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The superconducting transition behavior of ternary alloys of titanium
Scripta
METALLURGICA
V o l . 8, pp. 3 2 9 - 3 3 6 , 1974 Printed in t h e U n i t e d States
THE SUPERCONDUCTING
Pergamon
Press,
Inc.
TRANSITION BEHAVIOR OF TERNARY
ALLOYS OF TITANIUM
by W. L. Cotton,
R. Taggart,
College of Engineering,
Seattle, WA
(Received
and D. H. Polonis
University
of Washington
98195
February
i,
1974)
Introduction It has been shown that ternary additions
of the alpha stabilizing
elements
inhibit the formation of the omega phase and promote a phase separation beta stabilized Ti base alloys retained
in quenched alloys,
of the electron:atom
(i).
The omega phase can be formed or the beta phase completely
if the addition of high valency
ratio in excess of four (2).
values of the superconducting
transition
ternary elements
It is generally recognized
temperature
leads to values that high
depend upon an electron:atom
between 4.6 and 4.8 (3), which would require the addition of high concentrations or group 6 elements
to either Ti or Zr base alloys.
nominal composition
the phase separation
employed zones;
to increase
In beta stabilized
ratio
(e/a)
of group 5
alloys of low
reaction or the omega reversion process can be
the value of e/a in the beta matrix due to the formation of solute lean
this approach is expected
These fundamental designed
Sn, AI, and O
reaction in certain
concepts
to test the feasibility
to enhance the superconducting
form the basis for a series of experiments of increasing
to alloys of the type Tiy(NbaXl_a)l_y. fraction and the conposition
properties
the value of T
of such alloys. that have been
by adding a ternary element X
c Thermal treatments have been used to vary the volume
of the beta phase and the microstructural
of the beta and alpha phases, while at the same time maintaining
distribution
of mixtures
the value of e/a in the beta
matrix in the range 4.6 - 4.8. Alloys of the titanium-niobium
system containing
ternary additions
of either molybdenum
or aluminum were selected on the basis of the following considerations: i.
The Ti-Nb binary system exhibits Type II superconductivity
the presence of non-superconducting length for the alloy
precipitates
that can be enhanced by
having a spacing of the order of the coherence
(4), e.g., a few hundred Angstroms
(5). o
2.
The atomic radii of Ti, Nb, Mo, and A1 are 1.467, 1.456, 1.386 and 1.429 A respectively
These values provide the suitable matching of the atomic size that is necessary solubility during solution treatment at elevated 3.
In alloys based on titanium and zirconium, molybdenum
it possible
to achieve e/a > 4.5 at relatively
is a beta stabilizer
low solute concentrations.
329
for beta
temperatures. that makes
330
SUPERCONDUCTING
4.
TRANSITION
OF
TERNARY
ALLOYS
OF
Ti
Aluminum is a Group III element which stabilizes the alpha phase
Vol.
8, No.
4
and inhibits the
formation of the omega phase in alloys based on Ti and Zr. 5.
By combining Ti-Nb alloys with ternary additions of AI or Mo the value of e/a can be
varied readily over the range 3.8 to 5.0 in alloys of the type Tiy(NbaXl_a)l_y where X is either Mo or AI.
These alloys provide an opportunity to evaluate the suggestion by Matthias
(6), that the value of T
c
should be highest when the electron:atom ratio is between 4.6 and 4.8. Experimental Procedure
The ternary alloys were prepared by levitation melting in an atmosphere of purified helium.
The Ti-Nb-Mo alloys contained from 2 to 62 at.% Nb and from 3 to 39 at.% Mo.
Ti-Nb-AI alloys contained from 5 to 45 at.% Nb and from 5 to 25 at.% AI.
The
Binary Ti-Nb and
Ti-Mo alloys were prepared for reference purposes, and contained from 2 to i00 at.% Nb and 3 to 39 at.% Mo, respectively. Each alloy charge was levitated until the component elements were molten and thoroughly mixed; the melts were then chill cast to produce ingots 0.5 cm dia. and 5 cm in length.
