equal area of polished
quenched. The subsequent aging treatments were done in lead-bismuth baths and were terminated by The two commercial
particles below the original
face may be exposed sufficiently to be pulled off with
the
angular
relationships
between
the
particles may be changed slightly so it is not advisable tions.
replicas
in habit plane determina-
The angles within a given particle,
remain unchanged
however,
by the extraction.
The dendritic shape of the carbide precipitate, as suggested in Fig. 2 can be seen clearly in the micrographs
of
Fig.
3 at higher
magnification.
These
micrographs show the particles in extraction replicas taken of specimens aged at 150” and at 260°C following
aging. Metallographic specimens were polished in the usual manner. Most of the electron observations were made on extraction The etchant used with these replicas was
and etched microscope
directions in the dendrite subtending an angle in the range 68”-73”. A third direction is faintly visible in
repIicas.(r3) picral, with
an addition
per 100 ml.
Fig. 3A, 3B and 3C, subt~n~ng angles of about 50” and 60” with the two principal directions. The branches of the dendrite appear to be made up of
of 2 ml Zephiran
chloride
a brine-quench
from 740°C.
There are two principal
AND
CRYSTAL
following the
STRUCTURE
a quench.
detail
of the
OF
CARBIDES
The shadowing dendrites.
angle between the specimen
635
process obscures
Depending
upon
the
surface and the plane of
the particle, shadowed replicas can give the appearance of either plate-like or spherical particles. The dendritic high-purity employed.
carbides
were observed
smaller for corresponding tures and exhibited comparing
bundles
of narrow
rods.
carbide
will be discussed
dealing
with
electron
particles. The distribution
tion
of
further
are shown
Fig. 7B with Fig 3C.
difference
branching
than
This can be seen by There was no dis-
between the carbides in the two i.e. the difference in manganese
low-carbon steels; content,, 0.05% and 0.520/o, did not seem to influence the size or shape of the carbide particles.
analysis
of
particles
the
is fre-
Typical denuded grain boundary in Figs.
1 and 2.
carbides
These probably
carbides
of this
alloys.
in a later section
diffraction
stringers of the dendritic shown in Fig. 4.
morphology
of the precipitate
quently nonuniform. regions
The
cernible
aging times and tempera-
less extensive
those in the iron-carbon FIG. 4. String of dendritic carbides in Fe-0.014C alloy, quenched from 74O”C, aged 3 min at 250°C. Extraction replica. X 40.000.
both in the
iron-carbon alloys and in the two steels The particles formed in the steels were
along
&ringers were observed
Occasionally
were observed,
as
result from nuclea-
dislocation
lines.
Similar
at earlier stages of precipita-
tion, as shown in Fig. 5, taken from a specimen of the 0.014°/0 carbon iron aged 30 min at 300°C following quench.
The contrast
of the material
deposited
a on
the replica is very low. It is probably carbon from condensed along the dislocation line. “atmospheres” This
material
did
not
give
a crystalline
diffraction pattern. The difficulty of resolving the complex dendritic
particles
by
conventional
electron
shape of the
surface
replica
methods 6A and
is illustrated by the comparison of Figs. 6B. Both micrographs were taken of a
specimen
of O.OOO”/OC iron aged for 1 min at 315°C
Fro. 6. Cornrarison between appearzu~ce of’ rxrbides on a shadowed replica end on an extraction replica. Fe- O.OO!JC alloy, brine-quenched from 74O’C, aged I nlin at 315°C. x 50,000.
In
all the
persisted
over
alloys
examined
the
dendritic
as can be seen in the micrographs
of Fig. 7, covering
aging temperatures from 150” to 524’C. higher aging temperatures the dendrites shorter
and thicker.
persists
even
when
The
characteristic
coalescence
(Fig. 7E). Some of the specimens of aggregates
form
a wide range of aging temperatures,
is well
contained
At the become 70’
angle
advanced,
a small number
such as are shown in Figs. 3B and 8.
These take the form of sets of L-shaped lines. The lines are approximately 30 A wide and 100 A apart. No electron diffraction patterns could be obtained
Fro. 5. An early &age in t’he precipitation of dendritic carbides showing darkened unresolvable areas. Fe-0.014C alloy, brine-quenched from 74O”C, aged 30 min at 200°C. Extraction replica. x 50.000.
from this precipitate. Pitsch(21) has found particles with the same morphology and with the epsilon carbide structure in quench-aged iron--carbon-nitrogen alloys. The presence of such particles in our specimens containing only 0.0003°/0 nitrogen, however,
636
ACTA
METALLURGICA,
VOL.
7,
1959
FIG. 7. Dendritic carbides precipitated in steel I (except A) in the aging temperature range 150”-425°C. Extraction raplicas.
FIG. 8. Carbide aggregate in Fe-O.OSGC alloy, aged 1 hr at 2GO’C. Extraction replica. x 200,000.
FIG. 9. Dendrite and oblong plates of cementite in 0.014% C ferrite, solution treated 74O*C, quenched to 372”C, aged 30 min. Extraction replica. x 55,000.
iA FIG. 10. Electron diffraction pattern of dendritic eementite particle in Fig. 9.
i..
FIG. 11. Indexing of spot pattern cementite structure.
l
on basis of
LESLIE,
FISHER
AND
SEN:
MORPHOLOGY
AND
CRYSTAL
STRUCTURE
OF
CARBIDES
637
FIG. 12. Large dandrkic carbide in Fe-0.096C alloy, held 1 hr at 260°C. Extraction replica. x 200,000.
makes it doubtful
that nitrogen
aging temperature of carbide
is required for their
80 kV.
As a check on the calibration
some diffrac-
tion patterns were taken of particles which had been
formation. When specimens
were quenched
directly
to the
after solution treatment, two forms
were observed.
These take the form
of
shadowed
with gold so that both patterns were super-
imposed.
Using this method the accuracy
is about
l/2 per cent.
However,
dendrites and oblong plates, as shown in Fig. 9. The
in comparing
frequency
and very thin crystals with X-ray diffraction data from bulk samples. The relative intensities of diffrac-
of occurrence
of the two forms
upon the aging temperature. plates were formed
Relatively
depends
few of the
at 315”C, but this form predomi-
nates when the aging temperature is 455°C. Dendrites grown in this manner become quite large. The largest dendrites observed were those separated from the ferritic areas of a high-purity iron specimen carburized to 0.096%
carbon, cooled in the carburizing gas in the
cold zone of the furnace, peratures. reached
The
then aged at various tem-
dendrites
a maximum
length
grown
in
of about
this
manner
1O-3 cm.
One
a great many diffraction
lines will be missing entirely.
This effect is also observed for X-ray diffraction
and is
particularly troublesome in identification of cementite because of the complex structure. The large change in the X-ray
diffraction
progress of tempering
pattern of cementite
during the
has been discussed by Jaokos).
Table 2 lists transmission
electron diffraction
carbides
data
of a sample of the
0.014% carbon iron aged for 100 hr at 100°C. A sufficient number of particles had formed to give a
B. Identi$cution of crystal structure of carbides precipitated from ferrite
powder pattern.
The carbide particles which precipitate during aging from ferrite are too small and too few in number in the samples to be identified by X-ray diffraction However, it was possible to obtain techniques. electron diffraction powder patterns from groups of particles and cross-grating patterns from single particles on extraction replicas. Most of the patterns I operating
data from such small
tion lines may be quite different and if the particle has only a few unit cells along one or even two dimensions
for a group of dendritic
such is shown in Fig. 12.
were taken with a Siemens Elmiskop
electron diffraction
of the data
caution is required
at
Similar patterns were obtained from
a number of other specimens. The data are compared with the standard pattern for cementite and epsilon carbide. These measurements, as well as visual comparison of the actual plates with similar patterns from known cementite and epsilon carbide, leave no doubt that the dendrites are cementite rather than epsilon. Identification
of the powder patterns as cementite
ACTA
638
METALLURGICA,
2. Interplanar spacings (A) for dendr itic: carbides IFeO.O14C, aned 100 hr at 200°C:)
TABLE
Observed spacing
Epsilon carbide?
1Intensity*
>ementite. (Fe&)
(Fe,.&)
2.15
W
k W
1
1.60
:W W
t!]
