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The position of gray tin in the tin-mercury system
THE
POSITION
OF GRAY
TIN
IN THE
P. H. VAN
TIN-MERCURY
SYSTEM*
LENT?
The determination of the solubility of gray tin and white tin in mercury at temperatures below 0°C is described. From these measurements, the phase-fields of gray tin could be added to our knoudcdge of the tin-mercury system. Gray tin can be in equilibrium with a solution of tin in mercury in the temperature range between -7.5 f l.O”C and -35.2 I_t 0.2”C. A mechanism is proposed for the transformation of white tin amalgams. LA
LOCALISATION
DE
L’ETAIN GRIS DANS ETAIN-MEBCURE
LE
DIAGRAMME
D’ETAT
L’auteur d&Gritla c~~~~&tion de la solubiliti de l’etain gris et de J’etain blanc dans Ie mercure aux tempbatures inferieures Q 0°C. Ses mesures permettent de determiner les domaines de phase de I’etain gris dans le diagramma d’etat Btain-mercure. L’etain gris peut etre en Bquilibreavec une solution d’etsin f 1,O”C et -35,2 f 0,2”C. L’auteur dans du mercure pour des temperatures comprises entre -75 propose une m&anisme de transformation des amalgames d’etain blanc. DIE
LAGE
VON
GRAUEM
ZINN
IM
SYSTEM
ZINN-QUECKSILBER
Die Bestimmung der Losliehkeit van grauem und w&BernZinn in Quecksilber bei Temperaturen unter 0°C wird beschrieben. Mach diesen ~essun~n konnten die Phasenfelder des grauen Zinns unserer Kenntnis des Systems Zinn-Quecksilber hinzugefiigt werdan. Graues Zinn ktannmit einer Losung von Zinn in Quecksiiber im Temparaturbereich zwischen -75 + 1,O”C und -35,2 f 0,2”C in Gloichgewicht &hen. Fur die Transformation von Amalgamen des w&J&nZinns wird ein Mechanismus vorgoschlegen.
INTRODUCTION
New interest has arisen in the tin-mercury after Ewald and Tufteo)
system,
succeeded in growing gray tin
single crystals from a solution of tin in mercury. Gray (a) tin is not included in the phase diagram given by Hansen(Q, a summary of all known investigations J’sn white
in
the
field
Heteren@), and
difference
of
when
gray
the
tin-n~er~ur.~
measuring
tin in mercury
between
the
of
at 0°C found
no
both modifications
and was not able to indicate
system.
solubility
in this respect
the position
of gray tin
in the diagram. According to Cohen and van Lieshout(
gray tin
is stable
below
132°C.
In the
phase
diagram
Fro. I. The tin-mercury phase diagram according to Hansen.
of
Below
Hansen (Fig. 1) three intermediate phases occur, of which two can exist at temperatures where gray tin is stable.
According
to the investigations
of Green’s),
reports-referring
indicated
by the formula
suggests
HgSnl, 9 although its tin content may vary from This phase is formed when about 88-94 at. y& white tin is brought into contact with mercury at temperatures above the melting point of mercury. * Received February 13, 1960.
VOL. 9, FEBRUARY
1961
phase
is
to
unpublished
results
of
Pry-
the occurrence
of still another
phase,
the
so called S-phase, which would be stable below 9O”C, in order to be able to explain thermal effects found at 90°C. No other investigator has ever confirmed these effects. Moreover, as we found that HgSn,, crystallizes from a solution of tin in mercury at room
1 Physical Laboratory of the National Defense Research Council of the Netherlands (R.V.G.-T.N.O.), The Hague. ACTA META LLURGICA,
intermediate
therch-the formula HgSn, for this phase; but others considered the formula HgSn or HgsSn more and Bornemann( Gayler also likely (Guertler”)
At higher mercury concentraphase is formed. This phase is
called the y-phase generally
a second
as can be concluded from the measurements The composition and crystal of van Heteren@). structure of this phase are unknown. Gaylex(‘n
with microscope and X-ray techniques, not more than 0.1 at.% mercury can dissolve in white (P) tin at room temperature. tions an intermediate
-34.6”C
stable,
temperature, we think phase is very unlikely.