The
ingots were individually wrapped in tantalum foil, to getter any residual oxygen, and sealed in Vycor capsules at a vacuum of 10 -6 tort for solution treatment at I050°C, followed by either quenching or slow cooling. The specimens were quenched to room temperature by breaking the capsules in a water bath; the subsequent omega precipitation and reversion heat treatments were performed in neutral salt baths at 350°C and 500°C respectively.
The specimens that were transformed isothermally
in the ~ + 8 region were cooled from the homogenization temperature at a rate of i00 - 150°C per hour and subsequently aged for 40 hours at 750, 650, or 550°C. The superconducting transition temperature was measured using a germanium thermometer and an induction coil (7).
The transition temperature T c is defined by the value correspond-
ing with 50% of the inductance change. Needle specimens for x-ray studies were prepared by rolling portions of ductile samples to a thickness of 0.2 - 0.5 mm, followed by encapsulation, heat treatment, fine grinding, and etching in a solution containing 14 parts HNO 3 to one part HF.
Debye-Scherrer x-ray patterns
were used to identify the constitution of the heat treated alloys. Experimental Results and Discussion The values of T c were measured for alloys of the type Tiy(NbaXl_a)l_y where X was /either AI or Mo.
The thermal treatments include the quenched, slow-cooled, and isothermally tr~6s-
formed conditions.
Reversion treatments were employed to produce solute fluctuations in the
beta phase in those alloys where it was possible to form the omega phase during low temperature aging. a.
Ti-Nb-Mo Alloys Figure i shows the transition temperatures of Ti-Nb-Mo alloys in the as-quenched condition
plotted as a function of the nominal e/a ratio.
This family of curves provides a means for
Vol.
8, No.
4
SUPERCONDUCTING
TRANSITION
OF
TERNARY
ALLOYS
OF
Ti
531
I0
r,-n,-
6
~E Z O_ ~-- 4 u3 Z h.I.-
2
42
4.0
4.4
4.6
4.8
5.0
E L E C T R O N : A T O M RATIO
FIG. i.
The transition temperatures of Ti-Nb-Mo alloys in the as-quenched as a function of the nominal e/a ratio.
evaluating
condition plotted
the combined contribution
of all three elements on the value of T . Since Ti, Nb c and Mo have 4, 5, and 6 valence electrons, respectively, the e/a ratio of an alloy of the type Tiy(NbaMOl_a)l_y
is related to the alloy composition
as follows:
e/a = 4y + 5a(l-y) + 6(l-a)(l-y) A ternary alloy with a fixed Nb content of 12 at.% and an e/a of 4.8 should contain 54 at.% Ti, 12 at.% Nb, and 34 at.% Mo. The transition
temperature values for the binary Ti-Nb and Ti-Mo alloys are in agreement
with previously published values not show the beneficial
(8,9).
The addition of the ternary element molybdenum did
effect predicted on the basis of the model proposed by Matthias
and tended to depress the value of T
c
(6),
well below that of the binary alloys of equivalent
niobium content. The reduction
in the value of T
c
due to the addition of molybdenum is demonstrated
Figure 2 and Table I which represent many measurements the Ti-Nb-Mo
ternary system.
and thermal treatments
in
for alloys of
The addition of 9 at.% Mo to a Ti-Nb binary alloy containing
approximately condition,
52 at.% Nb reduces the value of T from 9.83°K to 6.98°K in the quenched c whereas a value of 7°K is exhibited by a binary Ti-Nb alloy containing only 22 at.%
Nb. The aging of the as-quenched
specimens at 350°C for periods up to 40 hours had a signifi-
332
SUPERCONDUCTING
TRANSITION
OF TERNARY
ALLOYS
OF
Ti
Vol.
8, No.