3.358 2.536 2.371 2.248 2.207 2.098 2.018 1.862 1.679 1.403 1.326 1.189
3.33 2.54 2.40 2.21 2.11 2.02 1.85 1.66 1.40 1.33 1.18
Miller indices of crystal planes
1.36 1.23
002 020 021 200 120 121 022 113 023 024 312 025
VOL.
apparent
7,
1959
in Figs. 3, 6 and 12.
These rods are 35 to
50 A wide, which is only 5 to 7 unit cell distances, so the diffraction
spots are stretched out along the direc-
tions of the branches of the dendrites. Even the large dendrites formed by quenching directly to the aging temperature
or by
gas cooling
temperature
exhibit
this diffraction
W-weak,
solution The
separate crystal although they are all oriented in the same way. The
oblong
following
plates
a quench
temperature
which
directly
during
aging
to an elevated
occur
aging
give an electron diffraction
which can also be interpreted M-medium,
the
streaking.
micrograph of Fig. 12 shows the make-up of such a dendrite. Each rod in the branches diffracts as a
~.._~ ~. * Intensities: S-strong, very weak. t Data from Jack’=‘.
from
VW-
instance the diffraction
pattern
obtained
of cementite
from lamellae
spot pattern
as cementite.
In this
is the same as that formed
during
the growth of pearlite. (13) The direction through the is confirmed by analysis of electron diffraction patterns of single particles.
thin plate is along the c axis of the orthorhombic
Fig. 10 shows the electron diffrac-
The small size and complex
tion pattern of the carbide particle in Fig. 9. Similar electron diffraction patterns were obtained from
habit plane of this precipitate.
dendritic
at least five directions
particles
over
the
full
range
of
aging
temperatures
and times.
This pattern is actually the
superposition
of two patterns at an angle of 70” and
carbide
increase
the
difficulty
of determining The observation
of the precipitate
can be seen
or {ill>
habit planes, unless more than one carbide is
present or more than one habit plane is adopted.
cipal
constant
and
so diffracts
as two
crystals.
During the early stages of growth of the dendrites third direction viously,
is faintly
visible,
as mentioned
but it does not appear to contribute
diffraction
a
preto the
pattern and vanishes as aging progresses.
When the particle
has relatively
few side branches,
the that
in one grain (Fig 1) eliminates the possibility of (100)
is a result of the fact that the dendrite has two prindirections
cell.
shape of the dendritic
70” angle observed
The
between the branches of
the dendrites corresponds to the 70’ 32’ angle between (111) directions
on (110)
paper on this subject,
plane and growth direction. able.
planes.
IIn his
most recent
Pitsch(2a) suggests this habit The choice seems reason-
Fig. 13 is a sketch showing the structure
and
one of the line patterns is very much weaker than the other. With the selected area electron diffraction technique it is possible with the
to relate the crystallographic
dimensions
diffraction
pattern
of the
obtained
section through the reciprocal crystal.
The coordinates
crystal.
direction
The
is equivalent
lattice of the diffracting
of the diffracting
spots may
be equal to the Miller indices of the crystal related to them in a simple manner. shown in Fig. 10 cannot be obtained carbide,
electron
to a plane
or else
The pattern from epsilon
but as shown in the sketch of Fig. 11, it can
be obtained
[ill1 a
from cementite.
The crystal grows with the b axis of the orthorhombic cementite unit cell aligned along the length of branches of the dendrite, the c axis perpendicular to the branches and in the plane of the particle and the a axis aligned through the particle. The streaking of the diffraction
spots along the C* direction is a result
of the fact that the branches of the dendrites are actually a parallel array of very narrow rods, as is
FIG. 13. Orientation
of growth of dendritio cementite ferrite.
in
LESLIE,
FISHER
AND
MORPHOLOGY
SEN:
AND
CRYSTAL
STRUCTURE
OF
CARBIDES
639
PREClP#TATE OBSERVED
FIG 14. Time required for precipitation of dendritic carbide from supersaturated alpha, iron (0.014% C, brine-quenched from 74O”C, reheated to temper&es indicated).
1
0.1
10
to
10 TIME
IN
l0
IO
MINUTES
15. Time required for precipitation of dendritic carbide from two low-carbon steels (brine-quenched from 72O”C, reheated to temperatures indicated).
FIG.
growth orientation of the dendrites. The carbides grow along the b axis of the orthorhombic cell which is the close-packed direction of iron atoms in the cementite structure. This same growth direction is observed for the carbides precipitated during growth of pearlite and bainite.(22) The third direction of growth, faintly visible in several of the figures, and making angles of about 50” and 60’ with the two principal directions, cannot be tt (111) direction.
The time required for precipitation of carbides from solution-treated and brine-quenched alpha iron, contaming 0.014°h carbon, in the temperature range 1.50” to 3WC, is indicated in Fig. 14. The times
required for precipitation of carbides in the two commercial low-carbon steels, at 200’ and 26O”C, are shown in Fig. 15;. The curves are based on the 6rst observation of a clearly defined precipitate on an extraction replica in the electron microscope, These observations were supplemented by the usual techniques of optical microscopy. Results obtained by both procedures agreed well. When clearly defined precipitates were obtained on the replicas, preoipitation could be observed on polished and etched surfaces by light microscopy, although the precipitate could not be resolved. When the time required for formation of the first recognizable precipitate is plotted vs. the reciprocal of the absolute temperature, the slope of the line
640
ACTA
METALLURGICAL
VOL.
7,
1959
0.2-
FIG. 16. Kinetics saturated solution
corresponds
to an aetivation
commonly
energy of 20,100 cal, the
accept.ed value for the activation
for diffusion of carbon in alpha iron. for
observation
however,
of the
is much
relationship. crepancy
of precipitation of carbon from superin alpha iron, as measured by internal friction.
A
The time required
first precipitate
longer
than
possible
energy
at
predicted
explanation
of
15O”C, by
this
this
dis-
is discussed later.
This may on the
replica, even though they are above the limit of resolmion of the microscope, are not recognized as carbides. Another
possibility
is that rate of precipitation
in
the specimens used may differ from those used in the
Very little difference was noted between the rates of precipitation
in the two commercial
considerable
difference
cipitation
of carbon as measured by internal friction.
be due to the fact that very small particles
steels despite the
in manganese
content.
Pre-
internal
friction
perform
both
work. internal
electron microscopy
It
would
friction
he desirable
measurements
to and
on the same specimen.
was slightly more rapid in the high-purity
iron than in either of the two steels, but the difference in solution
tcmperat.ures
makes the comparison
certain. At 2OO*C, a precipitate was observed 15 min in the high purity iron as compared l-2 hr for the steels. It is interesting to compare
unafter with
the cnrves of Figs. 14
and 15 with the data for the rate of precipitation
of
carbon,
in
as measured
by internal
Fig. 16. At 26O”C, a precipitate high-purity internal
iron-carbon
friction
precipitation
alloy
data(n)
is about
friction,
shown
was observed after
2 min.
at 250°C indicate
in the Wert’s
that the
70 per cent completed
after
2 min. At 17O”C, the internal friction measurements of Pitsch and Liickeo*) indicat.e that the precipitation of carbon is completed found
in about 200 min, which was
in this in~estigat,ion
to be about
the time
required to form the first recognizable precipitate. At 15O”C, complete precipitation occurred in about 400 min, according cipitate after
to Pitsch and Liickeo4’,
was observed
10,000 min.
decreases,
the
on extraction
Thus,
formation
as the aging of the
first
precipitate lags behind the completion
but no prereplicas
until
temperature recognizable
of precipitation
FIG. 17. Approximate length of time required for start a,nd for 50 per cent completion of isothermal precipitation of cementite in 0.02% C rimmed steel. Prior solution treatment 10 min at 705”C, quenched directly to the aging temperature.
LESLIE,
FISHER
SEN:
AND
MORPHOLOGY
AND
CRYSTAL
STRUCTURE
OF
CARBIDES
641
FIG. 18. Rate of growth of dendritic carbides at 200°C after quenching from 740°C and reheating (C!=O.O14%).
In discussing carbon
from
rate of isothermal
supersaturated
iron, a distinction
precipitation
solid solution
of
in alpha
must be made between (1) the rate
measured after quenching
from the solution tempera-
ture to room temperature
and reheating
temperature,
and (2) the rate measured after quench-
could be obtained by reflection from the surface of the
This is shown by a comparison directly
is observed
after from
about
740°C
5 set; to
room
A sufficient number of high-purity accurate
this
if the specimen temperature,
is
then
precipitate.
of observations determination
of the rate of
The length of the each aging period
Because of the shape of the particles,
is a measurement
of one-dimensional
sample.