125
that
the
existence
of this
ACTA
126
METALLURGICA,
VOL.
9, 1961
gray tin in the phase diagram 0 t 0 IO n + 0t
20 .u
from these measure-
ments.
van ~etefwl Gouy Joyner Ourmeasurements
EXPERIMENTAL
For
the
PROCEDURE
determinations
AND
of
the
RESULTS
solubilities
two
small glass tubes were used, each closed at one end with
a rubber
tube
and a pinch-cock,
other end with a rubber stop.
and at the
They were filled with
about 50 g mercury, purified by air oxidation and vacuum distillation. One tube was cooled to -40°C 0,. %
and then 0.5 g gray tin powder was added.
tin
was stored during 12 hr at -20°C.
FIG. 3. Mercury rich part of the tin-mercury phase
in the other tube about
dia.gram.
At low temperatures
the tin-mercury
system
was
investigated by van Heterenf3). His results are given in Fig. 2 together with points found by Joynercg) and Gouy(lO) in the vicinity points
of the liquidus
found by saturating 1 hr and analysing
of room at -18.8
temperature.
The
and 0°C have been
mercury with white tin during the solution. The solubilities
found in that way were 0.36 and 0.59 at.%, respectively. In another experiment mercury was saturated with white tin and with gray tin at 0°C during 5 hr. The solubilities found in that way were 0.62 and 0.60 at.‘+&, respectively. have been found
The other points
by van Heteren
in the slopes of cooling
in Fig. 2
from the changes
and heating
curves of amal-
gams with a well known composit#ion. From the measurements of van Heteren it appears that above -34.6% HgSn,a can be in equilibrium with a solution of tin in mercury.
This tube
To the mercury
0.5 g white tin powder was
added at room-temperature
(about 20°C).
It was kept
at this temperature, to exclude the presence of gray tin nuclei, (which may be present in the atmosphere) which
react
readily
at 20°C with
mercury,
under
formation of HgSn,,. The tubes with tin and mercury were suspended in a dewar-tube, filled with solid and liquid
of various
salt-water
eutectic
mixtures
(pre-
pared beforehand) and agitated intensely for 8 hr. After this the tubes were removed from the dewar, and by means of the pinch-cock solution
about
was drained and collected.
of the solution was determined
40 g of the
The tin content
by gravimetric
(as SnO,). The results are given in the following
analysis
table
and
have been plotted in Fig. 2. Here the two curves represent the liquidus curves of grsy tin and of BgSn1,.
Below this tempera-
TABLE
1
ture and above the mehing point of mercury (-38.9”C) the saturated solution is in equilibrium with HgSn,( 2). According to Ewald and Tufteo), HgSn,, crystallizes from above
a supersaturated about
-3O”C,
phase diagram.
solution
of tin in mercury
in agreement
However,
with the known
after 1 week at tempera-
tures in the range from -10”
to -3O”C,
vanished solution.
crystallized
and
gray
tin
From these observations
has
HgSn,,
has
from
the
we can conclude
that in
this temperature range gray tin can be in equilibrium with a solution of tin in mercury, but the nucleation
MaClz + Ho0 N&l+ Ha0 Na&03 + Hz0
- 33.6 1 0.242 0.243 0.243t 0.270 0.267 0.269 ~ 21.2 0.344 0.344 0.344 0.371 0.367 0.369 ~ 10.2 1 0.470 0.463 0.467) 0.4Q4 0.490 0.492
ZnSofffgH=o 2
--6.55 0.00 0.564 0.662 0.568 0.656 0.566 0.659~ ;0.561 0.656 0.559 0.656 0.560 0.656
THE
POSITION OF GRAY TIN TIN-MERCURY SYSTEM
As expected, in the temperature -10’ and -32.2”C the solubility
IN THE
range between of gray tin in
of gray tin is retarded to such extent, that HgSn,, crystallizes as a metastable phase. Thus the points
mercury is smaller than that of HgSn,,. At -6.5% the solubility of HgSnr, is the smaller one. From Fig. 2 it appears that the solubility of both phases is
measured by van Heteren in this temperature range represent metastable equilibria. In the course of investigations on the semiconductive properties of gray tin, we have determined the stable and metastable liquidus of the tin-mercury
the same at -7.5%. So this represents the temperature of the three-phases equilibrium: L-c&n-HgSn,,. At 0°C we found the same solubility for gray tin and with van Heteren), since HgSn,a (in agreement evidently gray tin at this temperature reacts with
system in the temperature range from 0” to -32.2%, by measuring the solubility of gray and white tin in mercury. We were able to indicate the position of
mercury to form HgSn,,. From the measurements at 0°C we may conclude that the equilibrium conditions arc reached in 8 hr.