4
Nb
/ I+A "7/f/ / / I t l : JS/ S // i
(046°)-~6
o
~1 o 5 . , 5 0 - 2 . 6 °
o=o,
2.1 °
( 0 , 9 6 °)
o
\_2o TRANSITION TEMPERATURE (°K) COMPOSITION (at%) O EXPERIMENTAL ALLOY COMPOSITIONS v COMPOSITION MARKED IN INCREMENTS OF IO at % ALONG AXES. NUMBERS INDICATE Tc VALUES FOR CORRESPONDING COMPOSITION POINTS ON DIAGRAM
FIG. 2.
Contours of constant values of T c for Ti-Nb-Mo ternary alloys in the beta stabilized condition.
TABLE I Transition Temperature Values For Heat Treated Ti-Nb-Mo Alloys
e/a
% Nb
% A1
Tc Furnace Cool
4.22
12.90
4.50
4.87
4.40
12.00
4.50
12.00
4.60
12.00
23.90
12.00
4.80
Tc Furnace Cool + 40 hrs. @ 550
Tc Water quenched
5.95
5.46
14.00
5.15
5.42
19.00
4.65
4.87
4.18
4.31
34.00
2.95
3.34
4.17
3.84
6.80
6.77
7.20
7.21
4.20
2.00
9100
4.50
32.00
9.00 9.00
4.15 3.60 7.01
4.60
42.00
4.70
52.00
9.00
7.20
6.98
4.50
20.00
15.00
5.45
5.62
Vol.
8, No.
4
SUPERCONDUCTING
TRANSITION
cant effect only on those alloys having a value of e/a in the vicinity of 4.2. process broadened
the superconducting
a double transition
transition
in the aged Ti-12Nb-4Mo
by as much as 1.2°K with the progressive aging.
When the temperature
The aging
zone in the impedance curve and resulted
alloy.
The corresponding
value of T
in
was lowered
c of the isothermal omega phase during
development
of the aged alloy was raised to 55°C for two minutes
the omega phase the value of T
333
OF TERNARY ALLOYS OF Ti
to revert
such c behavior is consistent with that reported for quenched and aged Zr-Nb alloys in which the omega phase was reverted
became equal to that of the original quenched condition;
(i0).
For alloys in which alpha precipitation
did not occur, furnace cooling resulted in a
decrease of 0.2 to 0.8 ° in the value of T . An increase in the value of T of i - 5 ° occurred c c after furnace cooling the alloys containing Mo as a ternary element and having a value of e/a less than 4.13. 4.22.
Similar results were obtained for Ti-Nb alloys with a value of e/a less than
These observations
solute enrichment
can be explained on the basis of alpha precipitation which promotes
in the beta phase,
thereby increasing
the bulk value of T c for the phase
mixture. The as-quenched
Ti-Nb binary alloys remained ductile over the entire compositon range.
Binary Ti-Mo alloys became brittle at concentrations
over 15 at.% and in Ti-Nb-Mo alloys
brittleness was encountered when the value of e/a exceeded 4.6. b.
Ti-Nb-AI Alloys The transition
function of e/a.
temperatures
of as-quenched
Ternary alloys containing
Ti-Nb-AI alloys are shown in Figure 3 as a
from 5 to i0 at.% AI showed sharp transitions
io
8
J r~ t'~
bJ I-Z _0 F-
4
z oc I.-
2i
$.8
FIG. 3.
The transition ratio.
4.0
temperatures
4.2 4.4 ELECTRON'ATOM
of as-quenched
4.6
I 4.8
I
2.0
RATIO
Ti-Nb-AI alloys as a function of the e/a
334
SUPERCONDUCTING
TRANSITION
OF
TERNARY
ALLOYS
O F Ti
Vol.
8, No.
4
from the normal to the superconducting state and a relationship between T that exhibited by the dotted Curve f o r t h e Ti-Nb binary alloys.
and e/a similar to c The ternary alloys containing
from 20 to 25 at.% AI showed a temdency for broad and double transitions.
There was no apparent
relationship between the values of T and the nominal e/a ratio for these alloys, thereby c suggesting that aluminum contents exceeding 15% alter the constitution of the alloy so that the influence of the beta phase is overshadowed.