Table 3 lists the interplanar
grain boundary with those
film.
Comparison
of cementite
table, identifies
Fe,C,(i6)
the carbide
also listed in the
film as cement&e.
result agrees with that recently and Leako5). The
occurrence
in silicon
which has a needle-like
spacings of the
of these spacings
reported
steel
appearance
This
by Leak
of a precipitate in a polished and
etched cross section has been observed for many years.
were made of
iron aged at 200°C to allow
growth of the carbide particles. largest particle observed after was measured.
After
bath at dOO”C, about 30 min
is required to form a recognizable
a reasonably
of Fig. 14 with
and Kristufek.02)
from 705” to 2OO”C, a precipitate
placed in a lead-bismuth
samples
from the solu-
The latter is the more rapid of the
Fig. 17 taken from Rickett
quenched
carbides
on an extraction replica, but deep etching left the carbide in relief so that electron diffraction patterns
tion temperature.
quenching
Fig. 19 shows typical grain boundary
to the aging
ing directly to the aging temperature two.
effects.
in a 3.20% Si, 0.01 %C alloy, cooled slowly from 870°C. These grain boundary carbides could not be removed
This precipitate
can be formed by various treatments,
including air cooling from high temperatures, heating to high temperatures followed by an isothermal treatment
in
the
temperature
range
250” to 6OO”C, and brine quenching temperature
followed
by
from
about
from an elevated
an isothermal
treatment.
growth.
The rate can be represented as a logarithmic function of time, as shown in Fig. 18. An extrapolation of the curve indicates
that the length of the particle would
be zero at 10 min which is a good check on the direct observat8ion (Fig. 14). D. Carhides precipitated
from
silicon ferrite
The presence of up to 0.5% manganese appears to have little effect on the kinetics of precipitation or the form of presence
the carbide in iron-carbon alloys. The of silicon, however, produces pronounced
FIG. 19. Grain boundary cementite in 3.20% Hi, 0.01% Picral-nital etch. >: 2000. C alloy, slowly cooled from 870°C.
642
ACTA
TABLE 3. Interplanar
METALLURGICA,
spacings (A) for grain boundary in silicon steel
-.
I
Miller indices of crystal planes
5.072 2.536 1.691 1.268 1.015
010 020 030 040 050
3.75 3.018 2.098 1.539 1.202
101 111 121 131 141
1.87 1.75 1.51 1.25 1.05
1.862 1.756 1.506 1.255 1.052
202 212 222 232 242
1.245 1.23 1.12 1.00
1.250 1.212 1.123 1.005
303 313 323 333
2.54 1.70 1.268 1.016
I
3.74 3.02 2.10 1.54 1.21
I
I
7,
1959
carbide
FeJYG
Observed spacing
VOL.
FIG. 22. Lenticular carbide from steel 1315T to 315”C, held 2 hr. Extraction
A, quenched from replica. x 20,000.
particles are believed to be carbides.
They are found
only
in iron-silicon
alloys
containing
they are displaced by grain boundary after prolonged heating. of round,
lenticular
micrograph
of Fig.
carbon,
and
cementite films
The particles have the shape
disks, as shown in the electron 22.
The
diameter-to-thickness
ratio is about 25 to 1. Fig. 20 is a micrograph of this precipitate
steel was completely The
quenching
Although
their
(at which
temperature
the
ferritic) then air cooled to room relatively
in Fig. 21 were obtained 1315”C,
occurrence
in Steel A, heated in an evacuated
silica capsule to 1315°C temperature.
showing a typical
large
particles
shown
by heating the same steel to
to 315”C, then holding composition
is
for 2 hr.
unknown,
these
Since not more than three directions cipitate
are observed
inferred
that the lenticular
one grain, carbides
of the preit can be
precipitate
clearly defined precipitate directions. The poles of the { lOO}planes of the grain fell on the normals to the traces of the precipitate.
This same observation
was
recently reported by Suits and Low(17). A typical
electron
is shown
diffract,ion
in Fig. 23.
pattern
of a single
The diffraction
spots
20.
FIG. 21.
FIG. 20. Lenticular carbides in steel A, air cooled from 1315°C. Picral-nital etch. x 100. FIG. 21. Lenticular carbides in steel A, quenched from 1315°C to 315”C, held 2 hr. Picral-nital etch. x 2000.
on
(100) planes of the ferrite. This was checked by determining the orientation of a large grain showing
particle
Fm.
within
FIG. 23. Electron diffraction spot pattern obtained from lenticular carbide shadowed with palladium.
LESLIE,
FISHER
\
SEN:
AND
MORPHOLOGY
AND
\a,
TRYSTAL TABLE
STRUCTURE
Observed
4.
0
MEDIUM
Intensity
W M W
1.43
S
form
a square
although
many
missing and others are very weak.
points
Except
are
1.34 1.94
WM WM
for inten-
sity, all points in such a pattern are equivalent
and so
1.47
W
1.56 1.04 1.21
WM W
the innermost spots must be indexed as (030), etc, in order to avoid fractional indices. This is shown in Fig. 24.
The interplanar
accurately palladium the
by shadowing
were determined
an extraction
replica with
so that the electron diffraction
palladium
and
superimposed. be concluded carbon
distances
a
precipitated
that the lenticular
precipitate
cementite
carbide but another carbide of unknown
S-strong,
were
were unsuccessful,
100 200 300 400 500 600 110 220 330 440 120 240 130 260 140 150 230 350 340
4. SUMMARY
spots is
coupled with the observation indicates that the iron
atoms have the same arrangement in the particles as in the ferrite matrix (in directions parallel to the That is, the iron atoms are
coherent on the surface of the particle;
account
for the lenticular
this
and electron of existing
The relatively
of the diffraction
spots
confirmed
from carbon atoms is too weak to be observed.
The
other possibility is that the crystal structure of the precipitate is actually complex with a large unit cell
concerning
the
supersaturated
solid
Some of the previous
inter-
techniques
by the observations
supersaturated
dendrites,
oblong
precipitate
This might
from
The carbides precipitated
may
reflections.
carbon
has led to the
used.
Calcula-
tion of particle shape from rate of precipitation has recently been shown to be fallacious,d*) and this is
parallel
be due to superlattice
diffraction
in alpha iron.
other than those already mentioned suggests that they indicate that the precipitate contains silicon atoms in an ordered arrangement, inasmuch as the scattering
of
CONCLUSIONS
discrepancies
tions of the experimental
of low intensity
of silicon in the
pretations(3T5yg) were erroneous because of the limita-
shape of even the
largest particles.
AND
clarification solution
could
I
of improved techniques of electron
microscopy
iron.
probably
I
W.M-media-weak
but the presence
The development
composition
precipitation
surface of the particle).
,I
in low-
the same as the (110) and the (200) spacings in alpha This observation,
M-medium,
I
carbide was indicated.
nor epsilon
and structure. The spacing of the most intense diffraction
that the habit plane is {loo},
for
-
pattern of
particle
The data are listed in Table 4. It can
silicon steel is neither
Intensities: W-weak.
1
6.06 3.03 2.02 1.515 1.212 1.01 4.28 2.14 1.427 1.07 2.67 1.335 1.938 0.969 1.468 1.19 1.563 1.038 1.212
of spot pattern of Fig. 23.
network
spa&es
Co-ordinates of diffraction spots
S
2.02 1.515 1.212 1.01
643
Calculated spacing
<-;MISSING FIG. 24. Indexing
CARBIDES
and calculated interplanar lenticular carbides _
06
Observed spacing
OF
lines
have
alpha
iron
take
plates
and
L-shaped
been
observed.
in the temperature
they are the predominant tures.
reported herein.
during the quench aging several The
forms;
arrays
of
dendrites
range 150”-48O”C,
and
form at the lower tempera-
The oblong plates predominate
at temperatures
above about 400°C. Both forms appear to be cementite, Fe.&. The branches of the dendrites seem to be
so that it contains a number of planes with a very low density of atoms. Although the square array of
made up of bundles of thin cementite rods. These branches have two principal directions of growth, with an angle of 70” between them, and a third minor
diffraction spots suggests a cubic or tetragonal structure, these are unlikely because of the large number of omissions in the pattern.
direction. No indication was found of the presence of epsilon carbide. However, no diffraction patterns could be
Attempts to determine the silicon content of the particles by use of the electron probe microanalyzer
is unknown.
obtained from the L-shaped arrays, and their structure
ACTA
644
At low aging temperatures,
METALLURGICA,
the rate of precipita-
VOL.
