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Electron microscope observations on the precipitation of zirconium hydride in zirconium
ELECTRON
MICROSCOPE
OBSERVATIONS
ZIRCONIUM
HYDRIDE
ON THE
PRECIPITATION
OF
IN ZIRCONIUM*
J. E. BAILEY? A study has been made of the precipitation of zirconium hydride in zirconium at hydrogen concent,rat,ions in the range 100-1000 p.p.m. using the transmission electron microscopy technique. In rapidly cooled or quenched specimens the precipitates appear needle-like with axes lying along (1120) directions In slowly cooled specimens the and are probably platelets parallel to {lOiO} planes of the matxix. Electron and X-ray diffraction experiments precipitates appear comparatively large in two dimensions. Identical orientation relationships show that all precipitates have a face centred tetragonal structure. also appear to hold for all precipitates. The needle-like precipitates grow rapidly along their (1120) type axes apparently remaining coherent; growth in the direction normal to their axes is accompanied by the formation of dislocations and the precipitates become incoherent on the appropriate faces. Beam heating experiments show that nucleation of the hydride does not necessarily require the presence of dislocations but that preferential precipitation will occur on them and on grain boundaries when present. OBSERVATIONS
EN MICROSCOPIE ELECTRONIQUE L’HYDRURE DE ZIRCONIUM DANS
SUR LA PRECIPITATION LE ZIRCONIUM
DE
L’auteur a &udi8 la pr&ipitation de I’hydrure de zirconium dans le zirconium, pour des teneurs en hydrogQne comprises dans la gamme de 100 8. 1000 p.p.m., & I’aide de la microscopic Bectronique par transmission. Dans les Bchantillons refroidis rapidement ou trempbs, les pr&ipit& apparaissent sous la forme d’aiguilles ax&es suivant les directions (1 lZO), et sent vraisemblablement des plaquettes paralleles Dans les Bchantillons refroidis lentement, les precipit& apparaissent aux plans {lOiO}; de la matrice. relrttivement d&elopp& suivant deux dimensions. Les essais de diffraction Blectronique et. de diffraction des rayons X mont,rent que tous les p&cipit& ant une structure t&ragonale 8,faces cent&es. 11semble
bien que tous les pr&cipit& observes prbsentent des relations d’orientation identiques. Les pr&ipit& aciculaires croissent rapidement le long de lenrs axes (1120) et restent apparemment coh8rents; la croissance dans la direction normale B leur axe s’accompagne de la formation de dislocations et les pr&ipit& deviennent incoh&ents sur les nouvelles faces ainsi form6es. Des essais de chauffage par le faisceau montrent que la germination de l’hydrure ne demande pas nBcessairement la pr&ence de dislocations, mais qu’on observe une pr6cipitation pr&f&entielle sur celles-ci ainsi que sur les limites de grains quand il s’en rencontre dans le champ observ& ELEKTRONENMIKROSKOPISCHE UNTERSUCHUNG DER ZIRKONHYDRID IN ZIRKON
AUSSCHEIDUNG
VON
Die Ausscheidung van Zirkonhydrid in Zirkon wnrde bei Wasserstoffkonzentrationen van 100 bis 1000 p.p.m. mittels Durchstrahlung im Elektronenmikroskop untersucht. Bei schnell abgekiihlten oder abgeschreckten Proben zeigen sich nedel&hnliche Ausscheidungen, deren Achae parallel zu (1120)Richtungen liegt; wahrscheinlich handelt es sich urn Plllttchen parallel zu {lOiO}-Ebenen der Matrix. In langsam abgekiihlten Proben sind die Ausscheidungen in zwei Dimensionen relativ ausgedehnt. Wie Experimente mit Elektronen- und RBntgenstreuung zeigen, besitsen alle Ausscheidungen tetragonal flllchenzentrierte Strnktur; such scheinen die Orientierungsverhiiltnissebei allen Ausscheidungen gleich zu sein. Die nadelftirmigen Ausscheidungen wachsen schnell und kohiirent entlang ihrer (1120)-Achse, wlihrend beim Wachstum senkrecht dazu Versetzungen entstehen und die Ausscheidungen nur teilweise inkoh&rent sind. Aufheizungsversuche mit Elektronenstrahlen zeigen da13 zur Keimbildung des Hydrids nicht unbedingt Versetzungen erforderlich sind, die Ausscheidungen jedoch vorzugsweise an vorhandenen Versetzungen und Korngrenzen entstehen. 1. INTRODUCTION
Extensive
metallographic
lying in (lOi5)
studies have been made
of the zirconium hydride precipitates decomposition
of the supersaturated
produced
associated
by the
near
the
the
high
hydride-metal
planes which are probably hydrogen
concentrations
interface.
These authors suggest that Kunz and Bibb were observing surface
solid solution.
Langeron and Lehr(l) established that at low hydrogen
twins produced
concentrations
pletely
(~100
and {lOil}
with
p.p.m.) the hydride precipitates
removed
during grinding which were not comby
chemical
polishing
and
that
in platelets lying parallel to {IOiO} planes of the zirconium matrix. Kunz and Bibbc2) reported however
subsequent
that the hydride precipitates as platelets on the twinning planes, i.e. (lOi2) (1121) and (1122). A further
X-ray studies of the zirconium hydrogen phase diagram by Gulbransen and Andrewc4) and Whitwamf5) appear to lead to the conclusion that two stable hydride phases exist, a face centred cubic and
ACTA METALLURGICA VOL.
11;
APRIL
1963
may have occurred
in these twins.
study by Westlake and Fisherc3) supported the work of Langeron and Lehr (l) by showing that the hydride platelets precipitated predominantly on {lOiO} planes together with some platelets of secondary importance * Received April 28, 1962. t Berkeley Nuclear Laboratories, Central Generating Board, Berkeley, Glos., England.
hydride precipitation
a face centred tetragonal phase designated 6 and E respectively, together with a minor metastable phase having a face centred tetragonal structure and desig-
Electricity 267
nated yl. The metastable y1 phase was found only in association with the 6 phase. However, Vaughan
ACTA
268
METALLURGICA,
and Bridgec6) on the basis of their high temperature X-ray
studies
exists whose position
concluded tetragonitl
that
one
structure
and temperature.
hydride
varies
The phase
phase
with
com-
diagram
ac-
cording to Vaughan and Bridge@) and Ellis and McQuillan(7) suggests that the hydride platelets formed from solutions
containing
tents may be the 6 phase. obtained electron diffraction
low hydrogen
con-
Schwartz and MalletW evidence which suggests
VOL.
11,
1963
Studies were also made of zirconium quenched
an inert atmosphere. The zirconium foils after being given the appropriate treatment, were thinned by electropolishing and examined in a Siemens electron microscope 100 kV.
of perchloric
acid to 90 parts glacial acetic acid.
bath
was operated
which
stirred and kept cool.
X-ray studies have been unable to detect the structure
men was removed
of these precipitates at low hydrogen concentration. The precipitates are of considerable importance since hydrogen
of zirconium
that occurs
concentrations
appears
present
the
to
be
with them. In
the
3.1
Zirconium
After work
transmission
electron
microscopy techniques and supplementary X-ray experiments have been used to study the precipitation
at The
at 20 V was vigorously
When suitably
thin the speci-
and washed in distilled water.
3. ELECTRON MICROSCOPE OBSERVATIONS
at low
associated
operating
The polishing bath used consisted of 10 parts
that these platelets were a tetragonrtl phase. To date,
the embrittlement
foils that were
into iced brine after annealing at 800°C in
foils-vacuum
this treatment
contain hydrogen
annealed
the foils
were expected
in concentrations
An electron micrograph
of ~10
to
p.p.m.(*)
taken from a typical
area of
of hydride in zirconium at low hydrogen concentrations
one of these foils is shown in Fig. 1 (a) ; a high density of small clusters is observed which must result from
The
the presence of some impurity.
technique
has clearly
hydride precipitates both
the
crystal
revealed
the
zirconium
and provided evidence concerning structure
of the precipitates
and
their stability. 2. EXPERIMENTAL
The
majority
of the
obser-
vations have been carried out on commercial
and re-
These clusters were The clusters could
be made to disappear in the same temperature range as hydrogen was found to precipitate from solution (these experiments
microscope
actor grade zirconium
electron
observed in all the foils examined.
are
described
below).
clusters that form preferentially
Furthermore,
on both
the grain
supplied by Murex Ltd., in the
form of foil of thickness 0.010 in.