When a mixture of the alpha and beta phases is
produced in Ti-Nb-AI alloys the aluminum separates to the alpha phase and the beta phase becomes enriched in niobium, leading to an improvement in the value of T original as-quenched condition.
compared with the c This is illustrated by the results for an alloy containing
45% Nb and 10% AI, for which T increases from 5°K in the quenched condition to 9.1°K after the c alloy was furnace cooled to Promote the formation of an alpha plus beta mixture. Thermal treatments designed to enrich the Nb content of the beta phase make it possible to approach the maximum T
c
value of 9.9°K in the ternary Ti-Nb-AI alloys.
The T
values increased by less than 1 ° from the as-quenched condition following excessive c aging and reversion treatments at 350°C and 550°C respectively. This stability of T is c attributed to the suppression of omega formation by the alpha stabilizing influence of aluminum. Aging for 40 hour periods at 550°C after furnace cooling generally increased the value of T for pseudo-binary alloys containing up to 25% Nb as shown in Table II.
c
The decrease in the
TABLE II Transition Temperature Values For Heat Treated Ti-Nb-AI Alloys
e/a
% Nb
% AI
TC Furnace Cool
TC Furnace Cool + 40 hrs. @ 550
Tc Water quenched
3.97
6.57
9.36
6.65
7.17
2.98
4.01
10.23
9.65
6.55
7.10
3.51
4.05
14.98
9.99
6,73
7.17
3.81
4. I0
19.55
9.75
6.24
7.65
4.70
4.11
18.02
6.07
6.98
7.15
4.80
4.15
24.97
10.03
6.36
7.89
5.00
4.25
34.94
i0.00
8.82
7.90
6.20
4.35
45.00
10.03
9.10
7.89
4.60
value of T
after aging the higher Nb alloys for 40 hours at 550°C reflects the dissolution of c the alpha phase at the aging temperature. The subsequent redistribution of solute leads to a
decrease in the average niobium content of the beta phase.
Vol.
8, No.
4
SUPERCONDUCTING
TRANSITION
OF
TERNARY
ALLOYS
OF
Ti
335
Conclusions The studies conducted sufficient alloys.
criterion
so far have made it clear that the electron:atom
to use as a basis for predicting
This fact becomes particularly
having a non-uniform the electron:atom
distribution
concentration
that of the alloy. electron:atom
ratio is not a
the optimum value of T in multi-component c evident in alloys containing more than one phase and
of the solute elements.
of the superconducting
Furthermore,
In such cases it is apparent
that
phase itself may be quite different
the addition of a third element
than
that tends to raise the
ratio can reduce the value of Tc, as revealed in the present work for Ti-Nb-Mo
alloys. Niobium additions
are especially
effective in enhancing
for the beta c factor is the distribution of the niobium
phase of titanium alloys, but an equally important within the alloy. increase
the value of T
This is evidenced by the fact that appropriate
the value of T
for a beta stabilized
thermal treatments
can
alloy if solute enrichment of the beta matrix is
c promoted by invoking phase separation processes. creased by ternary additions
or treatments
Alternatively, the value of T can be inc that promote alpha phase formation accompanied by
beta phase enrichment. This work is part of a program sponsored by the Division of Research,
U.S. Atomic Energy
Commission under Contract No. AT(45-1)-2225-TI3. References
i.
J. C. Williams,
2.
C. A. Luke, R. Taggart and D. H. Polonis,
3.
B. T. Matthias,
4.
J. D. Livingston and H. W. Schadler,
5.
C. Baker and J. Sutton, Phil. Mag., Vol. 19, p. 190, 1969.
6.
B. T. Matthias, Prog. Co., Vol. 2, 1957.
7.
T. S. Luhman,
8.
J. K. Hulm and R. D. Blaugher,
9.
J. C. Ho and E. W. Collings,
i0.
B. S. Hickman,
and D. H. Leslie, Met. Trans.,Vol.
2, p. 477, 1971.
Jnl. of Nucl. Mtls., Vol. 16, p. 7, 1965.