VAN
Resulting
LENT:
GRAY
TIN
from a high or a low tin concentration,
IX
THE
SYSTEM
127
THE TRANSFORMATION CONTAINING A FEW PER
the
measured values agreed within 0.5 per cent. Their accuracy is fixed by the errors in the gravimetric
Sn-Hg
The
transformation
from
OF WHITE TIN CENT MERCURY
white
to
gray
tin
is
determinations. As the duplicates on the average differ less than 1 per cent from the measured values,
accompanied 20 per cent),
by a large volume expansion (about with the result that the gray tin falls
we estimate
into pieces.
Groen(12>5) showed
per cent.
the error in our measurements
The
equilibrium
error
in the
temperature
not more than at -6.5”C
of L-&-HgSn,,
&l.O”C,
at 10.5
determination
of
the
is certainly
but likely less, as we found
a definite difference between the solubility
of gray tin and HgSnlz. This result agrees with the observations and Tufte’l)
of Ewald
Mercury
which has a retarding influence on the transformation. As can be seen from the phase diagram, in the temperature range from -7.5” to -35.2”C transformation of of HgSn,,
In a recent article, Smith(ll)
describes the determina-
According
tion of the same three-phases
equilibrium temperature,
white tin at the transformation
method.
He found
-8.15
i
with our measurements.
also
e.g. lead,
a few per cent mercury,
agreement
crystal-
of mercury.
of other elements,
white tin, containing
a dilatometric
only HgSn,,
a small amount
suppresses the influence
pieces
that the tin
practically
O.l”C in excellent
-10°C
contains
that compact
provided
lizes from the mercury solution, and that above 1°C mercury reacts rapidly with gray tin to form HgSn,,.
using
that above
of gray tin can be obtained,
a mixture
be accompanied
by the liberation
to Fig.
of metastable
1, the mercury
HgSn,,.
transformation
(being
and white tin,) will of free mercury. reacts
with
the
front, under formation
But when all white tin at the
front
has reacted,
mercury
can be
However, no other points of the phase diagram were given by him. The values of the solubility of white
piled up to more or less extent. The mercury does not form a complete
tin at -18.8”C
to the transformation,
as tin can diffuse through
from the untransformed a result of the solubility
to the transformed part, as difference between the stable
with
and 0°C of van Heteren agree poorly
our results.
Probably
equilibrium
conditions
were not reached in his measurements. The temperature of the three-phases
equilibrium
L-crSn-IHgSn,(?)l(2) is given by the intersection of the liquidus curves of gray tin and HgSn,(?). This temperature is -35.2”C as follows from Fig. 2. As the slope of the liquidus
of gray tin is considerably
and the metastable accounts
phase.
for the coherence
hindrance
This mechanism
it
easily
of the gray tin and the
suppressing of the influence of the retarding elements, for these are solved in the mercury and do not play any active part in the transformation. Investigations in
steeper than that of HgSn,(?),
the error in the deter-
progress on the transformation
mination
will be given
submit evidence that this mechanism
actually occurs.