Both grades had a
hardness in the annealed condition of ~200 VHN; no distinction will be made between these grades since their
behaviour
was
experiments. Some observations
identical
in
the
following
have been made on argon arc
melted crystal bar zirconium,
which is purer than the
grades described above and has a hardness number of ~100 VHN when fully annealed. The few experiments in which
this material
was used are clearly
identified below. Foils of suitable size were annealed at temperatures of about 800°C for several hours in a vacuum of & 10P5 mm of Hg to remove any residual hydrogen. The analyses carried out by Schwartz and Mallet@) show that this treatment reduces the hydrogen content to below 10 p.p.m. The vacuum apparatus
incorporated
a palladium
leak through which the required amounts of hydrogen were passed into the system. Hydriding was generally carried out by heating the zirconium foil to 800°C in a known pressure of hydrogen and allowing the specimens to furnace cool. In order to obtain a faster cooling rate some foils were heated electrically quenched by switching off the current.
and
FIG. l(a).
Small clusters observed on zirconium foils ( x 26,000).
electropolished
BAILEY:
PRECIPITATION
OF ZIRCONIUM
FIG. l(b). Clusters formed preferentially on grain boundaries lie on the surface of the foil ( x 26,000).
boundaries
(Fig. l(b))
and on dislocations
(Fig. l(c))
appear to be either on the top or bottom the foil.
surfaces of
From the above evidence it is concluded
these clusters are hydride
that
clusters which form on the
surface of the foil during electropolishing. The density of such clusters seems to depend sensitively on the polishing conditions.
Some specimens show relatively
few clusters and there is often a wide variation
in the
269
HYDRIDE
FIG. l(c). Clusters formed preferentially on the points of emergence of dislocations from the foil ( x 26,000). needle-like vations.
will be used here to describe These
precipitates
can
seen in Fig. 2(c).
Fig. 2(c) also shows that some pref-
erential precipitation
occurs on grain boundaries.
Fig. 2(b) shows the same area as Fig. 2(a) after tilting the specimen to produce different diffracting conditions.
A
semi-circular
“halo”
now appears
same specimen.
strong Bragg reflections are operating the double
clusters when referred to below. 3.2
Zirconium
These observations been hydrided
area.
foils-hydrided to contain
~500
on foils that had
p.p.m.
of hydrogen.
Figs. 2 and 3 show examples of the hydride precipitates observed in the furnace
cooled specimens.
It is clear
from Fig. 2(a) that the hydride precipitates assume a needle-like appearance at a very early stage of growth, and electron diffraction patterns show that these “needles” have axes lying along (1120) directions. When the plane of the foil is accurately parallel to the basal plane of the zirconium the hydride “needles” appear very thin as shown in Fig. 2(c). This evidence suggests that these “needles” are really platelets lying parallel to {IOiOo) planes which is in agreement with the metallographic work,(1,3) however, the term
dislocation
contrast Two
as indicated
images observed
by
in the same
that this contrast is due to the
strains induced
the precipitate
type
on one side of the precipitates.
It is considered
coherency
were made
distin-
guished from the surface clusters which can also be
density of clusters observed from different areas of the These artefacts will be called surface
the obser-
be clearly
in the matrix
surrounding
and is a similar effect to that observed
around G.P. [2] precipitates (Nicholson and Nutting@)). The larger needle-like
precipitates,
an example
of
which is shown in Fig. 2(d), result from the continued growth of the small precipitates; this is borne out by the electron beam heating experiments described in $4. As the precipitates
increase in size arrays of dis-
locations are observed to be associated with them. At this stage the precipitates must be incoherent on certain faces. Electron diffraction patterns taken from areas including these precipitates have so far failed to reveal diffraction spots that cannot be attributed to the zirconium matrix. These needle-like precipitates all have axes lying along the (1120)
ACTA
270
METALLURGICA,
VOL.
11,
1963
FIG. 2(a). Smell hydride precipitates in zirconium hydrided to contain &500 p.p.m. of hydrogen ( x 40,000).
FIG. 2(b). Same area as shown in Fig. 2(a) after tilting the foil to produce different diffracting conditions ( x 40,000).
directions
of the zirconium
matrix
has
obtained
suggests
been
orientations. Hydride precipitates
which
and no evidence other
possible
that were generally relatively
large in two dimensions compared with those described above were also found in these specimens ; examples are shown in Fig. 3(a) and (b). Diffraction patterns obtained from these precipitates suggest that they are the “so called” metastable y1 phase (see $5).
These large precipitates also have arrays of dislocations associated
with them.
Attempts
to find precipitates
that could be clearly interpreted as the 6 hydride phase have not been successful. Zirconium specimens that were electrically heated and quenched in the hydrogen atmosphere by switching off the current showed the presence of both long needle-like precipitates (Fig. 4(a) and (b)) and precipitates which appear wide in a direction normal to
BAILEY:
FIG. 2(c).
PRECIPITATION
Preferential precipitation of hydride boundaries ( x 11,000).
on grain
(a)
ZIRCONIUM
FIG. 2(d).
211
HYDRIDE
Needle-like
hydride precipitate
( x 26,000).
(b)
FIG. 3(a) and Fig. 3(b). Examples tain
OF
-500
of the large hydride p.p.m. of hydrogen
Pre:cipitates found is furnace cooled specimen and x 13,000 respectively). (x 26,000
hydrided
to con-
ACTA
252
(a)
METALLURGICA,
VOL.
11,
1963
(b)
FIG. 4(a) and FIG. 4(b). Examples of needle-like precipitates in rapidly cooled hydrided zirconium foils showing clearly the associated dislocation structures ( x 22,000 and x 26,000 respectively).
Fm.. 4(c) Hydride precipitate large in two dimensions also observed in rapidly cooled hydrided specimens ( ~26,000).
BAILEY:
(1120)
axes
(Fig.
4(c)).
PRECIPITATION
The precipitates
OF
that
are
ZIRCONIUM
periments
273
HYDRIDE
in which localized
regions of the electron
similar in habit to those shown in Fig. 3(a) and (b).
specimens have been heated by increasing the intensity of the electron beam. The electron beam
The majority
is reduced to a minimum
large in two dimensions
ofthe precipitates
specimens were however, dislocation arrangement precipitates
is clearly
The dislocations the precipitate
Zirconium
in these rapidly cooled of the needle-like type. The surrounding the needle-like
revealed
in Fig. 4(a) and (b).
are generally attached or appear
closed elongated the precipitate 3.3
e.g. Fig. 4(c), would appear
to the ends of
as completely
or partially
loops running parallel to the axis of
into iced brine
of the
quenching
needle-like
zirconium
argon atmosphere diffraction
foils annealed
by
at 800°C in an Electron
taken from areas including phase and X-ray
below confirmed this interpretation
These quenched
specimens
tain any of the “two discussed
high
these
contained spots which could be interpreted
in terms of the y1 hydride described
precipitates
into iced brine (Fig. 5(a)).
patterns
precipitates
hydride
of zirconium
dimensional”
studies (see $5).
did not con-
type precipitates
above. BEAM
HEATING-STAGE
Considerable
information
in order to increase the
of the beam ; the specimen
heated by increasing the beam current. cedure a hot zone is produced is surrounded Micrographs
(~5
is then
By this pro-
,u diameter) which
by a sharp radial temperature
gradient.
are taken after reducing the beam current
is illustrated
in such an ex-
in Fig. 6. An area of vacuum
annealed crystal bar zirconium is shown in Fig. 6(a) in which several needle-like hydride precipitates are present. beam
On heating with a suitably
(15 ,uA) for several seconds
disappear.
On rapidly
new precipitates
reducing
intense electron
these precipitates the electron
nucleated and grew;
beam
these are shown
in Fig. 6(b).
Repeating
intense
(20 ,uA), i.e. heating to a higher tem-
beam
this procedure
perature,
reduces
specimen
since no precipitation
Fig. 6(c).
4.’ ELECTRON
and the condenser I aperture
removed
general intensity
periment
It was found possible to produce a relatively density
of the microscope
rapidly and replacing the aperture. The type of behaviour observed
(Fig. 4(a)). foils-quenched
microscope
the amount
with a more
of hydrogen occurred
in the
on cooling,
Further beam heating at a lower intensity
(10 ,uA) again caused the nucleation
and growth
EXPERIMENTS
relatively
It is concluded
has been gained from ex-
from these experiments
HEATING
AND
FIG. 5(a). Needle-like hydride precipitates in zirconium foils quenched into iced brine from 800°C ( x 26,000).
large precipitates
FIG. 5(b).