Physics Today, p. 23, August 1971. in Mater.
in Low Temp. Physics,
Ph.D. dissertation,
S. L. Narasimhan,
Prog.
University
Sc., Vol. 12, p. 249, 1964.
edited by J. C. Goster, North Holland Publishing
of Washington,
1970.
Phys. Rev., Vol. 123, p. 1569, 1961.
Phys. Letts., Vol. 29A, p. 206, 1969.
R. Taggart and D. H. Polonis,
Jnl. Nucl. Mtls., Vol. 43, p. 258, 1972.
METALLURGICA
V o l . 8, pp. 3 2 9 - 3 3 6 , 1974 Printed in t h e U n i t e d States
THE SUPERCONDUCTING
Pergamon
Press,
Inc.
TRANSITION BEHAVIOR OF TERNARY
ALLOYS OF TITANIUM
by W. L. Cotton,
R. Taggart,
College of Engineering,
Seattle, WA
(Received
and D. H. Polonis
University
of Washington
98195
February
i,
1974)
Introduction It has been shown that ternary additions
of the alpha stabilizing
elements
inhibit the formation of the omega phase and promote a phase separation beta stabilized Ti base alloys retained
in quenched alloys,
of the electron:atom
(i).
The omega phase can be formed or the beta phase completely
if the addition of high valency
ratio in excess of four (2).
values of the superconducting
transition
ternary elements
It is generally recognized
temperature
leads to values that high
depend upon an electron:atom
between 4.6 and 4.8 (3), which would require the addition of high concentrations or group 6 elements
to either Ti or Zr base alloys.
nominal composition
the phase separation
employed zones;
to increase
In beta stabilized
ratio
(e/a)
of group 5
alloys of low
reaction or the omega reversion process can be
the value of e/a in the beta matrix due to the formation of solute lean
this approach is expected
These fundamental designed
Sn, AI, and O
reaction in certain
concepts
to test the feasibility
to enhance the superconducting
form the basis for a series of experiments of increasing
to alloys of the type Tiy(NbaXl_a)l_y. fraction and the conposition
properties
the value of T
of such alloys. that have been
by adding a ternary element X
c Thermal treatments have been used to vary the volume
of the beta phase and the microstructural
of the beta and alpha phases, while at the same time maintaining
distribution
of mixtures
the value of e/a in the beta
matrix in the range 4.6 - 4.8. Alloys of the titanium-niobium
system containing
ternary additions
of either molybdenum
or aluminum were selected on the basis of the following considerations: i.
The Ti-Nb binary system exhibits Type II superconductivity
the presence of non-superconducting length for the alloy
precipitates
that can be enhanced by
having a spacing of the order of the coherence
(4), e.g., a few hundred Angstroms
(5). o
2.
The atomic radii of Ti, Nb, Mo, and A1 are 1.467, 1.456, 1.386 and 1.429 A respectively
These values provide the suitable matching of the atomic size that is necessary solubility during solution treatment at elevated 3.
In alloys based on titanium and zirconium, molybdenum
it possible
to achieve e/a > 4.5 at relatively
is a beta stabilizer
low solute concentrations.
329
for beta
temperatures. that makes
330
SUPERCONDUCTING
4.
TRANSITION
OF
TERNARY
ALLOYS
OF
Ti
Aluminum is a Group III element which stabilizes the alpha phase
Vol.
8, No.
4
and inhibits the
formation of the omega phase in alloys based on Ti and Zr. 5.
By combining Ti-Nb alloys with ternary additions of AI or Mo the value of e/a can be
varied readily over the range 3.8 to 5.0 in alloys of the type Tiy(NbaXl_a)l_y where X is either Mo or AI.
These alloys provide an opportunity to evaluate the suggestion by Matthias
(6), that the value of T
c
should be highest when the electron:atom ratio is between 4.6 and 4.8. Experimental Procedure
The ternary alloys were prepared by levitation melting in an atmosphere of purified helium.
The Ti-Nb-Mo alloys contained from 2 to 62 at.% Nb and from 3 to 39 at.% Mo.