Details of this work will be published
in due time.
of this temperature
error in our solubility
determination.
by the
We estimated
this error to be not more than f0.2”C. As mercury is almost insoluble in gray tin and only to a very slight extent in white tin, mercury
will not
Smith’ll)
of white tin amalgams
also mentions the liberation
the transformation
of mercury at
front, but not the diffusion
of tin
through free mercury. He explains the suppressing of the influence of the retarding elements by supposing
have an appreciable influence on the transformation temperature of tin. Hence the temperature of the
that
three-phases equilibrium c&n-BSn-HgSn,, will be 13.2”C. The phase diagram, based on the temperatures
front to free mercury, present in cracks in the gray tin. No account is given for the coherence of the gray
of the three-phases
tin.
equilibria,
is drawn in Fig. 3.
the
atoms
will diffuse
at the transformation
ACKNOWLEDGMENTS
Thanks are due to Professor Dr. W. G. Burgers for his stimulating
interest and helpful comments,
to Miss J.
Kouwenhoven for assistance with the analysis and to the Chairman of the National Defense Research Council
of the Netherlands
permission
-100
bS’
0
I
IO
I
I
20
30
HQsn, I
40
50
*cc HgSn3+aS”
60
I
1
I
70
80
90
100
at %tin
FIG. 3.
The tin-mercury phase diagram the phase fields of gray tin.
extended
for his
REFERENCES
I”;
I
(R.V.O.-T.N.O.)
to publish this paper.
to
1. A. W. EWALD and 0. N. TUFTE, J. Appl. Phys. 29, 1007 (1958). 2. M. HANSEN, Constitution of binary ccZZoy,s.McGraw-Hill, New York (1958).
ACTA
128
METALLURGICA,
3. W. J. VAN HETEREN, Thesis, Amsterdam (1902); 2. Anorg. Chem. 42, 129 (1904). 4. E. COHEN and A. K. W. A. VAN LIESHOUT, 2. Phys. Chem.
173,1 (1953).
5. L. J. GROEN, Thesis, Delft, (1956). 6. M. L. V. GAYLER, J. Inst. Met. 60, 379 (1937). 7. W. GUERTLER, Handbuch rler Metallographie Bd. 1, S.719
VOL.
8. 9. 10. 11.
12.
9,
1961
Verlagsbuch-handlung Gebriider Bortaaeger, (1912). K. BORNEMANN, Metallurgic, Berlin 7, 108 (1909). R. A. JOYNER. J. Chem. Sot. 99, 1995 (1911). J. GOUY, J. Phys., Paris 4, 320 (1895). R. W. SMITH,Can&. J. Phys. 37, 1079 (1959). L. J. GROIN, Nature, Lord. 174, 1836 (1954).
Berlin
POSITION
OF GRAY
TIN
IN THE
P. H. VAN
TIN-MERCURY
SYSTEM*
LENT?
The determination of the solubility of gray tin and white tin in mercury at temperatures below 0°C is described. From these measurements, the phase-fields of gray tin could be added to our knoudcdge of the tin-mercury system. Gray tin can be in equilibrium with a solution of tin in mercury in the temperature range between -7.5 f l.O”C and -35.2 I_t 0.2”C. A mechanism is proposed for the transformation of white tin amalgams. LA
LOCALISATION
DE
L’ETAIN GRIS DANS ETAIN-MEBCURE
LE
DIAGRAMME
D’ETAT
L’auteur d&Gritla c~~~~&tion de la solubiliti de l’etain gris et de J’etain blanc dans Ie mercure aux tempbatures inferieures Q 0°C. Ses mesures permettent de determiner les domaines de phase de I’etain gris dans le diagramma d’etat Btain-mercure. L’etain gris peut etre en Bquilibreavec une solution d’etsin f 1,O”C et -35,2 f 0,2”C. L’auteur dans du mercure pour des temperatures comprises entre -75 propose une m&anisme de transformation des amalgames d’etain blanc. DIE
LAGE
VON
GRAUEM
ZINN
IM
SYSTEM
ZINN-QUECKSILBER
Die Bestimmung der Losliehkeit van grauem und w&BernZinn in Quecksilber bei Temperaturen unter 0°C wird beschrieben. Mach diesen ~essun~n konnten die Phasenfelder des grauen Zinns unserer Kenntnis des Systems Zinn-Quecksilber hinzugefiigt werdan. Graues Zinn ktannmit einer Losung von Zinn in Quecksiiber im Temparaturbereich zwischen -75 + 1,O”C und -35,2 f 0,2”C in Gloichgewicht &hen. Fur die Transformation von Amalgamen des w&J&nZinns wird ein Mechanismus vorgoschlegen.