(Fig. 6(d)).
of
that there must be a residual
Removal of the precipitates shown in Fig. S(a) by election beam heating ( x 26,000).
ACTA
274
(cl FIG. 6. Sequence of micrographs
METALLURGICA,
VOL.
11,
1963
(4 showing the effect of electron beam heating on hydride precipitation.
(See text)
(x
13,000).
BAILEY:
pressure of hydrogen
inside the electron
from which hydrogen specimens.
PRECIPITATION
is absorbed
The above experiments since they demonstrate precipitates directions
shrink
from
microscope
by the zirconium
The source is considered
present in the microscope tamination originates.
OF
to be the oils
which
carbon
are of considerable clearly
and grow
interest
that the needle-like rapidly
these beam heating experiments cipitates
disappeared
temperature
range as the normal hydride precipitates
do
not
imply
that
another
form
of
does not
for the “punching precipitates
these experiments.
In Fig.
e.g.
either with some precipitated
present.
The removal
with
cipitates
by electron
panied
beam heating
by the complete
surrounding
them;
removal
accom-
of the dislocations
for example the precipitates
and B, Fig. 5(a), were observed appear together
is often
at A
to shrink and dis-
with their associated
dislocations
as
shown in Fig. 5(b). Experiments
been carried
out using a cali-
brated heating stage in order to determine perature
at
removed.
which
the
hydride
has a relatively
being of the furnace
at temperatures
are
type.
of
heating experiment be explained.
by
ential cooling
events
the impurity
described
beam
above (Fig. 6) can now
Since the precipitates
become unstable
The loops
At
300°C
(Schwartz
the
terminal
and MallettP)
< C,
at 300°C in this case.
solubility
is ~100
and Gulbransen
p.p.m.
and An-
drew(lO)) and therefore pH is < 10-5. Since the terminal solubility decreases with decreasing temperature, on rapidly
cooling
(Fig. 6(b)).
the
Reheating
specimen
precipitation
occurs
the specimen to a higher tem-
perature reduces the value of C, sufficiently to prevent precipitation on subsequently quenching (Fig. 6(c)). Further heating of the specimen to a temperature below 300°C again raises the value of C, to a value above C and precipitation It was also observed
occurs directly,
Fig. 6(d)).
that on heating a specimen to a
temperature at which the precipitates in the hot zone disappear, precipitates were appearing in the region surrounding the hot zone, this situation is similar to that observed in Fig. 6(d), since in this region the temperature is such that C, > C. Occasionally circular type precipitates surrounded by dense tangles of dislocations
were observed during
by the differset up
and impurity
during particle.
arrangements
loops
and more
which
resemble
been produced
by a hydride
this procedure
removed
the hydride
at B (Fig. 8(b)) and has nucleated Numerous
new
loops are now observable
in
the field of view and these must be associated with the hydride
appear
precipitates. (1120)
precipitates.
to be “thrown
In
off”
these
loops
the sides of the
and since they must glide in this
the Burger’s type.
vectors
are expected
to be of
In the case of these hydride pre-
cipitates, ‘loops and dislocations growth
general
from
All arrays of loops have axes parallel to
directions,
the l/3(1120)
C, in the specimen such that C,
or
This has been confirmed by beam heating
the specimen;
H, in the microscope
C being the terminal solubility
out”
has produced
at B have
precipitate.
direction
concentration
particle
dislocation
at 300°C it would appear that the residual pressure of pH gives rise to an equilibrium
hydride
case of impurity
stresses
the matrix
are always
closely the similar effects observed inmagnesium.(11-13)
precipitates.
in the
In the
contraction
between
these
An example of this effect can be seen at A in Fig. S(a) ;
new
observed
C;
the loops are “punched
These experiare removed
B and
particles.
thermal
precipitate
of about 300°C.
sequence
particles
large thermal
ments show that the hydride precipitates The
the tem-
precipitates
The heating stage which was supplied
Siemens and Halske capacity,
impurity
complex
have
at A,
from
S(a) arrays of loops are
observed,
pre-
is
out” of complete loops
associated
hydride
hydride
has also been obtained
observed however that hydride precipitates do nucleate preferentially on dislocations when they are of the zirconium
These pre-
in the same
precipitating. Evidence
It is
(Fig. 7).
and reappeared
and it is considered that they may result from the growth of the surface clusters described in $3.1, and
by hydride
require the presence of dislocations.
275
HYDRIDE
(1120)
along
of the matrix and that nucleation
necessarily
con-
ZIRCONIUM
and it is difficult
are produced
to distinguish
during
additional
loops that may be produced during cooling. Some preliminary cooling stage experiments do suggest however that loops can be produced
on cooling.
5. CRYSTALLOGRAPHIC ANALYSIS HYDRIDE PRECIPITATES
OF THE
5.1 Structure of the hydride precipitates
Electron diffraction patterns were easily obtainable from the large precipitates (Fig. 3) observed in slowly cooled
zirconium
specimens.
from the precipitates
The pattern
obtained
in Fig. 3(a) is shown in Fig. 9.
These patterns could be accurately interpreted in terms of the tetragonal y1 phase using lattice parameters given by Whitwam.c5) Although the yl phase may be treated as a slight distortion of the S f.c.c. phase, the distortion is sufficient to be detected on the electron diffraction pattern, e.g. the angle between (ill) and (202) for the y1 phase is 93” as was observed on the diffraction pattern taken from the precipitate
276
ACTA
METALLURGICA,
VOL.
11,
1963
FIG. 7. Circular type hydride precipitates sometimes observed during electron beam heating experiments ( x 20,000).
FIG. 8(a). Examples of “punched out” dislocation loops produced by hydride precipitates and impurity particles.
BAILEY:
PRECIPITATION
OF
ZIRCONIUM
HYDRIDE
FIG. 8(b). Same area as Fig. 8(a) after the production of hydride precipitates by electron beam heating (x 20,000).
FIQ. 9. Selected area electron diffraction pattern taken from the large precipitate shown in Fig. 3(a).
shown in Fig. 3(b);
this angle should be 90” for the
the electron
diffraction
the precipitates
8 phase. Electron
diffraction
patterns from the thin needle-
like precipitates have been more difficult to obtain. Patterns were occasiona,lly obtained from the
For the large precipitates the orientation
Previous
X-ray studies have been unable to detect
with certainty the needle-like hydride precipitates found in zirconium at low hydrogen concentrations. In t’he present York it was found
that a large con-
centration of these precipitates could be produced by quenching zirconium foils from 800°C int,o iced brine ($3.3) and therefore an attempt was made to determine their crystal structure by X-ray studies. X-ray diffraction photographs were taken with a Guiner focussing camera permitting the simultaneous examination of the quenched and unhydrided foils: using monochromated MO K, and Cu K, radiat’ion. The quenched foils clearly showed the presence of additional
reflections
from
the hydride
precipitates
which corresponded closely to t’hose observed by Whitwamc5) from the phase designated y’. These reflections
could be indexed
the strong prominent
on a trtragonal
cell and
lines were :
d Z”2 = 1.A75 *
These
values
A further
r = 1.HX8 A
orientation
wit’h those
of
out on slowly
yl phase, and not to the face centred cubic that
available,
is identical
{ll:O},
and (lOlO),,
{llzO),
is parallel to {llO},,1 and
(IOTO}, is almost parallel to {131);,1 (ml” inclination). It is assumed here that the habit planes are the planes perpendicular to the foil. By similar arguments the habit planes of the needle-like precipitates platelets
are {lOTO), parallel to (11 l}+
if these are The change
in habit during growth from platelets to massive precipitates is not easily explained since it would not result from a straightforward thickening of the platelets as suggested by the form of the precipitate in Fig. 4(c);
such a thickening
would
suggest
(liOO),
parallel to (Ill),,1 as a habit plane. It may be of significance that the (131},1 type planes appear to be habit planes. The spacing of (lOlO},
planes c&,,
= = to
6. DISCUSSION
to the
6 phase.
the hydride
at these low hydrogen
and electron
“two
and rapidly
dimensional”
diffraction
studies estab-
precipitates
observed
cooled zirconium
precipitates
in
foils and the
observed
in the rela-
cooled foils both have a face
centred
tetragonal structure corresponding closely to the y1 st,ructure previously detected in zirconium cont,aining
c = 4.960 P,
therefore
evidence
wit’h (1). From the shape of the two large precipitates (Fig. 3(a) and (b)) the habit planes would appear to be
quenched
hydride were again found to clearly correspond
observed
the
t’ively slowly
was then carried
It is concluded
From
lished that the needle-like
cooled zirconium foils containing ~1000 p.p.m. of hydrogen and the additional reflections due to the
cipitates
the
relationship for the needle-like precipitates
The X-ray
arc t’o be compared
study
(1)
(1 l20), parallel to (I lO)+ 1
and
for the y1 phase :
IL = 1.610 A
(TI1)71
these planes.