7,
1959
Smith and J. C. Swartz for their help in other phases
tion, measured by electron and optical metallography,
of the work, and to R. L. Rickett for suggestions which
is much slower than the rate of precipitation
led to the investigation.
by internal friction. to
an inability
This disagreement
to
recognize
particles
on extraction
specimen
composition
very
replicas
measured
may be due
fine precipitate
or to differences
and history,
in
solution tempera-
ture, and aging procedure. The habit
planes
of Fe&
precipitated
from
un-
alloyed alpha iron are probably { 1 lo},. The principal directions of growth in this plane are (ill),. A third minor direction
of growth remains unknown.
The presence of up to 0.5% effect
upon
the morphology,
or habit, of the carbides but the presence of 3.25% effect.
manganese
has little
rate of precipitation,
precipitated
from
ferrite,
silicon has a pronounced
The carbides precipitated
during aging of the
iron-carbon-silicon alloy take the form of lenticular disks on (100) planes of the ferrite. The crystal structure
of these carbides is unknown,
neither cementite
but they are
(Fe.&) nor epsilon carbide
(Fe,,,C).
ACKNOWLEDGMENT
The
thanks
of
the
authors
Szirmae for the preparation micrographs,
are
due
to
Albert
of many excellent electron
to C. P. Stroble,
K. G. Carroll, R. P.
REFERENCES 1. C. WERT, J. Appl. Phys. 20, 943 (1949). 2. C. WERT and C. ZENER, Ibid. 21, 5 (1950). 3. J. RADAVICH and C. WERT. Ibid. 22. 367 (1951). a. W. PITSCH, Acta Met. 3, 542 (1955).’ ’ 5. W. PITSCH, Ibid. 5, 175 (1957). 6. R. H. DOREMUS, Ibid. 5, 393 (1957). 7. A, L. Tsou, J. NUTTING and J. W. MENTER, J. Iron St.Ist.172,163 (1952). 8. 0. KRISEMENT, A&iv Pys. 7, 353 (1955). 9. G. LAGERBERG and B. S. LEMENT, Trans. Amer. Sot. Metals 50,141 (1958). 10. L. J. DIJKSTRA, Tmns. Amer. Inst. Min. (Metall.) Engre. 185, 252 (1949). 11. C. WERT, Thermodynamics in Physical Metallurgy, p. 178. American Society for Metals, Cleveland, Ohio (1950). 12. R. L. RICKETT and F. C. KRISTUI~EK, Trans. Amer.Soc. Metals 41, 1113 (1949). 13. R. M. FISHER, Symposium. 0% Techniques for ElectTon Microscopy. ASTM (1953). 14. W. PITSCH and K. LOCKE, Arch. Eisenhiittenw. 27, 45 (1956). 15. D. A. LEAK and G. M. LEAK, J. Iron St. Inst. 189,256 (1958). 16. K. H. JACK, J. Ivon St. Inst. 169,26 (1951). 17. J. C. SUITS and J. R. Low. JR., Acta Met. 5. 285 (1957). 18. F. S. HAM. J. Phvs. Chem. Solids 6. 335 (1958). 19. C. ZENER,‘J. Ap& Phys. 20, 950 ii949).‘ 20. W. PITSCH and A. SCHRADER, Arch. Eisenhiittenw. 29, 485 (1958). 21. W. PI~sca. Private Communication. 22. R. M. FISHER, 4th International Congress on Electron Microscopy, Berlin (September 1958). 23. F. W. C. BOSWELL, Actu Cryst., Camb. 11, 51 (1958).
AND CRYSTAL STRUCTURE OF CARBIDES FROM SOLID SOLUTION IN ALPHA IRON*
W, C. LESLIE,P
R
M. FISHER?
and N. SENf
The carbides precipitated from solid solution in high-purity iron-carbon alloys, in two low-carbon steels and in an iron-carbon-3.25% silicon allay were studied by electron microscopy and diffraction. In the iron-carbon alloy and in the two low-carbon steels the carbide precipitates in a dendritic form during aging following quenching. In specimens quenched directly to the aging temperature oblong plates appeared, along with dendrites. Both of these forms are cementite (FE&) and no diffraction evidence of precipitation of epsilon carbide was found. The time required for formation of identi~able particles at 260°C corresponds to the time reported by others for 76 per cent aompbtion of the precipitation reaction, as memured by internal friction. At 150°C the time required for form&ion of such particles was much longer t&m the time for completion of precipitation, as measured by internal friction. The dendritic carbides in Fe-C alloys &ppea,rto p~cipitat~ on (110) planes of ferrite, with brnnches along (11 I> directions. In the iron-3.25% silicon alloy the carbides take t,he form of lentieular disks precipitated on
ET STRUCTURE CRISTALLINE DES CARBURES PARTIR D’UNE SOLUTION SOLIDE DE FER cc
PRECIPITES
A
-4 l’aide de la microscopic et de la diffraction Blectroniques, les auteurs ant etudie les carbures preeipitbs & pertir de la solution solids dans des a&ages fer-carbone de t&s haute pm&+, dans deuaz zmicrsk bas carbone et dans un &age fer-carbone-3,25% silicium. Dsns l’&sge Fe-C et dens les deux seiors It bas earbone, Its carbums pritcipitent sous une form% dendritique pendttnt le vieiflissement ~pr&s trempe. Dans tes Bchantillons tramp& directement B la temperature de vieilfissement, epparaissent des plaquettee oblongues en m&me temps que des dendrites. Ces deux formes sont const&ubes par la c&nentite (Fe&) et b diffraction ne r&v&? aucune trace de carbure E. Le temps necessaire 8, la, formation de psxticules identi~abl0a k 25O’C correspond au temps mesu& pm frnttement interne et requis pour que la precipitation soit r&&s& ii 76 per cent. Au contraire 2r 156”C, 1%temps r&&if k la formation de ces particules est beaucoup plus long que eelui indique par le frottement interne pour le d~roulem~nt eomplet de la pr&ipitation. Len carbures dendritiques dans les allixges Fe-C precipitent sur fes plans {l 101 de la ferrite, &vec des ramifications le long des directions {ill). Dans l’alliage Fe-C-3,255(/, Si, les carbures prennent la forme de disques lenticulniresprecipitant sur les plans (100) de la matrice ferritique. La structure cristalline bien que non d&ermintie, ne peut etre celle du citrbura E ni de la cementite. Au come d’un vieillissement prolong& ces disques sont deplaces par des films de cementite le long des joints de grains. ~~ORPHOL~GIE
UND KRISTALLS~~UKT~~ VON KA~,~ID~~USS~H~IDUNGEN A~P~A~~ISEN-MIS~HK~ISTAL~~N
-4US
Die K~rbid~usseheidungen sue ~is~hkrist&llen von hu~ll~einen risen-Kohlensto~egierun~en, zwei kohl~~toffarInen Stithlen und einer Eisen-Kohlenstoff-3,25°/~ Silizium-Le~~~g wurden mit dem ~lektronenmikroskop und mit ~lektronen~u~ng untsrsucht. Aus der Eisen-KohlenstoffLegierung und mxsden zwei kohlanstoffa,rmen Stiihlen scheidet sich das Karbid w&hrend des Auslagerns nach dem Absehreeken in dendritisaher Form aus. In Proben, die direkt auf die Auslagerungstemperatur abgesehreckt worden waren, erschienen l&ngliehe Pliittehen ~~~~rnrnenmit Dendriten. Bcide Formen sind Zementit (Fe&) und die Bougungs~ufnahmeu g&en keinen Hinweis auf die Ausseheidung von Epsilon-Karbid. Die Zeit, die bei 250°C notwendig ist, damit sich identifizierbare Teilcben bildan, entspricht der von anderen mitgeteilten Zeit, in der die Ausscheidungsresktion nach Ausweis von Dtlmpfungsmessuugen zu 70% abgelaufen ist. Bei 156°C WRPdie zur Bildung solcher Teilchen notwondigo Zeit vie1 liinger als die &it, in der die Ausscheidung nach Ausweis van DBmpfungsmessungen vollstiindig abgelaufen ist. Die dendritischen Karbide der Fe-C-Legierungen scheinen sich auf den jli6)-Ebenen des Ferrits auszusaheiden mit Asten ltings { 111 )-Richtungen. In der Eisen-3,250& Sifizium-tegieruug s&&den sich die Karbide in der Form van Iinsenf&migen Seheiben auf den {106)-Ebenen der Ferritmatrix aus. Die Kristallstruktur dieser Ksrbide wurde nicht bestimmt, sie ist aber weder Epsilon no& Zementit. Nach Itigerem Ausfagern werden diese Sehciben durch ~o~~en~enzementit ersetzt. * Received November 13, 1958. t Edgar C. Brain Laboratory for Fundamental Research, United St&es Steel Corporation Research Center, Monroeville, Pennsylvania. ACTA METALLURGICA,
VOL. 7, SEPTEMBER
I359
632
LESLIE,
FISHER
SEN:
AND
MORPHOLOGY
AND
INTRODUCTION
CRYSTAL
STRUCTURE
micrograph*
of Fig.