INTRODUCTION
New interest has arisen in the tin-mercury after Ewald and Tufteo)
system,
succeeded in growing gray tin
single crystals from a solution of tin in mercury. Gray (a) tin is not included in the phase diagram given by Hansen(Q, a summary of all known investigations J’sn white
in
the
field
Heteren@), and
difference
of
when
gray
the
tin-n~er~ur.~
measuring
tin in mercury
between
the
of
at 0°C found
no
both modifications
and was not able to indicate
system.
solubility
in this respect
the position
of gray tin
in the diagram. According to Cohen and van Lieshout(
gray tin
is stable
below
132°C.
In the
phase
diagram
Fro. I. The tin-mercury phase diagram according to Hansen.
of
Below
Hansen (Fig. 1) three intermediate phases occur, of which two can exist at temperatures where gray tin is stable.
According
to the investigations
of Green’s),
reports-referring
indicated
by the formula
suggests
HgSnl, 9 although its tin content may vary from This phase is formed when about 88-94 at. y& white tin is brought into contact with mercury at temperatures above the melting point of mercury. * Received February 13, 1960.
VOL. 9, FEBRUARY
1961
phase
is
to
unpublished
results
of
Pry-
the occurrence
of still another
phase,
the
so called S-phase, which would be stable below 9O”C, in order to be able to explain thermal effects found at 90°C. No other investigator has ever confirmed these effects. Moreover, as we found that HgSn,, crystallizes from a solution of tin in mercury at room
1 Physical Laboratory of the National Defense Research Council of the Netherlands (R.V.G.-T.N.O.), The Hague. ACTA META LLURGICA,
intermediate
therch-the formula HgSn, for this phase; but others considered the formula HgSn or HgsSn more and Bornemann( Gayler also likely (Guertler”)
At higher mercury concentraphase is formed. This phase is
called the y-phase generally
a second
as can be concluded from the measurements The composition and crystal of van Heteren@). structure of this phase are unknown. Gaylex(‘n
with microscope and X-ray techniques, not more than 0.1 at.% mercury can dissolve in white (P) tin at room temperature. tions an intermediate
-34.6”C
stable,
temperature, we think phase is very unlikely.
125
that
the
existence
of this
ACTA
126
METALLURGICA,
VOL.
9, 1961
gray tin in the phase diagram 0 t 0 IO n + 0t
20 .u
from these measure-
ments.
van ~etefwl Gouy Joyner Ourmeasurements
EXPERIMENTAL
For
the
PROCEDURE
determinations
AND
of
the
RESULTS
solubilities
two
small glass tubes were used, each closed at one end with
a rubber
tube
and a pinch-cock,
other end with a rubber stop.
and at the
They were filled with
about 50 g mercury, purified by air oxidation and vacuum distillation. One tube was cooled to -40°C 0,. %
and then 0.5 g gray tin powder was added.
tin
was stored during 12 hr at -20°C.
FIG. 3. Mercury rich part of the tin-mercury phase
in the other tube about
dia.gram.
At low temperatures
the tin-mercury
system
was
investigated by van Heterenf3). His results are given in Fig. 2 together with points found by Joynercg) and Gouy(lO) in the vicinity points
of the liquidus
found by saturating 1 hr and analysing
of room at -18.8
temperature.