Ti-Nb-AI alloys contained from 5 to 45 at.% Nb and from 5 to 25 at.% AI.
The
Binary Ti-Nb and
Ti-Mo alloys were prepared for reference purposes, and contained from 2 to i00 at.% Nb and 3 to 39 at.% Mo, respectively. Each alloy charge was levitated until the component elements were molten and thoroughly mixed; the melts were then chill cast to produce ingots 0.5 cm dia. and 5 cm in length.
The
ingots were individually wrapped in tantalum foil, to getter any residual oxygen, and sealed in Vycor capsules at a vacuum of 10 -6 tort for solution treatment at I050°C, followed by either quenching or slow cooling. The specimens were quenched to room temperature by breaking the capsules in a water bath; the subsequent omega precipitation and reversion heat treatments were performed in neutral salt baths at 350°C and 500°C respectively.
The specimens that were transformed isothermally
in the ~ + 8 region were cooled from the homogenization temperature at a rate of i00 - 150°C per hour and subsequently aged for 40 hours at 750, 650, or 550°C. The superconducting transition temperature was measured using a germanium thermometer and an induction coil (7).
The transition temperature T c is defined by the value correspond-
ing with 50% of the inductance change. Needle specimens for x-ray studies were prepared by rolling portions of ductile samples to a thickness of 0.2 - 0.5 mm, followed by encapsulation, heat treatment, fine grinding, and etching in a solution containing 14 parts HNO 3 to one part HF.
Debye-Scherrer x-ray patterns
were used to identify the constitution of the heat treated alloys. Experimental Results and Discussion The values of T c were measured for alloys of the type Tiy(NbaXl_a)l_y where X was /either AI or Mo.
The thermal treatments include the quenched, slow-cooled, and isothermally tr~6s-
formed conditions.
Reversion treatments were employed to produce solute fluctuations in the
beta phase in those alloys where it was possible to form the omega phase during low temperature aging. a.
Ti-Nb-Mo Alloys Figure i shows the transition temperatures of Ti-Nb-Mo alloys in the as-quenched condition
plotted as a function of the nominal e/a ratio.
This family of curves provides a means for
Vol.
8, No.
4
SUPERCONDUCTING
TRANSITION
OF
TERNARY
ALLOYS
OF
Ti
531
I0
r,-n,-
6
~E Z O_ ~-- 4 u3 Z h.I.-
2
42
4.0
4.4
4.6
4.8
5.0
E L E C T R O N : A T O M RATIO
FIG. i.
The transition temperatures of Ti-Nb-Mo alloys in the as-quenched as a function of the nominal e/a ratio.
evaluating
condition plotted
the combined contribution
of all three elements on the value of T . Since Ti, Nb c and Mo have 4, 5, and 6 valence electrons, respectively, the e/a ratio of an alloy of the type Tiy(NbaMOl_a)l_y
is related to the alloy composition
as follows:
e/a = 4y + 5a(l-y) + 6(l-a)(l-y) A ternary alloy with a fixed Nb content of 12 at.% and an e/a of 4.8 should contain 54 at.% Ti, 12 at.% Nb, and 34 at.% Mo. The transition
temperature values for the binary Ti-Nb and Ti-Mo alloys are in agreement
with previously published values not show the beneficial
(8,9).
The addition of the ternary element molybdenum did
effect predicted on the basis of the model proposed by Matthias
and tended to depress the value of T
c
(6),
well below that of the binary alloys of equivalent
niobium content. The reduction
in the value of T
c
due to the addition of molybdenum is demonstrated
Figure 2 and Table I which represent many measurements the Ti-Nb-Mo
ternary system.
and thermal treatments
in
for alloys of
The addition of 9 at.% Mo to a Ti-Nb binary alloy containing
approximately condition,
52 at.% Nb reduces the value of T from 9.83°K to 6.98°K in the quenched c whereas a value of 7°K is exhibited by a binary Ti-Nb alloy containing only 22 at.%
Nb. The aging of the as-quenched
specimens at 350°C for periods up to 40 hours had a signifi-
332
SUPERCONDUCTING
TRANSITION
OF TERNARY
ALLOYS
OF
Ti
Vol.