1.
OF
Electron
The precipitation of carbon from super-saturated ferrite during quench-aging has been a subject of
several years ago of an extraction
considerable
as
interest
for
a number
of
years.
A
Fro. I. Carbides precipitated in 0.02yJ C rimmed steel held 10 min at 705”C, quenched to 425”C, aged 10 min. brinequenched. Picral etch. x 1000.
aged low-carbon plates
actually
a number of discrepancies
In addition,
be resolved. calculated
For example,
to be spherical from
dependence
calculations must
be
appear
of the time during
micrographs purporting to been publish~.(3) Similar
plate-like(4~6~ and electron micrographs to support this view have been pre-
sented.(59g)
reports
been
have been made to show that the particles
which
solution
analysis
have
of the change of internal friction
aging(l12) and electron show this shape have
carbide
t#he carbides
It has been claimed
are precipitated
from
that two forms
super-saturated
in alpha
iron. f7*8~9$3) According cementite (Fe,C) forms during
of
633
mi~ro~aphs
made
replica of a quenchthat
in optical
what
appeared
nlicro~aphs
were
Fm. 2. Grain boundary and dispersed carbides in 0.047& C rimmed steel held 20 min at 72O”C, quenched to S15”C, aged 20 min, brine-quenched. Extraction replica. x 20,000.
review of the numerous papers on this topic shows that have arisen whioh need to
steel showed
or needles
CARBIDES
more complex
shapes,
the electron
particles extracted not compatible
as shown in Fig, 2.
diffraction
patterns
from
from a number of specimens were
with the crystal
strrrcture of epsilon
carbide. These observations, and the conflicting claims in the literature, provided the impetus for a more thorough
investigation
carbon from super-saturated
of the precipitation
of
alpha iron.
As will be described later, improvements in techniques of electron microscopy and diffraction now make it possible to determine
solid
structure
to these aging at
certainty.
of
the
precipitated
the shape and crystal carbides
with
more
about 200°C or above whereas at lower temperatures
In a paper published after this work was completed, Pitsch and Sehrader(20) have reported results similar
epsilon
to part of the work reported here.
(Fe,,,C)
measurements
occurs. indicate
However,
internal
that
precipitation
the
frietion of
carbon from solid solution in ferrite is a single-stage process.(lJ0J” Also, a recent analysis by Harn(l@) has shown precipitation shape
that in general reaction
providing
geometrically
the
the time rate law of a
does not depend upon particle precipitated
particle
similar, in contradiction
remains
to the earlier
suggestion by Zener(lg) which was used in the calculations previously mentioned.
2. MATERIALS
AND
PROCEDURES
The ~ompo~it,ions of the materials used are listed in Table 1. The high-purity iron was obtained in the form of a 25 lb ingot from National poration.
The major
impurity
Research
was 0.033%
Cor-
silicon.
Steel I was an enameling iron in the form of hot-rolled sheet, 0.140 in. thick. Steel P was hot-rolled lowcarbon sheet 0.127 in. thick. Steel A was a hot-rolled silicon steel in the form of sheet 0.110 in. thick.
Many observations, made at this laboratory, of the carbides precipitated in low-carbon steel during quench-aging indicated that these carbides were
A + in. thick slice was cut, perpendicular to the long axis of the high-purity iron ingot, then cold
certainly not spherical (12) but rather, seemed to taka the form of plates or needles, as shown in the optical
* All micrographs reduced approximately ductions.
50% in repro-
ACTA
METALLUXGICA,
TABLE 1. % Composition of materials used
VOL.
Electron
7,
1959
diffraction
patterns
were
obtained
from
particles on these replicas. 3. RESULTS
A.
Precipitate
AND
DISCUSSIONS
morphology
The extraction
replica technique
of electron micro-
scopy is very well suited to the determination _.--
---
--
shape and crystal
* Al. 0.001; N, 0.0013; 0, 0.0057; MO, 0.003.
precipitated
structure
from
solid
solution.
particles are not obscured
of the
of very small particles Details
by shadowing
of
the
and electron
rolled to a thickness of 0.035 in. Strips 1 in. wide were annealed in dry, purified hydrogen at 740°C for
diffraction patterns can be obt,ained without interference from the matrix or from thin surface films.
6 h, then cooled in hydrogen
in the cold zone of the
There are a few inherent
furnace.
carburized
should
They
were
then
in
Hs-CH,
be
limitations,
recognized.
During
the
however,
that
second
etch,
PIG. 3. Dendritic carbides precipitated during aging of Fe-0.014C alloy,brine quenched from 74O"C, aged as noted. Extraction replicas. ~40.000.
mixtures
at 740°C to carbon
0.009 to 0.014%, furnace.
The nitrogen
was 0.0003°/0.
specimens solution
contents
in the range
and cooled in the cold zone of the content
after this treatment
After cutting into smaller sections, the
were sealed treated
at
into
740°C
evacuated for l/2
silica tubes,
hr, then
brine
through the replica, the replica.
More particles
brine quenching.
to use extraction
tion-treated
steels were solu-
for 20 min at 72O”C, then either
quenched to room temperature aging temperature, or quenched
brine
and reheated to the directly to the aging
temperature. The specimens were brine quenched at the end of the aging period. Observations of the microstructure
were made as soon as possible
after
and etched surface,
so
that attempts to determine the density of precipitate from extraction replicas are not justified. During the separation,
low-carbon
sur-
appear than can be seen
on an equal area of polished
quenched. The subsequent aging treatments were done in lead-bismuth baths and were terminated by The two commercial
particles below the original
face may be exposed sufficiently to be pulled off with
the
angular
relationships
between
the
particles may be changed slightly so it is not advisable tions.
replicas
in habit plane determina-
The angles within a given particle,
remain unchanged
however,
by the extraction.
The dendritic shape of the carbide precipitate, as suggested in Fig. 2 can be seen clearly in the micrographs
of
Fig.
3 at higher
magnification.
These
micrographs show the particles in extraction replicas taken of specimens aged at 150” and at 260°C following
aging. Metallographic specimens were polished in the usual manner. Most of the electron observations were made on extraction The etchant used with these replicas was
and etched microscope
directions in the dendrite subtending an angle in the range 68”-73”. A third direction is faintly visible in
repIicas.(r3) picral, with
an addition
per 100 ml.
Fig. 3A, 3B and 3C, subt~n~ng angles of about 50” and 60” with the two principal directions. The branches of the dendrite appear to be made up of
of 2 ml Zephiran
chloride
a brine-quench
from 740°C.
There are two principal
AND
CRYSTAL
following the
STRUCTURE
a quench.
detail
of the
OF
CARBIDES
The shadowing dendrites.
angle between the specimen
635
process obscures
Depending
upon
the
surface and the plane of
the particle, shadowed replicas can give the appearance of either plate-like or spherical particles. The dendritic high-purity employed.
carbides
were observed
smaller for corresponding tures and exhibited comparing
bundles
of narrow
rods.
carbide
will be discussed
dealing
with
electron
particles. The distribution
tion
of
further
are shown
Fig. 7B with Fig 3C.
difference
branching
than
This can be seen by There was no dis-
between the carbides in the two i.e. the difference in manganese
low-carbon steels; content,, 0.05% and 0.520/o, did not seem to influence the size or shape of the carbide particles.
analysis
of
particles
the
is fre-
Typical denuded grain boundary in Figs.