(202) reflrctions are :
Whitwam
can be expressed as:
2d (131j; the two lattices fit therefore nearly perfectly (misfit 0.07 per cent) in the direction normal to
0.005 a
as calculated from the (Ill)
a = 4.617 B
relationship
them.
2.798 and the spacing of the {131},1 planes do,,, 1.396, and hence d,,,I,, is almost exactly equal
dzoo= 2.28 -f 0.01 a The cell dimensions
from both
shown in Fig. 3(a) and (b)
(IlOO), parallel to
“quenched in” precipitates discussed in $3.2. These patterns were also interpretable HAdue to a tetragonal phase.
patt’erns obtained
and the matrix surrounding
prc-
concentra-
the face centred cubic hydride phase (Gulbransen Andrew(d) and Whitwam(5)).
Furthermore,
and
the X-ray
work showed that the y1 phase was present in slowly cooled zirconium foils containing ~1000 p.p.m. of hydrogen; no evidence for t)he presence of the f.c.c. B phase was obtained.
It is concluded
the hydride phase in zirconium
therefore that
at low hydrogen
con-
tions have the tetragonal y1 structure for which c/a > 1
centrations
and lattice parameters of Q = 4.617 A and c = 4.888 1%arcording to the present X-ra.;v study.
to be expected according to the current phase diagram.
5.2 Orientation
These results confirm the previous work of Schwartz and Mallett(*) who concluded that the needle-like
and eirconium
rp,latio?lshipsbetlc~epn
h!/rlrid~preci~itcxths
matrix
The orientation
relationships
( < 10 at. ‘A,) is a face centred tetragonal
phase and not the face centred cubic 8 phase which is
hydride precipitates wclre dct,crmined from
were a tetragonal phase analogous
to that found in the H,-H
spst,em.
BAILEY:
PRECIPITATION
The needle-like zirconium hydride precipitates axes lying along (1120) directions it is clear
therefore
that
OF
have
of the matrix,
if these
precipitates
and are
platelets they must lie parallel to planes of the form (101x); the evidence suggests that they are parallel to (1010) planes, which is in agreement with the observations
of Langeron
and Lehro)
and Westlake
No evidence for precipitation on and Fisher.c3) twinning planes has been obtained. These precipitates which appear coherent when small ($3.2) grow easily along the direction
of their axes and the observations
show that as they grow in thickness dislocations
associated
the number
of
with them increases, e.g. com-
pare the thin precipitates
in Fig. 5(a) with those in
ZIRCONIUM
279
HYDRIDE
occasionally,
e.g. around some precipitates
and 8. One dislocation 30 (loio),
spacings
in Figs. 4
will be required roughly every in order
to
accommodate
the
strain ; thus for the large precipitate in Fig. 4(b) which is ~1500 A thick about 20 dislocation loops would be expected. This figure is close to the number of segments observed. In cases where complete loops appear to be given off, e.g. at B in Fig. 8(a) their axes appear to lie along (1120) directions suggesting that the Burger’s vectors of the loops are the normal i (1120)
type.
dislocation cipitate
It is clear that the long segments
of
and sides of the loops parallel to the pre-
axis must
glide
away
on the basal plane.
These results therefore provide evidence for slip on the
Figs. 4(b) and 2(d). It is considered therefore that some interfaces of the precipitates become incoherent
basal plane in zirconium under appropriate conditions. Hydrogen forms an interstitial solution in zirconium
during the thickening
and can migrate rapidly at relatively low temperatures
process.
Consider precipitates
with axes [1210], then the spacing of the planes of the matrix
and precipitate
and (ill),,,,
normal to [lOiO],
i.e. (lOiO),
are 2.798 A and 2.706 A respectively.
If
( <300°C) to form hydride precipitates. At these low temperatures appreciable concentrations of point defects produced
thermally
are not expected
and it is
the strain resulting from growth in the [lOiO], direction is accommodated by dislocations then ideally
considered unlikely that a large proportion of the strain associated with the growth of the precipitates
prismatic
can be accommodated
dislocation
loops would be punched out in planes parallel to (lOTO),. These loops will be vacancy loops since the matrix spacing is larger than the precipitate spacing. However, the precipitates do not necessarily thicken uniformly in the [lOTO], direction and complete
loops may not form;
instead the seg-
7. CONCLUSIONS
A study
has been made
p.p.m.
of hydrogen
illustrated in Fig. 10. This will, in general, be the case -since the precipitates grow preferentially in the [1210],
scopy.
Electron
direction precipitate
will end on the precipitates,
and will therefore
taper at their ends; the Evidence
at A in Fig. 7 is a good example.
for the punching
out of complete
loops can be found
of the morphology
and
crystallography of the zirconium hydride precipitates formed in zirconium specimens containing
as
ments of dislocation
by such defects.
by transmission
and X-ray
electron
diffraction
micro-
evidence
has
shown that all of these precipitates have a tetragonal structure similar to the y1 phase, (Gulbransen and Andrewc4)
and Whitwamc5)).
In rapidly
cooled
or
quenched specimens the precipitates appear needlelike with axes lying along (1120) directions and may be interpreted as platelets parallel to {IOiO} planes of the matrix. In slowly cooled specimens the precipitates are comparatively large in two dimensions. Identical orientation relationships between hydride and matrix hold for both types of precipitate. It is concluded ticular
from
nucleation
the
from the observations beam
heating
of the hydride precipitates
sarily require
the presence
preferential precipitation
liner
FIG. 10. Illustration of the formation of dislocation segments during the growth of the precipitates in the [lOTO] directions. 4
that
does not neces-
of dislocations
although
will occur if they are present,
as well as on grain boundaries.
Wslocation
and in par-
experiments
These experiments
showed that under the conditions operating in the microscope the hydride precipitates become unstable and were completely removed at temperatures of -3oo”c. The needle-like precipitates which are considered to be responsible for the hydrogen embrittlement of zirconium grow rapidly along the direction of their
280
ACTA
METALLURGICA,
axes and apparently remain coherent; growth in the direction normal to their axes is accompanied by the formation of dislocations and the precipitates become incoherent on the appropriate faces. ACKNOWLEDGMENTS
The author is indebted to Dr. G. K. Williamson for his critical discussion of the content of this paper. He particularly wishes to thank Mr. W. T. Eeles for his advice and help in carrying out the X-ray experiments. He is also grateful to Mr. R. Redford who constructed the hydriding apparatus and Mr. G. Rickards for assistance in electron microscopy. This paper is published by permission of the Director of the Berkeley Nuclear Laboratories, C.E.G.B., Berkeley, Glos.
VOL.
11,
1963 REFERENCES
;: 3. 4. :. 7: 8. 9. 10. 11. 12. 13.