8, No.
4
Nb
/ I+A "7/f/ / / I t l : JS/ S // i
(046°)-~6
o
~1 o 5 . , 5 0 - 2 . 6 °
o=o,
2.1 °
( 0 , 9 6 °)
o
\_2o TRANSITION TEMPERATURE (°K) COMPOSITION (at%) O EXPERIMENTAL ALLOY COMPOSITIONS v COMPOSITION MARKED IN INCREMENTS OF IO at % ALONG AXES. NUMBERS INDICATE Tc VALUES FOR CORRESPONDING COMPOSITION POINTS ON DIAGRAM
FIG. 2.
Contours of constant values of T c for Ti-Nb-Mo ternary alloys in the beta stabilized condition.
TABLE I Transition Temperature Values For Heat Treated Ti-Nb-Mo Alloys
e/a
% Nb
% A1
Tc Furnace Cool
4.22
12.90
4.50
4.87
4.40
12.00
4.50
12.00
4.60
12.00
23.90
12.00
4.80
Tc Furnace Cool + 40 hrs. @ 550
Tc Water quenched
5.95
5.46
14.00
5.15
5.42
19.00
4.65
4.87
4.18
4.31
34.00
2.95
3.34
4.17
3.84
6.80
6.77
7.20
7.21
4.20
2.00
9100
4.50
32.00
9.00 9.00
4.15 3.60 7.01
4.60
42.00
4.70
52.00
9.00
7.20
6.98
4.50
20.00
15.00
5.45
5.62
Vol.
8, No.
4
SUPERCONDUCTING
TRANSITION
cant effect only on those alloys having a value of e/a in the vicinity of 4.2. process broadened
the superconducting
a double transition
transition
in the aged Ti-12Nb-4Mo
by as much as 1.2°K with the progressive aging.
When the temperature
The aging
zone in the impedance curve and resulted
alloy.
The corresponding
value of T
in
was lowered
c of the isothermal omega phase during
development
of the aged alloy was raised to 55°C for two minutes
the omega phase the value of T
333
OF TERNARY ALLOYS OF Ti
to revert
such c behavior is consistent with that reported for quenched and aged Zr-Nb alloys in which the omega phase was reverted
became equal to that of the original quenched condition;
(i0).
For alloys in which alpha precipitation
did not occur, furnace cooling resulted in a
decrease of 0.2 to 0.8 ° in the value of T . An increase in the value of T of i - 5 ° occurred c c after furnace cooling the alloys containing Mo as a ternary element and having a value of e/a less than 4.13. 4.22.
Similar results were obtained for Ti-Nb alloys with a value of e/a less than
These observations
solute enrichment
can be explained on the basis of alpha precipitation which promotes
in the beta phase,
thereby increasing
the bulk value of T c for the phase
mixture. The as-quenched
Ti-Nb binary alloys remained ductile over the entire compositon range.
Binary Ti-Mo alloys became brittle at concentrations
over 15 at.% and in Ti-Nb-Mo alloys
brittleness was encountered when the value of e/a exceeded 4.6. b.
Ti-Nb-AI Alloys The transition
function of e/a.
temperatures
of as-quenched
Ternary alloys containing
Ti-Nb-AI alloys are shown in Figure 3 as a
from 5 to i0 at.% AI showed sharp transitions
io
8
J r~ t'~
bJ I-Z _0 F-
4
z oc I.-
2i
$.8
FIG. 3.
The transition ratio.
4.0
temperatures
4.2 4.4 ELECTRON'ATOM
of as-quenched
4.6
I 4.8
I
2.0
RATIO
Ti-Nb-AI alloys as a function of the e/a
334
SUPERCONDUCTING
TRANSITION
OF
TERNARY
ALLOYS
O F Ti
Vol.
8, No.