The
and 0°C have been
mercury with white tin during the solution. The solubilities
found in that way were 0.36 and 0.59 at.%, respectively. In another experiment mercury was saturated with white tin and with gray tin at 0°C during 5 hr. The solubilities found in that way were 0.62 and 0.60 at.‘+&, respectively. have been found
The other points
by van Heteren
in the slopes of cooling
in Fig. 2
from the changes
and heating
curves of amal-
gams with a well known composit#ion. From the measurements of van Heteren it appears that above -34.6% HgSn,a can be in equilibrium with a solution of tin in mercury.
This tube
To the mercury
0.5 g white tin powder was
added at room-temperature
(about 20°C).
It was kept
at this temperature, to exclude the presence of gray tin nuclei, (which may be present in the atmosphere) which
react
readily
at 20°C with
mercury,
under
formation of HgSn,,. The tubes with tin and mercury were suspended in a dewar-tube, filled with solid and liquid
of various
salt-water
eutectic
mixtures
(pre-
pared beforehand) and agitated intensely for 8 hr. After this the tubes were removed from the dewar, and by means of the pinch-cock solution
about
was drained and collected.
of the solution was determined
40 g of the
The tin content
by gravimetric
(as SnO,). The results are given in the following
analysis
table
and
have been plotted in Fig. 2. Here the two curves represent the liquidus curves of grsy tin and of BgSn1,.
Below this tempera-
TABLE
1
ture and above the mehing point of mercury (-38.9”C) the saturated solution is in equilibrium with HgSn,( 2). According to Ewald and Tufteo), HgSn,, crystallizes from above
a supersaturated about
-3O”C,
phase diagram.
solution
of tin in mercury
in agreement
However,
with the known
after 1 week at tempera-
tures in the range from -10”
to -3O”C,
vanished solution.
crystallized
and
gray
tin
From these observations
has
HgSn,,
has
from
the
we can conclude
that in
this temperature range gray tin can be in equilibrium with a solution of tin in mercury, but the nucleation
MaClz + Ho0 N&l+ Ha0 Na&03 + Hz0
- 33.6 1 0.242 0.243 0.243t 0.270 0.267 0.269 ~ 21.2 0.344 0.344 0.344 0.371 0.367 0.369 ~ 10.2 1 0.470 0.463 0.467) 0.4Q4 0.490 0.492
ZnSofffgH=o 2
--6.55 0.00 0.564 0.662 0.568 0.656 0.566 0.659~ ;0.561 0.656 0.559 0.656 0.560 0.656
THE
POSITION OF GRAY TIN TIN-MERCURY SYSTEM
As expected, in the temperature -10’ and -32.2”C the solubility
IN THE
range between of gray tin in
of gray tin is retarded to such extent, that HgSn,, crystallizes as a metastable phase. Thus the points
mercury is smaller than that of HgSn,,. At -6.5% the solubility of HgSnr, is the smaller one. From Fig. 2 it appears that the solubility of both phases is
measured by van Heteren in this temperature range represent metastable equilibria. In the course of investigations on the semiconductive properties of gray tin, we have determined the stable and metastable liquidus of the tin-mercury
the same at -7.5%. So this represents the temperature of the three-phases equilibrium: L-c&n-HgSn,,. At 0°C we found the same solubility for gray tin and with van Heteren), since HgSn,a (in agreement evidently gray tin at this temperature reacts with
system in the temperature range from 0” to -32.2%, by measuring the solubility of gray and white tin in mercury. We were able to indicate the position of
mercury to form HgSn,,. From the measurements at 0°C we may conclude that the equilibrium conditions arc reached in 8 hr.
VAN
Resulting
LENT:
GRAY
TIN
from a high or a low tin concentration,
IX
THE
SYSTEM
127
THE TRANSFORMATION CONTAINING A FEW PER
the
measured values agreed within 0.5 per cent. Their accuracy is fixed by the errors in the gravimetric
Sn-Hg
The
transformation
from
OF WHITE TIN CENT MERCURY
white
to
gray
tin
is
determinations. As the duplicates on the average differ less than 1 per cent from the measured values,
accompanied 20 per cent),
by a large volume expansion (about with the result that the gray tin falls
we estimate
into pieces.