J. P. LANQERON and P. LEHR, Rev. M&all. 60, 901 (1958). F. W. KUNZ and A. E. BIBB, Trans. Amer. Inst. Min. (Metall.) Engm. 218, 133 (1960). D. G. WESTLAKE and E. S. FISHER. Trans Amer. Inst. Min. (Metall.) Engrs. 224, 254 (1962): E. A. GULBRANSEN and K. F. ANDREW, J. Electrochem. sot. 101,474 (1954). D. WHITWAM, Mem. Sci. Rev. MetalE. LVII, 1 (1960). D. A. VAUQH~N and J. R. BRIDLE, J. Metals 8,528 (i956). C. E. ELLS and A. D. MCQUILLAN, J. Inst. Met. 85, 89 11956). C. M. SCHWARTZand M. W. MALLETT, Trans. Amer. Sot. Metals 46, 640 (1954). R. B. NICHOLSON and J. NUTTING, Phil. Mag. 2, 531 (1958). E. A. GULBRANSEN and K. F. ANDREW. J. Metals 7. 136 (1955). A. FOURDEUX and A. BERQHEZAN,C. R. Acud. Sci. Paris 252, 1462 (1961). S. LALLY and P. G. PARTRIDOE. To be published. R. I. HUTCHINSON. Private communication. \----I-
MICROSCOPE
OBSERVATIONS
ZIRCONIUM
HYDRIDE
ON THE
PRECIPITATION
OF
IN ZIRCONIUM*
J. E. BAILEY? A study has been made of the precipitation of zirconium hydride in zirconium at hydrogen concent,rat,ions in the range 100-1000 p.p.m. using the transmission electron microscopy technique. In rapidly cooled or quenched specimens the precipitates appear needle-like with axes lying along (1120) directions In slowly cooled specimens the and are probably platelets parallel to {lOiO} planes of the matxix. Electron and X-ray diffraction experiments precipitates appear comparatively large in two dimensions. Identical orientation relationships show that all precipitates have a face centred tetragonal structure. also appear to hold for all precipitates. The needle-like precipitates grow rapidly along their (1120) type axes apparently remaining coherent; growth in the direction normal to their axes is accompanied by the formation of dislocations and the precipitates become incoherent on the appropriate faces. Beam heating experiments show that nucleation of the hydride does not necessarily require the presence of dislocations but that preferential precipitation will occur on them and on grain boundaries when present. OBSERVATIONS
EN MICROSCOPIE ELECTRONIQUE L’HYDRURE DE ZIRCONIUM DANS
SUR LA PRECIPITATION LE ZIRCONIUM
DE
L’auteur a &udi8 la pr&ipitation de I’hydrure de zirconium dans le zirconium, pour des teneurs en hydrogQne comprises dans la gamme de 100 8. 1000 p.p.m., & I’aide de la microscopic Bectronique par transmission. Dans les Bchantillons refroidis rapidement ou trempbs, les pr&ipit& apparaissent sous la forme d’aiguilles ax&es suivant les directions (1 lZO), et sent vraisemblablement des plaquettes paralleles Dans les Bchantillons refroidis lentement, les precipit& apparaissent aux plans {lOiO}; de la matrice. relrttivement d&elopp& suivant deux dimensions. Les essais de diffraction Blectronique et. de diffraction des rayons X mont,rent que tous les p&cipit& ant une structure t&ragonale 8,faces cent&es. 11semble
bien que tous les pr&cipit& observes prbsentent des relations d’orientation identiques. Les pr&ipit& aciculaires croissent rapidement le long de lenrs axes (1120) et restent apparemment coh8rents; la croissance dans la direction normale B leur axe s’accompagne de la formation de dislocations et les pr&ipit& deviennent incoh&ents sur les nouvelles faces ainsi form6es. Des essais de chauffage par le faisceau montrent que la germination de l’hydrure ne demande pas nBcessairement la pr&ence de dislocations, mais qu’on observe une pr6cipitation pr&f&entielle sur celles-ci ainsi que sur les limites de grains quand il s’en rencontre dans le champ observ& ELEKTRONENMIKROSKOPISCHE UNTERSUCHUNG DER ZIRKONHYDRID IN ZIRKON
AUSSCHEIDUNG
VON
Die Ausscheidung van Zirkonhydrid in Zirkon wnrde bei Wasserstoffkonzentrationen van 100 bis 1000 p.p.m. mittels Durchstrahlung im Elektronenmikroskop untersucht. Bei schnell abgekiihlten oder abgeschreckten Proben zeigen sich nedel&hnliche Ausscheidungen, deren Achae parallel zu (1120)Richtungen liegt; wahrscheinlich handelt es sich urn Plllttchen parallel zu {lOiO}-Ebenen der Matrix. In langsam abgekiihlten Proben sind die Ausscheidungen in zwei Dimensionen relativ ausgedehnt. Wie Experimente mit Elektronen- und RBntgenstreuung zeigen, besitsen alle Ausscheidungen tetragonal flllchenzentrierte Strnktur; such scheinen die Orientierungsverhiiltnissebei allen Ausscheidungen gleich zu sein. Die nadelftirmigen Ausscheidungen wachsen schnell und kohiirent entlang ihrer (1120)-Achse, wlihrend beim Wachstum senkrecht dazu Versetzungen entstehen und die Ausscheidungen nur teilweise inkoh&rent sind. Aufheizungsversuche mit Elektronenstrahlen zeigen da13 zur Keimbildung des Hydrids nicht unbedingt Versetzungen erforderlich sind, die Ausscheidungen jedoch vorzugsweise an vorhandenen Versetzungen und Korngrenzen entstehen. 1. INTRODUCTION
Extensive
metallographic
lying in (lOi5)
studies have been made
of the zirconium hydride precipitates decomposition
of the supersaturated
produced
associated
by the
near
the
the
high
hydride-metal
planes which are probably hydrogen
concentrations
interface.
These authors suggest that Kunz and Bibb were observing surface
solid solution.
Langeron and Lehr(l) established that at low hydrogen
twins produced
concentrations
pletely
(~100
and {lOil}
with
p.p.m.) the hydride precipitates
removed
during grinding which were not comby
chemical
polishing
and
that
in platelets lying parallel to {IOiO} planes of the zirconium matrix. Kunz and Bibbc2) reported however
subsequent
that the hydride precipitates as platelets on the twinning planes, i.e. (lOi2) (1121) and (1122). A further
X-ray studies of the zirconium hydrogen phase diagram by Gulbransen and Andrewc4) and Whitwamf5) appear to lead to the conclusion that two stable hydride phases exist, a face centred cubic and
ACTA METALLURGICA VOL.
11;
APRIL
1963
may have occurred
in these twins.
study by Westlake and Fisherc3) supported the work of Langeron and Lehr (l) by showing that the hydride platelets precipitated predominantly on {lOiO} planes together with some platelets of secondary importance * Received April 28, 1962. t Berkeley Nuclear Laboratories, Central Generating Board, Berkeley, Glos., England.
hydride precipitation
a face centred tetragonal phase designated 6 and E respectively, together with a minor metastable phase having a face centred tetragonal structure and desig-
Electricity 267
nated yl. The metastable y1 phase was found only in association with the 6 phase. However, Vaughan
ACTA
268
METALLURGICA,
and Bridgec6) on the basis of their high temperature X-ray
studies
exists whose position
concluded tetragonitl
that
one
structure
and temperature.
hydride
varies
The phase
phase
with
com-
diagram
ac-
cording to Vaughan and Bridge@) and Ellis and McQuillan(7) suggests that the hydride platelets formed from solutions
containing
tents may be the 6 phase. obtained electron diffraction
low hydrogen
con-
Schwartz and MalletW evidence which suggests
VOL.
11,
1963
Studies were also made of zirconium quenched
an inert atmosphere. The zirconium foils after being given the appropriate treatment, were thinned by electropolishing and examined in a Siemens electron microscope 100 kV.
of perchloric
acid to 90 parts glacial acetic acid.
bath
was operated
which
stirred and kept cool.
X-ray studies have been unable to detect the structure
men was removed
of these precipitates at low hydrogen concentration. The precipitates are of considerable importance since hydrogen
of zirconium
that occurs
concentrations
appears
present
the
to
be
with them. In
the
3.1
Zirconium
After work
transmission
electron
microscopy techniques and supplementary X-ray experiments have been used to study the precipitation
at The
at 20 V was vigorously
When suitably
thin the speci-
and washed in distilled water.
3. ELECTRON MICROSCOPE OBSERVATIONS
at low
associated
operating
The polishing bath used consisted of 10 parts
that these platelets were a tetragonrtl phase. To date,
the embrittlement
foils that were
into iced brine after annealing at 800°C in
foils-vacuum
this treatment
contain hydrogen
annealed
the foils
were expected
in concentrations
An electron micrograph
of ~10
to
p.p.m.(*)
taken from a typical
area of
of hydride in zirconium at low hydrogen concentrations
one of these foils is shown in Fig. 1 (a) ; a high density of small clusters is observed which must result from
The
the presence of some impurity.
technique
has clearly
hydride precipitates both
the
crystal
revealed
the
zirconium
and provided evidence concerning structure
of the precipitates
and
their stability. 2. EXPERIMENTAL
The
majority
of the
obser-
vations have been carried out on commercial
and re-
These clusters were The clusters could
be made to disappear in the same temperature range as hydrogen was found to precipitate from solution (these experiments
microscope
actor grade zirconium
electron
observed in all the foils examined.
are
described
below).
clusters that form preferentially
Furthermore,
on both
the grain
supplied by Murex Ltd., in the
form of foil of thickness 0.010 in.