4
from the normal to the superconducting state and a relationship between T that exhibited by the dotted Curve f o r t h e Ti-Nb binary alloys.
and e/a similar to c The ternary alloys containing
from 20 to 25 at.% AI showed a temdency for broad and double transitions.
There was no apparent
relationship between the values of T and the nominal e/a ratio for these alloys, thereby c suggesting that aluminum contents exceeding 15% alter the constitution of the alloy so that the influence of the beta phase is overshadowed.
When a mixture of the alpha and beta phases is
produced in Ti-Nb-AI alloys the aluminum separates to the alpha phase and the beta phase becomes enriched in niobium, leading to an improvement in the value of T original as-quenched condition.
compared with the c This is illustrated by the results for an alloy containing
45% Nb and 10% AI, for which T increases from 5°K in the quenched condition to 9.1°K after the c alloy was furnace cooled to Promote the formation of an alpha plus beta mixture. Thermal treatments designed to enrich the Nb content of the beta phase make it possible to approach the maximum T
c
value of 9.9°K in the ternary Ti-Nb-AI alloys.
The T
values increased by less than 1 ° from the as-quenched condition following excessive c aging and reversion treatments at 350°C and 550°C respectively. This stability of T is c attributed to the suppression of omega formation by the alpha stabilizing influence of aluminum. Aging for 40 hour periods at 550°C after furnace cooling generally increased the value of T for pseudo-binary alloys containing up to 25% Nb as shown in Table II.
c
The decrease in the
TABLE II Transition Temperature Values For Heat Treated Ti-Nb-AI Alloys
e/a
% Nb
% AI
TC Furnace Cool
TC Furnace Cool + 40 hrs. @ 550
Tc Water quenched
3.97
6.57
9.36
6.65
7.17
2.98
4.01
10.23
9.65
6.55
7.10
3.51
4.05
14.98
9.99
6,73
7.17
3.81
4. I0
19.55
9.75
6.24
7.65
4.70
4.11
18.02
6.07
6.98
7.15
4.80
4.15
24.97
10.03
6.36
7.89
5.00
4.25
34.94
i0.00
8.82
7.90
6.20
4.35
45.00
10.03
9.10
7.89
4.60
value of T
after aging the higher Nb alloys for 40 hours at 550°C reflects the dissolution of c the alpha phase at the aging temperature. The subsequent redistribution of solute leads to a
decrease in the average niobium content of the beta phase.
Vol.
8, No.
4
SUPERCONDUCTING
TRANSITION
OF
TERNARY
ALLOYS
OF
Ti
335
Conclusions The studies conducted sufficient alloys.
criterion
so far have made it clear that the electron:atom
to use as a basis for predicting
This fact becomes particularly
having a non-uniform the electron:atom
distribution
concentration
that of the alloy. electron:atom
ratio is not a
the optimum value of T in multi-component c evident in alloys containing more than one phase and
of the solute elements.
of the superconducting
Furthermore,
In such cases it is apparent
that
phase itself may be quite different
the addition of a third element
than
that tends to raise the
ratio can reduce the value of Tc, as revealed in the present work for Ti-Nb-Mo
alloys. Niobium additions
are especially
effective in enhancing
for the beta c factor is the distribution of the niobium
phase of titanium alloys, but an equally important within the alloy. increase
the value of T
This is evidenced by the fact that appropriate
the value of T
for a beta stabilized
thermal treatments
can
alloy if solute enrichment of the beta matrix is
c promoted by invoking phase separation processes. creased by ternary additions
or treatments
Alternatively, the value of T can be inc that promote alpha phase formation accompanied by
beta phase enrichment. This work is part of a program sponsored by the Division of Research,
U.S. Atomic Energy
Commission under Contract No. AT(45-1)-2225-TI3. References
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J. C. Williams,
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C. A. Luke, R. Taggart and D. H. Polonis,
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B. T. Matthias, Prog. Co., Vol. 2, 1957.
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T. S. Luhman,
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B. S. Hickman,
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R. Taggart and D. H. Polonis,
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