1 and 2.
carbides
These probably
carbides
of this
alloys.
in a later section
diffraction
stringers of the dendritic shown in Fig. 4.
morphology
of the precipitate
quently nonuniform. regions
The
cernible
aging times and tempera-
less extensive
those in the iron-carbon FIG. 4. String of dendritic carbides in Fe-0.014C alloy, quenched from 74O”C, aged 3 min at 250°C. Extraction replica. X 40.000.
both in the
iron-carbon alloys and in the two steels The particles formed in the steels were
along
&ringers were observed
Occasionally
were observed,
as
result from nuclea-
dislocation
lines.
Similar
at earlier stages of precipita-
tion, as shown in Fig. 5, taken from a specimen of the 0.014°/0 carbon iron aged 30 min at 300°C following quench.
The contrast
of the material
deposited
a on
the replica is very low. It is probably carbon from condensed along the dislocation line. “atmospheres” This
material
did
not
give
a crystalline
diffraction pattern. The difficulty of resolving the complex dendritic
particles
by
conventional
electron
shape of the
surface
replica
methods 6A and
is illustrated by the comparison of Figs. 6B. Both micrographs were taken of a
specimen
of O.OOO”/OC iron aged for 1 min at 315°C
Fro. 6. Cornrarison between appearzu~ce of’ rxrbides on a shadowed replica end on an extraction replica. Fe- O.OO!JC alloy, brine-quenched from 74O’C, aged I nlin at 315°C. x 50,000.
In
all the
persisted
over
alloys
examined
the
dendritic
as can be seen in the micrographs
of Fig. 7, covering
aging temperatures from 150” to 524’C. higher aging temperatures the dendrites shorter
and thicker.
persists
even
when
The
characteristic
coalescence
(Fig. 7E). Some of the specimens of aggregates
form
a wide range of aging temperatures,
is well
contained
At the become 70’
angle
advanced,
a small number
such as are shown in Figs. 3B and 8.
These take the form of sets of L-shaped lines. The lines are approximately 30 A wide and 100 A apart. No electron diffraction patterns could be obtained
Fro. 5. An early &age in t’he precipitation of dendritic carbides showing darkened unresolvable areas. Fe-0.014C alloy, brine-quenched from 74O”C, aged 30 min at 200°C. Extraction replica. x 50.000.
from this precipitate. Pitsch(21) has found particles with the same morphology and with the epsilon carbide structure in quench-aged iron--carbon-nitrogen alloys. The presence of such particles in our specimens containing only 0.0003°/0 nitrogen, however,
636
ACTA
METALLURGICA,
VOL.
7,
1959
FIG. 7. Dendritic carbides precipitated in steel I (except A) in the aging temperature range 150”-425°C. Extraction raplicas.
FIG. 8. Carbide aggregate in Fe-O.OSGC alloy, aged 1 hr at 2GO’C. Extraction replica. x 200,000.
FIG. 9. Dendrite and oblong plates of cementite in 0.014% C ferrite, solution treated 74O*C, quenched to 372”C, aged 30 min. Extraction replica. x 55,000.
iA FIG. 10. Electron diffraction pattern of dendritic eementite particle in Fig. 9.
i..
FIG. 11. Indexing of spot pattern cementite structure.
l
on basis of
LESLIE,
FISHER
AND
SEN:
MORPHOLOGY
AND
CRYSTAL
STRUCTURE
OF
CARBIDES
637
FIG. 12. Large dandrkic carbide in Fe-0.096C alloy, held 1 hr at 260°C. Extraction replica. x 200,000.
makes it doubtful
that nitrogen
aging temperature of carbide
is required for their
80 kV.
As a check on the calibration
some diffrac-
tion patterns were taken of particles which had been
formation. When specimens
were quenched
directly
to the
after solution treatment, two forms
were observed.
These take the form
of
shadowed
with gold so that both patterns were super-
imposed.
Using this method the accuracy
is about
l/2 per cent.
However,
dendrites and oblong plates, as shown in Fig. 9. The
in comparing
frequency
and very thin crystals with X-ray diffraction data from bulk samples. The relative intensities of diffrac-
of occurrence
of the two forms
upon the aging temperature. plates were formed
Relatively
depends
few of the
at 315”C, but this form predomi-
nates when the aging temperature is 455°C. Dendrites grown in this manner become quite large. The largest dendrites observed were those separated from the ferritic areas of a high-purity iron specimen carburized to 0.096%
carbon, cooled in the carburizing gas in the
cold zone of the furnace, peratures. reached
The
then aged at various tem-
dendrites
a maximum
length
grown
in
of about
this
manner
1O-3 cm.
One
a great many diffraction
lines will be missing entirely.
This effect is also observed for X-ray diffraction
and is
particularly troublesome in identification of cementite because of the complex structure. The large change in the X-ray
diffraction
progress of tempering
pattern of cementite
during the
has been discussed by Jaokos).
Table 2 lists transmission
electron diffraction
carbides
data
of a sample of the
0.014% carbon iron aged for 100 hr at 100°C. A sufficient number of particles had formed to give a
B. Identi$cution of crystal structure of carbides precipitated from ferrite
powder pattern.
The carbide particles which precipitate during aging from ferrite are too small and too few in number in the samples to be identified by X-ray diffraction However, it was possible to obtain techniques. electron diffraction powder patterns from groups of particles and cross-grating patterns from single particles on extraction replicas. Most of the patterns I operating
data from such small
tion lines may be quite different and if the particle has only a few unit cells along one or even two dimensions
for a group of dendritic
such is shown in Fig. 12.
were taken with a Siemens Elmiskop
electron diffraction
of the data
caution is required
at
Similar patterns were obtained from
a number of other specimens. The data are compared with the standard pattern for cementite and epsilon carbide. These measurements, as well as visual comparison of the actual plates with similar patterns from known cementite and epsilon carbide, leave no doubt that the dendrites are cementite rather than epsilon. Identification
of the powder patterns as cementite
ACTA
638
METALLURGICA,
2. Interplanar spacings (A) for dendr itic: carbides IFeO.O14C, aned 100 hr at 200°C:)
TABLE
Observed spacing
Epsilon carbide?
1Intensity*
>ementite. (Fe&)
(Fe,.&)
2.15
W
k W
1
1.60
:W W
t!]
3.358 2.536 2.371 2.248 2.207 2.098 2.018 1.862 1.679 1.403 1.326 1.189
3.33 2.54 2.40 2.21 2.11 2.02 1.85 1.66 1.40 1.33 1.18
Miller indices of crystal planes
1.36 1.23
002 020 021 200 120 121 022 113 023 024 312 025
VOL.
apparent
7,
1959
in Figs. 3, 6 and 12.
These rods are 35 to
50 A wide, which is only 5 to 7 unit cell distances, so the diffraction
spots are stretched out along the direc-
tions of the branches of the dendrites. Even the large dendrites formed by quenching directly to the aging temperature
or by
gas cooling
temperature
exhibit
this diffraction
W-weak,
solution The
separate crystal although they are all oriented in the same way. The
oblong
following
plates
a quench
temperature
which
directly
during
aging
to an elevated
occur
aging
give an electron diffraction
which can also be interpreted M-medium,
the
streaking.
micrograph of Fig. 12 shows the make-up of such a dendrite. Each rod in the branches diffracts as a
~.._~ ~. * Intensities: S-strong, very weak. t Data from Jack’=‘.
from
VW-
instance the diffraction
pattern
obtained
of cementite
from lamellae
spot pattern
as cementite.
In this
is the same as that formed
during
the growth of pearlite. (13) The direction through the is confirmed by analysis of electron diffraction patterns of single particles.
thin plate is along the c axis of the orthorhombic
Fig. 10 shows the electron diffrac-
The small size and complex
tion pattern of the carbide particle in Fig. 9. Similar electron diffraction patterns were obtained from
habit plane of this precipitate.
dendritic
at least five directions
particles
over
the
full
range
of
aging
temperatures
and times.