Both grades had a
hardness in the annealed condition of ~200 VHN; no distinction will be made between these grades since their
behaviour
was
experiments. Some observations
identical
in
the
following
have been made on argon arc
melted crystal bar zirconium,
which is purer than the
grades described above and has a hardness number of ~100 VHN when fully annealed. The few experiments in which
this material
was used are clearly
identified below. Foils of suitable size were annealed at temperatures of about 800°C for several hours in a vacuum of & 10P5 mm of Hg to remove any residual hydrogen. The analyses carried out by Schwartz and Mallet@) show that this treatment reduces the hydrogen content to below 10 p.p.m. The vacuum apparatus
incorporated
a palladium
leak through which the required amounts of hydrogen were passed into the system. Hydriding was generally carried out by heating the zirconium foil to 800°C in a known pressure of hydrogen and allowing the specimens to furnace cool. In order to obtain a faster cooling rate some foils were heated electrically quenched by switching off the current.
and
FIG. l(a).
Small clusters observed on zirconium foils ( x 26,000).
electropolished
BAILEY:
PRECIPITATION
OF ZIRCONIUM
FIG. l(b). Clusters formed preferentially on grain boundaries lie on the surface of the foil ( x 26,000).
boundaries
(Fig. l(b))
and on dislocations
(Fig. l(c))
appear to be either on the top or bottom the foil.
surfaces of
From the above evidence it is concluded
these clusters are hydride
that
clusters which form on the
surface of the foil during electropolishing. The density of such clusters seems to depend sensitively on the polishing conditions.
Some specimens show relatively
few clusters and there is often a wide variation
in the
269
HYDRIDE
FIG. l(c). Clusters formed preferentially on the points of emergence of dislocations from the foil ( x 26,000). needle-like vations.
will be used here to describe These
precipitates
can
seen in Fig. 2(c).
Fig. 2(c) also shows that some pref-
erential precipitation
occurs on grain boundaries.
Fig. 2(b) shows the same area as Fig. 2(a) after tilting the specimen to produce different diffracting conditions.
A
semi-circular
“halo”
now appears
same specimen.
strong Bragg reflections are operating the double
clusters when referred to below. 3.2
Zirconium
These observations been hydrided
area.
foils-hydrided to contain
~500
on foils that had
p.p.m.
of hydrogen.
Figs. 2 and 3 show examples of the hydride precipitates observed in the furnace
cooled specimens.
It is clear
from Fig. 2(a) that the hydride precipitates assume a needle-like appearance at a very early stage of growth, and electron diffraction patterns show that these “needles” have axes lying along (1120) directions. When the plane of the foil is accurately parallel to the basal plane of the zirconium the hydride “needles” appear very thin as shown in Fig. 2(c). This evidence suggests that these “needles” are really platelets lying parallel to {IOiOo) planes which is in agreement with the metallographic work,(1,3) however, the term
dislocation
contrast Two
as indicated
images observed
by
in the same
that this contrast is due to the
strains induced
the precipitate
type
on one side of the precipitates.
It is considered
coherency
were made
distin-
guished from the surface clusters which can also be
density of clusters observed from different areas of the These artefacts will be called surface
the obser-
be clearly
in the matrix
surrounding
and is a similar effect to that observed
around G.P. [2] precipitates (Nicholson and Nutting@)). The larger needle-like
precipitates,
an example
of
which is shown in Fig. 2(d), result from the continued growth of the small precipitates; this is borne out by the electron beam heating experiments described in $4. As the precipitates
increase in size arrays of dis-
locations are observed to be associated with them. At this stage the precipitates must be incoherent on certain faces. Electron diffraction patterns taken from areas including these precipitates have so far failed to reveal diffraction spots that cannot be attributed to the zirconium matrix. These needle-like precipitates all have axes lying along the (1120)
ACTA
270
METALLURGICA,
VOL.
11,
1963
FIG. 2(a). Smell hydride precipitates in zirconium hydrided to contain &500 p.p.m. of hydrogen ( x 40,000).
FIG. 2(b). Same area as shown in Fig. 2(a) after tilting the foil to produce different diffracting conditions ( x 40,000).
directions
of the zirconium
matrix
has
obtained
suggests
been
orientations. Hydride precipitates
which
and no evidence other
possible
that were generally relatively
large in two dimensions compared with those described above were also found in these specimens ; examples are shown in Fig. 3(a) and (b). Diffraction patterns obtained from these precipitates suggest that they are the “so called” metastable y1 phase (see $5).
These large precipitates also have arrays of dislocations associated
with them.
Attempts
to find precipitates
that could be clearly interpreted as the 6 hydride phase have not been successful. Zirconium specimens that were electrically heated and quenched in the hydrogen atmosphere by switching off the current showed the presence of both long needle-like precipitates (Fig. 4(a) and (b)) and precipitates which appear wide in a direction normal to
BAILEY:
FIG. 2(c).
PRECIPITATION
Preferential precipitation of hydride boundaries ( x 11,000).
on grain
(a)
ZIRCONIUM
FIG. 2(d).
211
HYDRIDE
Needle-like
hydride precipitate
( x 26,000).
(b)
FIG. 3(a) and Fig. 3(b). Examples tain
OF
-500
of the large hydride p.p.m. of hydrogen
Pre:cipitates found is furnace cooled specimen and x 13,000 respectively). (x 26,000
hydrided
to con-
ACTA
252
(a)
METALLURGICA,
VOL.
11,
1963
(b)
FIG. 4(a) and FIG. 4(b). Examples of needle-like precipitates in rapidly cooled hydrided zirconium foils showing clearly the associated dislocation structures ( x 22,000 and x 26,000 respectively).
Fm.. 4(c) Hydride precipitate large in two dimensions also observed in rapidly cooled hydrided specimens ( ~26,000).
BAILEY:
(1120)
axes
(Fig.
4(c)).
PRECIPITATION
The precipitates
OF
that
are
ZIRCONIUM
periments
273
HYDRIDE
in which localized
regions of the electron
similar in habit to those shown in Fig. 3(a) and (b).
specimens have been heated by increasing the intensity of the electron beam. The electron beam
The majority
is reduced to a minimum
large in two dimensions
ofthe precipitates
specimens were however, dislocation arrangement precipitates
is clearly
The dislocations the precipitate
Zirconium
in these rapidly cooled of the needle-like type. The surrounding the needle-like
revealed
in Fig. 4(a) and (b).
are generally attached or appear
closed elongated the precipitate 3.3
e.g. Fig. 4(c), would appear
to the ends of
as completely
or partially
loops running parallel to the axis of
into iced brine
of the
quenching
needle-like
zirconium
argon atmosphere diffraction
foils annealed
by
at 800°C in an Electron
taken from areas including phase and X-ray
below confirmed this interpretation
These quenched
specimens
tain any of the “two discussed
high
these
contained spots which could be interpreted
in terms of the y1 hydride described
precipitates
into iced brine (Fig. 5(a)).
patterns
precipitates
hydride
of zirconium
dimensional”
studies (see $5).
did not con-
type precipitates
above. BEAM
HEATING-STAGE
Considerable
information
in order to increase the
of the beam ; the specimen
heated by increasing the beam current. cedure a hot zone is produced is surrounded Micrographs
(~5
is then
By this pro-
,u diameter) which
by a sharp radial temperature
gradient.
are taken after reducing the beam current
is illustrated
in such an ex-
in Fig. 6. An area of vacuum
annealed crystal bar zirconium is shown in Fig. 6(a) in which several needle-like hydride precipitates are present. beam
On heating with a suitably
(15 ,uA) for several seconds
disappear.
On rapidly
new precipitates
reducing
intense electron
these precipitates the electron
nucleated and grew;
beam
these are shown
in Fig. 6(b).
Repeating
intense
(20 ,uA), i.e. heating to a higher tem-
beam
this procedure
perature,
reduces
specimen
since no precipitation
Fig. 6(c).
4.’ ELECTRON
and the condenser I aperture
removed
general intensity
periment
It was found possible to produce a relatively density
of the microscope
rapidly and replacing the aperture. The type of behaviour observed
(Fig. 4(a)). foils-quenched
microscope
the amount
with a more
of hydrogen occurred
in the
on cooling,
Further beam heating at a lower intensity
(10 ,uA) again caused the nucleation
and growth
EXPERIMENTS
relatively
It is concluded
has been gained from ex-
from these experiments
HEATING
AND
FIG. 5(a). Needle-like hydride precipitates in zirconium foils quenched into iced brine from 800°C ( x 26,000).
large precipitates
FIG. 5(b).