Groen(12>5) showed
per cent.
the error in our measurements
The
equilibrium
error
in the
temperature
not more than at -6.5”C
of L-&-HgSn,,
&l.O”C,
at 10.5
determination
of
the
is certainly
but likely less, as we found
a definite difference between the solubility
of gray tin and HgSnlz. This result agrees with the observations and Tufte’l)
of Ewald
Mercury
which has a retarding influence on the transformation. As can be seen from the phase diagram, in the temperature range from -7.5” to -35.2”C transformation of of HgSn,,
In a recent article, Smith(ll)
describes the determina-
According
tion of the same three-phases
equilibrium temperature,
white tin at the transformation
method.
He found
-8.15
i
with our measurements.
also
e.g. lead,
a few per cent mercury,
agreement
crystal-
of mercury.
of other elements,
white tin, containing
a dilatometric
only HgSn,,
a small amount
suppresses the influence
pieces
that the tin
practically
O.l”C in excellent
-10°C
contains
that compact
provided
lizes from the mercury solution, and that above 1°C mercury reacts rapidly with gray tin to form HgSn,,.
using
that above
of gray tin can be obtained,
a mixture
be accompanied
by the liberation
to Fig.
of metastable
1, the mercury
HgSn,,.
transformation
(being
and white tin,) will of free mercury. reacts
with
the
front, under formation
But when all white tin at the
front
has reacted,
mercury
can be
However, no other points of the phase diagram were given by him. The values of the solubility of white
piled up to more or less extent. The mercury does not form a complete
tin at -18.8”C
to the transformation,
as tin can diffuse through
from the untransformed a result of the solubility
to the transformed part, as difference between the stable
with
and 0°C of van Heteren agree poorly
our results.
Probably
equilibrium
conditions
were not reached in his measurements. The temperature of the three-phases
equilibrium
L-crSn-IHgSn,(?)l(2) is given by the intersection of the liquidus curves of gray tin and HgSn,(?). This temperature is -35.2”C as follows from Fig. 2. As the slope of the liquidus
of gray tin is considerably
and the metastable accounts
phase.
for the coherence
hindrance
This mechanism
it
easily
of the gray tin and the
suppressing of the influence of the retarding elements, for these are solved in the mercury and do not play any active part in the transformation. Investigations in
steeper than that of HgSn,(?),
the error in the deter-
progress on the transformation
mination
will be given
submit evidence that this mechanism
actually occurs.
Details of this work will be published
in due time.
of this temperature
error in our solubility
determination.
by the
We estimated
this error to be not more than f0.2”C. As mercury is almost insoluble in gray tin and only to a very slight extent in white tin, mercury
will not
Smith’ll)
of white tin amalgams
also mentions the liberation
the transformation
of mercury at
front, but not the diffusion
of tin
through free mercury. He explains the suppressing of the influence of the retarding elements by supposing
have an appreciable influence on the transformation temperature of tin. Hence the temperature of the
that
three-phases equilibrium c&n-BSn-HgSn,, will be 13.2”C. The phase diagram, based on the temperatures
front to free mercury, present in cracks in the gray tin. No account is given for the coherence of the gray
of the three-phases
tin.
equilibria,
is drawn in Fig. 3.
the
atoms
will diffuse
at the transformation
ACKNOWLEDGMENTS
Thanks are due to Professor Dr. W. G. Burgers for his stimulating
interest and helpful comments,
to Miss J.
Kouwenhoven for assistance with the analysis and to the Chairman of the National Defense Research Council
of the Netherlands
permission
-100
bS’
0
I
IO
I
I
20
30
HQsn, I
40
50
*cc HgSn3+aS”
60
I
1
I
70
80
90
100
at %tin
FIG. 3.
The tin-mercury phase diagram the phase fields of gray tin.
extended
for his
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I”;
I
(R.V.O.-T.N.O.)
to publish this paper.
to
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128
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Berlin