This pattern is actually the
superposition
of two patterns at an angle of 70” and
carbide
increase
the
difficulty
of determining The observation
of the precipitate
can be seen
or {ill>
habit planes, unless more than one carbide is
present or more than one habit plane is adopted.
cipal
constant
and
so diffracts
as two
crystals.
During the early stages of growth of the dendrites third direction viously,
is faintly
visible,
as mentioned
but it does not appear to contribute
diffraction
a
preto the
pattern and vanishes as aging progresses.
When the particle
has relatively
few side branches,
the that
in one grain (Fig 1) eliminates the possibility of (100)
is a result of the fact that the dendrite has two prindirections
cell.
shape of the dendritic
70” angle observed
The
between the branches of
the dendrites corresponds to the 70’ 32’ angle between (111) directions
on (110)
paper on this subject,
plane and growth direction. able.
planes.
IIn his
most recent
Pitsch(2a) suggests this habit The choice seems reason-
Fig. 13 is a sketch showing the structure
and
one of the line patterns is very much weaker than the other. With the selected area electron diffraction technique it is possible with the
to relate the crystallographic
dimensions
diffraction
pattern
of the
obtained
section through the reciprocal crystal.
The coordinates
crystal.
direction
The
is equivalent
lattice of the diffracting
of the diffracting
spots may
be equal to the Miller indices of the crystal related to them in a simple manner. shown in Fig. 10 cannot be obtained carbide,
electron
to a plane
or else
The pattern from epsilon
but as shown in the sketch of Fig. 11, it can
be obtained
[ill1 a
from cementite.
The crystal grows with the b axis of the orthorhombic cementite unit cell aligned along the length of branches of the dendrite, the c axis perpendicular to the branches and in the plane of the particle and the a axis aligned through the particle. The streaking of the diffraction
spots along the C* direction is a result
of the fact that the branches of the dendrites are actually a parallel array of very narrow rods, as is
FIG. 13. Orientation
of growth of dendritio cementite ferrite.
in
LESLIE,
FISHER
AND
MORPHOLOGY
SEN:
AND
CRYSTAL
STRUCTURE
OF
CARBIDES
639
PREClP#TATE OBSERVED
FIG 14. Time required for precipitation of dendritic carbide from supersaturated alpha, iron (0.014% C, brine-quenched from 74O”C, reheated to temper&es indicated).
1
0.1
10
to
10 TIME
IN
l0
IO
MINUTES
15. Time required for precipitation of dendritic carbide from two low-carbon steels (brine-quenched from 72O”C, reheated to temperatures indicated).
FIG.
growth orientation of the dendrites. The carbides grow along the b axis of the orthorhombic cell which is the close-packed direction of iron atoms in the cementite structure. This same growth direction is observed for the carbides precipitated during growth of pearlite and bainite.(22) The third direction of growth, faintly visible in several of the figures, and making angles of about 50” and 60’ with the two principal directions, cannot be tt (111) direction.
The time required for precipitation of carbides from solution-treated and brine-quenched alpha iron, contaming 0.014°h carbon, in the temperature range 1.50” to 3WC, is indicated in Fig. 14. The times
required for precipitation of carbides in the two commercial low-carbon steels, at 200’ and 26O”C, are shown in Fig. 15;. The curves are based on the 6rst observation of a clearly defined precipitate on an extraction replica in the electron microscope, These observations were supplemented by the usual techniques of optical microscopy. Results obtained by both procedures agreed well. When clearly defined precipitates were obtained on the replicas, preoipitation could be observed on polished and etched surfaces by light microscopy, although the precipitate could not be resolved. When the time required for formation of the first recognizable precipitate is plotted vs. the reciprocal of the absolute temperature, the slope of the line
640
ACTA
METALLURGICAL
VOL.
7,
1959
0.2-
FIG. 16. Kinetics saturated solution
corresponds
to an aetivation
commonly
energy of 20,100 cal, the
accept.ed value for the activation
for diffusion of carbon in alpha iron. for
observation
however,
of the
is much
relationship. crepancy
of precipitation of carbon from superin alpha iron, as measured by internal friction.
A
The time required
first precipitate
longer
than
possible
energy
at
predicted
explanation
of
15O”C, by
this
this
dis-
is discussed later.
This may on the
replica, even though they are above the limit of resolmion of the microscope, are not recognized as carbides. Another
possibility
is that rate of precipitation
in
the specimens used may differ from those used in the
Very little difference was noted between the rates of precipitation
in the two commercial
considerable
difference
cipitation
of carbon as measured by internal friction.
be due to the fact that very small particles
steels despite the
in manganese
content.
Pre-
internal
friction
perform
both
work. internal
electron microscopy
It
would
friction
he desirable
measurements
to and
on the same specimen.
was slightly more rapid in the high-purity
iron than in either of the two steels, but the difference in solution
tcmperat.ures
makes the comparison
certain. At 2OO*C, a precipitate was observed 15 min in the high purity iron as compared l-2 hr for the steels. It is interesting to compare
unafter with
the cnrves of Figs. 14
and 15 with the data for the rate of precipitation
of
carbon,
in
as measured
by internal
Fig. 16. At 26O”C, a precipitate high-purity internal
iron-carbon
friction
precipitation
alloy
data(n)
is about
friction,
shown
was observed after
2 min.
at 250°C indicate
in the Wert’s
that the
70 per cent completed
after
2 min. At 17O”C, the internal friction measurements of Pitsch and Liickeo*) indicat.e that the precipitation of carbon is completed found
in about 200 min, which was
in this in~estigat,ion
to be about
the time
required to form the first recognizable precipitate. At 15O”C, complete precipitation occurred in about 400 min, according cipitate after
to Pitsch and Liickeo4’,
was observed
10,000 min.
decreases,
the
on extraction
Thus,
formation
as the aging of the
first
precipitate lags behind the completion
but no prereplicas
until
temperature recognizable
of precipitation
FIG. 17. Approximate length of time required for start a,nd for 50 per cent completion of isothermal precipitation of cementite in 0.02% C rimmed steel. Prior solution treatment 10 min at 705”C, quenched directly to the aging temperature.
LESLIE,
FISHER
SEN:
AND
MORPHOLOGY
AND
CRYSTAL
STRUCTURE
OF
CARBIDES
641
FIG. 18. Rate of growth of dendritic carbides at 200°C after quenching from 740°C and reheating (C!=O.O14%).
In discussing carbon
from
rate of isothermal
supersaturated
iron, a distinction
precipitation
solid solution
of
in alpha
must be made between (1) the rate
measured after quenching
from the solution tempera-
ture to room temperature
and reheating
temperature,
and (2) the rate measured after quench-
could be obtained by reflection from the surface of the
This is shown by a comparison directly
is observed
after from
about
740°C
5 set; to
room
A sufficient number of high-purity accurate
this
if the specimen temperature,
is
then
precipitate.
of observations determination
of the rate of
The length of the each aging period
Because of the shape of the particles,
is a measurement
of one-dimensional
sample.
Table 3 lists the interplanar
grain boundary with those
film.
Comparison
of cementite
table, identifies
Fe,C,(i6)
the carbide
also listed in the
film as cement&e.
result agrees with that recently and Leako5). The
occurrence
in silicon
which has a needle-like
spacings of the
of these spacings
reported
steel
appearance
This
by Leak
of a precipitate in a polished and
etched cross section has been observed for many years.
were made of
iron aged at 200°C to allow
growth of the carbide particles. largest particle observed after was measured.
After
bath at dOO”C, about 30 min
is required to form a recognizable
a reasonably
of Fig. 14 with
and Kristufek.02)
from 705” to 2OO”C, a precipitate
placed in a lead-bismuth
samples
from the solu-
The latter is the more rapid of the
Fig. 17 taken from Rickett
quenched
carbides
on an extraction replica, but deep etching left the carbide in relief so that electron diffraction patterns
tion temperature.
quenching
Fig. 19 shows typical grain boundary
to the aging
ing directly to the aging temperature two.
effects.
in a 3.20% Si, 0.01 %C alloy, cooled slowly from 870°C. These grain boundary carbides could not be removed
This precipitate
can be formed by various treatments,
including air cooling from high temperatures, heating to high temperatures followed by an isothermal treatment
in
the
temperature
range
250” to 6OO”C, and brine quenching temperature
followed
by
from
about
from an elevated
an isothermal
treatment.
growth.