(Fig. 6(d)).
of
that there must be a residual
Removal of the precipitates shown in Fig. S(a) by election beam heating ( x 26,000).
ACTA
274
(cl FIG. 6. Sequence of micrographs
METALLURGICA,
VOL.
11,
1963
(4 showing the effect of electron beam heating on hydride precipitation.
(See text)
(x
13,000).
BAILEY:
pressure of hydrogen
inside the electron
from which hydrogen specimens.
PRECIPITATION
is absorbed
The above experiments since they demonstrate precipitates directions
shrink
from
microscope
by the zirconium
The source is considered
present in the microscope tamination originates.
OF
to be the oils
which
carbon
are of considerable clearly
and grow
interest
that the needle-like rapidly
these beam heating experiments cipitates
disappeared
temperature
range as the normal hydride precipitates
do
not
imply
that
another
form
of
does not
for the “punching precipitates
these experiments.
In Fig.
e.g.
either with some precipitated
present.
The removal
with
cipitates
by electron
panied
beam heating
by the complete
surrounding
them;
removal
accom-
of the dislocations
for example the precipitates
and B, Fig. 5(a), were observed appear together
is often
at A
to shrink and dis-
with their associated
dislocations
as
shown in Fig. 5(b). Experiments
been carried
out using a cali-
brated heating stage in order to determine perature
at
removed.
which
the
hydride
has a relatively
being of the furnace
at temperatures
are
type.
of
heating experiment be explained.
by
ential cooling
events
the impurity
described
beam
above (Fig. 6) can now
Since the precipitates
become unstable
The loops
At
300°C
(Schwartz
the
terminal
and MallettP)
< C,
at 300°C in this case.
solubility
is ~100
and Gulbransen
p.p.m.
and An-
drew(lO)) and therefore pH is < 10-5. Since the terminal solubility decreases with decreasing temperature, on rapidly
cooling
(Fig. 6(b)).
the
Reheating
specimen
precipitation
occurs
the specimen to a higher tem-
perature reduces the value of C, sufficiently to prevent precipitation on subsequently quenching (Fig. 6(c)). Further heating of the specimen to a temperature below 300°C again raises the value of C, to a value above C and precipitation It was also observed
occurs directly,
Fig. 6(d)).
that on heating a specimen to a
temperature at which the precipitates in the hot zone disappear, precipitates were appearing in the region surrounding the hot zone, this situation is similar to that observed in Fig. 6(d), since in this region the temperature is such that C, > C. Occasionally circular type precipitates surrounded by dense tangles of dislocations
were observed during
by the differset up
and impurity
during particle.
arrangements
loops
and more
which
resemble
been produced
by a hydride
this procedure
removed
the hydride
at B (Fig. 8(b)) and has nucleated Numerous
new
loops are now observable
in
the field of view and these must be associated with the hydride
appear
precipitates. (1120)
precipitates.
to be “thrown
In
off”
these
loops
the sides of the
and since they must glide in this
the Burger’s type.
vectors
are expected
to be of
In the case of these hydride pre-
cipitates, ‘loops and dislocations growth
general
from
All arrays of loops have axes parallel to
directions,
the l/3(1120)
C, in the specimen such that C,
or
This has been confirmed by beam heating
the specimen;
H, in the microscope
C being the terminal solubility
out”
has produced
at B have
precipitate.
direction
concentration
particle
dislocation
at 300°C it would appear that the residual pressure of pH gives rise to an equilibrium
hydride
case of impurity
stresses
the matrix
are always
closely the similar effects observed inmagnesium.(11-13)
precipitates.
in the
In the
contraction
between
these
An example of this effect can be seen at A in Fig. S(a) ;
new
observed
C;
the loops are “punched
These experiare removed
B and
particles.
thermal
precipitate
of about 300°C.
sequence
particles
large thermal
ments show that the hydride precipitates The
the tem-
precipitates
The heating stage which was supplied
Siemens and Halske capacity,
impurity
complex
have
at A,
from
S(a) arrays of loops are
observed,
pre-
is
out” of complete loops
associated
hydride
hydride
has also been obtained
observed however that hydride precipitates do nucleate preferentially on dislocations when they are of the zirconium
These pre-
in the same
precipitating. Evidence
It is
(Fig. 7).
and reappeared
and it is considered that they may result from the growth of the surface clusters described in $3.1, and
by hydride
require the presence of dislocations.
275
HYDRIDE
(1120)
along
of the matrix and that nucleation
necessarily
con-
ZIRCONIUM
and it is difficult
are produced
to distinguish
during
additional
loops that may be produced during cooling. Some preliminary cooling stage experiments do suggest however that loops can be produced
on cooling.
5. CRYSTALLOGRAPHIC ANALYSIS HYDRIDE PRECIPITATES
OF THE
5.1 Structure of the hydride precipitates
Electron diffraction patterns were easily obtainable from the large precipitates (Fig. 3) observed in slowly cooled
zirconium
specimens.
from the precipitates
The pattern
obtained
in Fig. 3(a) is shown in Fig. 9.
These patterns could be accurately interpreted in terms of the tetragonal y1 phase using lattice parameters given by Whitwam.c5) Although the yl phase may be treated as a slight distortion of the S f.c.c. phase, the distortion is sufficient to be detected on the electron diffraction pattern, e.g. the angle between (ill) and (202) for the y1 phase is 93” as was observed on the diffraction pattern taken from the precipitate
276
ACTA
METALLURGICA,
VOL.
11,
1963
FIG. 7. Circular type hydride precipitates sometimes observed during electron beam heating experiments ( x 20,000).
FIG. 8(a). Examples of “punched out” dislocation loops produced by hydride precipitates and impurity particles.
BAILEY:
PRECIPITATION
OF
ZIRCONIUM
HYDRIDE
FIG. 8(b). Same area as Fig. 8(a) after the production of hydride precipitates by electron beam heating (x 20,000).
FIQ. 9. Selected area electron diffraction pattern taken from the large precipitate shown in Fig. 3(a).
shown in Fig. 3(b);
this angle should be 90” for the
the electron
diffraction
the precipitates
8 phase. Electron
diffraction
patterns from the thin needle-
like precipitates have been more difficult to obtain. Patterns were occasiona,lly obtained from the
For the large precipitates the orientation
Previous
X-ray studies have been unable to detect
with certainty the needle-like hydride precipitates found in zirconium at low hydrogen concentrations. In t’he present York it was found
that a large con-
centration of these precipitates could be produced by quenching zirconium foils from 800°C int,o iced brine ($3.3) and therefore an attempt was made to determine their crystal structure by X-ray studies. X-ray diffraction photographs were taken with a Guiner focussing camera permitting the simultaneous examination of the quenched and unhydrided foils: using monochromated MO K, and Cu K, radiat’ion. The quenched foils clearly showed the presence of additional
reflections
from
the hydride
precipitates
which corresponded closely to t’hose observed by Whitwamc5) from the phase designated y’. These reflections
could be indexed
the strong prominent
on a trtragonal
cell and
lines were :
d Z”2 = 1.A75 *
These
values
A further
r = 1.HX8 A
orientation
wit’h those
of
out on slowly
yl phase, and not to the face centred cubic that
available,
is identical
{ll:O},
and (lOlO),,
{llzO),
is parallel to {llO},,1 and
(IOTO}, is almost parallel to {131);,1 (ml” inclination). It is assumed here that the habit planes are the planes perpendicular to the foil. By similar arguments the habit planes of the needle-like precipitates platelets
are {lOTO), parallel to (11 l}+
if these are The change
in habit during growth from platelets to massive precipitates is not easily explained since it would not result from a straightforward thickening of the platelets as suggested by the form of the precipitate in Fig. 4(c);
such a thickening
would
suggest
(liOO),
parallel to (Ill),,1 as a habit plane. It may be of significance that the (131},1 type planes appear to be habit planes. The spacing of (lOlO},
planes c&,,
= = to
6. DISCUSSION
to the
6 phase.
the hydride
at these low hydrogen
and electron
“two
and rapidly
dimensional”
diffraction
studies estab-
precipitates
observed
cooled zirconium
precipitates
in
foils and the
observed
in the rela-
cooled foils both have a face
centred
tetragonal structure corresponding closely to the y1 st,ructure previously detected in zirconium cont,aining
c = 4.960 P,
therefore
evidence
wit’h (1). From the shape of the two large precipitates (Fig. 3(a) and (b)) the habit planes would appear to be
quenched
hydride were again found to clearly correspond
observed
the
t’ively slowly
was then carried
It is concluded
From
lished that the needle-like
cooled zirconium foils containing ~1000 p.p.m. of hydrogen and the additional reflections due to the
cipitates
the
relationship for the needle-like precipitates
The X-ray
arc t’o be compared
study
(1)
(1 l20), parallel to (I lO)+ 1
and
for the y1 phase :
IL = 1.610 A
(TI1)71
these planes.