The rate can be represented as a logarithmic function of time, as shown in Fig. 18. An extrapolation of the curve indicates
that the length of the particle would
be zero at 10 min which is a good check on the direct observat8ion (Fig. 14). D. Carhides precipitated
from
silicon ferrite
The presence of up to 0.5% manganese appears to have little effect on the kinetics of precipitation or the form of presence
the carbide in iron-carbon alloys. The of silicon, however, produces pronounced
FIG. 19. Grain boundary cementite in 3.20% Hi, 0.01% Picral-nital etch. >: 2000. C alloy, slowly cooled from 870°C.
642
ACTA
TABLE 3. Interplanar
METALLURGICA,
spacings (A) for grain boundary in silicon steel
-.
I
Miller indices of crystal planes
5.072 2.536 1.691 1.268 1.015
010 020 030 040 050
3.75 3.018 2.098 1.539 1.202
101 111 121 131 141
1.87 1.75 1.51 1.25 1.05
1.862 1.756 1.506 1.255 1.052
202 212 222 232 242
1.245 1.23 1.12 1.00
1.250 1.212 1.123 1.005
303 313 323 333
2.54 1.70 1.268 1.016
I
3.74 3.02 2.10 1.54 1.21
I
I
7,
1959
carbide
FeJYG
Observed spacing
VOL.
FIG. 22. Lenticular carbide from steel 1315T to 315”C, held 2 hr. Extraction
A, quenched from replica. x 20,000.
particles are believed to be carbides.
They are found
only
in iron-silicon
alloys
containing
they are displaced by grain boundary after prolonged heating. of round,
lenticular
micrograph
of Fig.
carbon,
and
cementite films
The particles have the shape
disks, as shown in the electron 22.
The
diameter-to-thickness
ratio is about 25 to 1. Fig. 20 is a micrograph of this precipitate
steel was completely The
quenching
Although
their
(at which
temperature
the
ferritic) then air cooled to room relatively
in Fig. 21 were obtained 1315”C,
occurrence
in Steel A, heated in an evacuated
silica capsule to 1315°C temperature.
showing a typical
large
particles
shown
by heating the same steel to
to 315”C, then holding composition
is
for 2 hr.
unknown,
these
Since not more than three directions cipitate
are observed
inferred
that the lenticular
one grain, carbides
of the preit can be
precipitate
clearly defined precipitate directions. The poles of the { lOO}planes of the grain fell on the normals to the traces of the precipitate.
This same observation
was
recently reported by Suits and Low(17). A typical
electron
is shown
diffract,ion
in Fig. 23.
pattern
of a single
The diffraction
spots
20.
FIG. 21.
FIG. 20. Lenticular carbides in steel A, air cooled from 1315°C. Picral-nital etch. x 100. FIG. 21. Lenticular carbides in steel A, quenched from 1315°C to 315”C, held 2 hr. Picral-nital etch. x 2000.
on
(100) planes of the ferrite. This was checked by determining the orientation of a large grain showing
particle
Fm.
within
FIG. 23. Electron diffraction spot pattern obtained from lenticular carbide shadowed with palladium.
LESLIE,
FISHER
\
SEN:
AND
MORPHOLOGY
AND
\a,
TRYSTAL TABLE
STRUCTURE
Observed
4.
0
MEDIUM
Intensity
W M W
1.43
S
form
a square
although
many
missing and others are very weak.
points
Except
are
1.34 1.94
WM WM
for inten-
sity, all points in such a pattern are equivalent
and so
1.47
W
1.56 1.04 1.21
WM W
the innermost spots must be indexed as (030), etc, in order to avoid fractional indices. This is shown in Fig. 24.
The interplanar
accurately palladium the
by shadowing
were determined
an extraction
replica with
so that the electron diffraction
palladium
and
superimposed. be concluded carbon
distances
a
precipitated
that the lenticular
precipitate
cementite
carbide but another carbide of unknown
S-strong,
were
were unsuccessful,
100 200 300 400 500 600 110 220 330 440 120 240 130 260 140 150 230 350 340
4. SUMMARY
spots is
coupled with the observation indicates that the iron
atoms have the same arrangement in the particles as in the ferrite matrix (in directions parallel to the That is, the iron atoms are
coherent on the surface of the particle;
account
for the lenticular
this
and electron of existing
The relatively
of the diffraction
spots
confirmed
from carbon atoms is too weak to be observed.
The
other possibility is that the crystal structure of the precipitate is actually complex with a large unit cell
concerning
the
supersaturated
solid
Some of the previous
inter-
techniques
by the observations
supersaturated
dendrites,
oblong
precipitate
This might
from
The carbides precipitated
may
reflections.
carbon
has led to the
used.
Calcula-
tion of particle shape from rate of precipitation has recently been shown to be fallacious,d*) and this is
parallel
be due to superlattice
diffraction
in alpha iron.
other than those already mentioned suggests that they indicate that the precipitate contains silicon atoms in an ordered arrangement, inasmuch as the scattering
of
CONCLUSIONS
discrepancies
tions of the experimental
of low intensity
of silicon in the
pretations(3T5yg) were erroneous because of the limita-
shape of even the
largest particles.
AND
clarification solution
could
I
of improved techniques of electron
microscopy
iron.
probably
I
W.M-media-weak
but the presence
The development
composition
precipitation
surface of the particle).
,I
in low-
the same as the (110) and the (200) spacings in alpha This observation,
M-medium,
I
carbide was indicated.
nor epsilon
and structure. The spacing of the most intense diffraction
that the habit plane is {loo},
for
-
pattern of
particle
The data are listed in Table 4. It can
silicon steel is neither
Intensities: W-weak.
1
6.06 3.03 2.02 1.515 1.212 1.01 4.28 2.14 1.427 1.07 2.67 1.335 1.938 0.969 1.468 1.19 1.563 1.038 1.212
of spot pattern of Fig. 23.
network
spa&es
Co-ordinates of diffraction spots
S
2.02 1.515 1.212 1.01
643
Calculated spacing
<-;MISSING FIG. 24. Indexing
CARBIDES
and calculated interplanar lenticular carbides _
06
Observed spacing
OF
lines
have
alpha
iron
take
plates
and
L-shaped
been
observed.
in the temperature
they are the predominant tures.
reported herein.
during the quench aging several The
forms;
arrays
of
dendrites
range 150”-48O”C,
and
form at the lower tempera-
The oblong plates predominate
at temperatures
above about 400°C. Both forms appear to be cementite, Fe.&. The branches of the dendrites seem to be
so that it contains a number of planes with a very low density of atoms. Although the square array of
made up of bundles of thin cementite rods. These branches have two principal directions of growth, with an angle of 70” between them, and a third minor
diffraction spots suggests a cubic or tetragonal structure, these are unlikely because of the large number of omissions in the pattern.
direction. No indication was found of the presence of epsilon carbide. However, no diffraction patterns could be
Attempts to determine the silicon content of the particles by use of the electron probe microanalyzer
is unknown.
obtained from the L-shaped arrays, and their structure
ACTA
644
At low aging temperatures,
METALLURGICA,
the rate of precipita-
VOL.
7,
1959
Smith and J. C. Swartz for their help in other phases
tion, measured by electron and optical metallography,
of the work, and to R. L. Rickett for suggestions which
is much slower than the rate of precipitation
led to the investigation.
by internal friction. to
an inability
This disagreement
to
recognize
particles
on extraction
specimen
composition
very
replicas
measured
may be due
fine precipitate
or to differences
and history,
in
solution tempera-
ture, and aging procedure. The habit
planes
of Fe&
precipitated
from
un-
alloyed alpha iron are probably { 1 lo},. The principal directions of growth in this plane are (ill),. A third minor direction
of growth remains unknown.
The presence of up to 0.5% effect
upon
the morphology,
or habit, of the carbides but the presence of 3.25% effect.
manganese
has little
rate of precipitation,
precipitated
from
ferrite,
silicon has a pronounced
The carbides precipitated
during aging of the
iron-carbon-silicon alloy take the form of lenticular disks on (100) planes of the ferrite. The crystal structure
of these carbides is unknown,
neither cementite
but they are
(Fe.&) nor epsilon carbide
(Fe,,,C).
ACKNOWLEDGMENT
The
thanks
of
the
authors
Szirmae for the preparation micrographs,
are
due
to
Albert
of many excellent electron
to C. P. Stroble,
K. G. Carroll, R. P.
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