(202) reflrctions are :
Whitwam
can be expressed as:
2d (131j; the two lattices fit therefore nearly perfectly (misfit 0.07 per cent) in the direction normal to
0.005 a
as calculated from the (Ill)
a = 4.617 B
relationship
them.
2.798 and the spacing of the {131},1 planes do,,, 1.396, and hence d,,,I,, is almost exactly equal
dzoo= 2.28 -f 0.01 a The cell dimensions
from both
shown in Fig. 3(a) and (b)
(IlOO), parallel to
“quenched in” precipitates discussed in $3.2. These patterns were also interpretable HAdue to a tetragonal phase.
patt’erns obtained
and the matrix surrounding
prc-
concentra-
the face centred cubic hydride phase (Gulbransen Andrew(d) and Whitwam(5)).
Furthermore,
and
the X-ray
work showed that the y1 phase was present in slowly cooled zirconium foils containing ~1000 p.p.m. of hydrogen; no evidence for t)he presence of the f.c.c. B phase was obtained.
It is concluded
the hydride phase in zirconium
therefore that
at low hydrogen
con-
tions have the tetragonal y1 structure for which c/a > 1
centrations
and lattice parameters of Q = 4.617 A and c = 4.888 1%arcording to the present X-ra.;v study.
to be expected according to the current phase diagram.
5.2 Orientation
These results confirm the previous work of Schwartz and Mallett(*) who concluded that the needle-like
and eirconium
rp,latio?lshipsbetlc~epn
h!/rlrid~preci~itcxths
matrix
The orientation
relationships
( < 10 at. ‘A,) is a face centred tetragonal
phase and not the face centred cubic 8 phase which is
hydride precipitates wclre dct,crmined from
were a tetragonal phase analogous
to that found in the H,-H
spst,em.
BAILEY:
PRECIPITATION
The needle-like zirconium hydride precipitates axes lying along (1120) directions it is clear
therefore
that
OF
have
of the matrix,
if these
precipitates
and are
platelets they must lie parallel to planes of the form (101x); the evidence suggests that they are parallel to (1010) planes, which is in agreement with the observations
of Langeron
and Lehro)
and Westlake
No evidence for precipitation on and Fisher.c3) twinning planes has been obtained. These precipitates which appear coherent when small ($3.2) grow easily along the direction
of their axes and the observations
show that as they grow in thickness dislocations
associated
the number
of
with them increases, e.g. com-
pare the thin precipitates
in Fig. 5(a) with those in
ZIRCONIUM
279
HYDRIDE
occasionally,
e.g. around some precipitates
and 8. One dislocation 30 (loio),
spacings
in Figs. 4
will be required roughly every in order
to
accommodate
the
strain ; thus for the large precipitate in Fig. 4(b) which is ~1500 A thick about 20 dislocation loops would be expected. This figure is close to the number of segments observed. In cases where complete loops appear to be given off, e.g. at B in Fig. 8(a) their axes appear to lie along (1120) directions suggesting that the Burger’s vectors of the loops are the normal i (1120)
type.
dislocation cipitate
It is clear that the long segments
of
and sides of the loops parallel to the pre-
axis must
glide
away
on the basal plane.
These results therefore provide evidence for slip on the
Figs. 4(b) and 2(d). It is considered therefore that some interfaces of the precipitates become incoherent
basal plane in zirconium under appropriate conditions. Hydrogen forms an interstitial solution in zirconium
during the thickening
and can migrate rapidly at relatively low temperatures
process.
Consider precipitates
with axes [1210], then the spacing of the planes of the matrix
and precipitate
and (ill),,,,
normal to [lOiO],
i.e. (lOiO),
are 2.798 A and 2.706 A respectively.
If
( <300°C) to form hydride precipitates. At these low temperatures appreciable concentrations of point defects produced
thermally
are not expected
and it is
the strain resulting from growth in the [lOiO], direction is accommodated by dislocations then ideally
considered unlikely that a large proportion of the strain associated with the growth of the precipitates
prismatic
can be accommodated
dislocation
loops would be punched out in planes parallel to (lOTO),. These loops will be vacancy loops since the matrix spacing is larger than the precipitate spacing. However, the precipitates do not necessarily thicken uniformly in the [lOTO], direction and complete
loops may not form;
instead the seg-
7. CONCLUSIONS
A study
has been made
p.p.m.
of hydrogen
illustrated in Fig. 10. This will, in general, be the case -since the precipitates grow preferentially in the [1210],
scopy.
Electron
direction precipitate
will end on the precipitates,
and will therefore
taper at their ends; the Evidence
at A in Fig. 7 is a good example.
for the punching
out of complete
loops can be found
of the morphology
and
crystallography of the zirconium hydride precipitates formed in zirconium specimens containing
as
ments of dislocation
by such defects.
by transmission
and X-ray
electron
diffraction
micro-
evidence
has
shown that all of these precipitates have a tetragonal structure similar to the y1 phase, (Gulbransen and Andrewc4)
and Whitwamc5)).
In rapidly
cooled
or
quenched specimens the precipitates appear needlelike with axes lying along (1120) directions and may be interpreted as platelets parallel to {IOiO} planes of the matrix. In slowly cooled specimens the precipitates are comparatively large in two dimensions. Identical orientation relationships between hydride and matrix hold for both types of precipitate. It is concluded ticular
from
nucleation
the
from the observations beam
heating
of the hydride precipitates
sarily require
the presence
preferential precipitation
liner
FIG. 10. Illustration of the formation of dislocation segments during the growth of the precipitates in the [lOTO] directions. 4
that
does not neces-
of dislocations
although
will occur if they are present,
as well as on grain boundaries.
Wslocation
and in par-
experiments
These experiments
showed that under the conditions operating in the microscope the hydride precipitates become unstable and were completely removed at temperatures of -3oo”c. The needle-like precipitates which are considered to be responsible for the hydrogen embrittlement of zirconium grow rapidly along the direction of their
280
ACTA
METALLURGICA,
axes and apparently remain coherent; growth in the direction normal to their axes is accompanied by the formation of dislocations and the precipitates become incoherent on the appropriate faces. ACKNOWLEDGMENTS
The author is indebted to Dr. G. K. Williamson for his critical discussion of the content of this paper. He particularly wishes to thank Mr. W. T. Eeles for his advice and help in carrying out the X-ray experiments. He is also grateful to Mr. R. Redford who constructed the hydriding apparatus and Mr. G. Rickards for assistance in electron microscopy. This paper is published by permission of the Director of the Berkeley Nuclear Laboratories, C.E.G.B., Berkeley, Glos.
VOL.
11,
1963 REFERENCES
;: 3. 4. :. 7: 8. 9. 10. 11. 12. 13.
J. P. LANQERON and P. LEHR, Rev. M&all. 60, 901 (1958). F. W. KUNZ and A. E. BIBB, Trans. Amer. Inst. Min. (Metall.) Engm. 218, 133 (1960). D. G. WESTLAKE and E. S. FISHER. Trans Amer. Inst. Min. (Metall.) Engrs. 224, 254 (1962): E. A. GULBRANSEN and K. F. ANDREW, J. Electrochem. sot. 101,474 (1954). D. WHITWAM, Mem. Sci. Rev. MetalE. LVII, 1 (1960). D. A. VAUQH~N and J. R. BRIDLE, J. Metals 8,528 (i956). C. E. ELLS and A. D. MCQUILLAN, J. Inst. Met. 85, 89 11956). C. M. SCHWARTZand M. W. MALLETT, Trans. Amer. Sot. Metals 46, 640 (1954). R. B. NICHOLSON and J. NUTTING, Phil. Mag. 2, 531 (1958). E. A. GULBRANSEN and K. F. ANDREW. J. Metals 7. 136 (1955). A. FOURDEUX and A. BERQHEZAN,C. R. Acud. Sci. Paris 252, 1462 (1961). S. LALLY and P. G. PARTRIDOE. To be published. R. I. HUTCHINSON. Private communication. \----I-