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Ternary phases in the Pd-GaAs system: Implications for shallow contacts to GaAs
Volume
3, number
MATERIALS
9,lO
TERNARY PHASES IN THE Pd-GaAs
July 1985
LETTERS
SYSTEM :
IMPLICATIONS FOR SHALLOW CONTACTS TO GaAs * T. SANDS ** , V.G. KERAMIDAS Bell Communications
Research Inc., Murray Hill, NJ 07974,
USA
R. GRONSKY and J. WASHBURN Materials and Molecular Research Division, Lawrence Berkeley Loboratory, Berkeley, CA 94720, Received
Ternary
USA
9 May 19 85
phases of the type MXAmBV prepared
useful materials
for forming
tron microscopy
study of the Pd-GaAs
type MXAmBV (Pd,(GaAs),
reaction
and Pd,GaAs).
stalline films of Pd,(GaAs),, films are analogous
by solid-phase
shallow and adherent
reaction
between a metal, M, and a substrate,
to III-V semiconductors.
appropriate
accumulations
AmBv, are potentially
In this letter, the results of a transmission
It is shown that the first two reaction
are presented.
By choosing
free of interfacial
to silicide contacts
contacts
metal thicknesses
products
are ternary
and annealing temperatures, uniform monocryAs contacts to GaAs, these PdxGaAs
of As and Ga, can be obtained.
to silicon
1. Introduction
completely
satisfy in practice,
there is recent evidence
phases of the form MxGaAs do exist, specifically Integration iconductor laterally
and miniaturization
devices necessitate uniform
cal perspective,
potentially
of III-V compound
the development
and adherent
contacts.
III-V substrate
to promote
adhesion
is the first phase to form during
annealing
However,
materials
tures above 400°C results in the decomposition
must meet
and this reaction
must
morphologies
(b) The deposited
metal so
interface.
in a thin film
end phase (rich in the group Bland
ments) with a composition tage of such contacts properties
of MXA’nBV. The principle
is that their electrical
would not be dominated
(c)
Pd,Ga
and PdAs, after annealing
Because of the potential
order to identify the compounds
described.
to
system in
formed during low tempera-
(TEM) study of the Pd-GaAs
development
given in reference
2. Experimental Gallium
reaction
It is shown that the first two reaction
phases of the type PdXGaAs. morphological
*This work was supported by the Director, Office of Energy Research, Office of Basic Energy Sciences, Materials Science Division of the US. Department of Energy under Contract No. DE-AC03-76SF00098. “Work performed as a visiting Industrial Fellow at the Center for Advanced Materials, Lawrence Berkeley Laboratory. Berkeley, CA 94720
phases as
the Pd-GaAs
In this letter, the results of a transmission
near the interface. or impossible
of ternary
and to resolve some of the discrepancies
ated nonstoichiometry
may be difficult
we have investigated
vious studies. tron microscope
of the semiconductor
PdGa after of PdGa,
ture annealing
or by the associ-
these criteria
at 250°C.
at 350°C.
importance
advan-
tions of either group III or group V elements Although
is a metastable
and a combination
contact
accumula-
of Ni,GaAs
that Ni,GaAs
phases after annealing
at this temperature
materials,
at tempera-
[5,6] claimed to have observed
V ele-
and mechanical
by interfacial
annealing
annealing
et al. ]3] and Kuan [4] have reported
of PdzGaAs
Earlier investigators
The reaction
of a stable ternary
into NiGa and NiAs, suggesting the formation
that voids are not formed at the contact/A’nB” resulting
of Ni on GaAs.
phase 111. Both Oelhafen
on
species during the reaction
should go to completion,
[1,2]and Pd [3,4]. Ogawa [I] and Lahav and Eizenberg ]2]
From the metallurgi-
of contact
the 10 nm scale is to be achieved. moving
Ni
metal should react with the
occur in the solid state if control
should be the dominant
sem-
of shallow,
that
for the metals
have shown that Ni,GaAs
useful contact
several criteria: (a) The deposited
elec-
phases of the
elecare
products
A detailed description of the Pd-Ga-As
in pre-
are
of the
reacted layer is
7.
Methods
arsenide
substrates
with (100) orientation
were
409
MATERIALS LETTERS
Volume 3, number 9,lO
prepared for metal deposition by immersion into a 9: 1 DI H,O:HCI
solution
Palladium
by electron beam evaporation
50 nm at a rate of 0.6 rim/s in a vacuum Annealing
view and XTEM specimens were observed in a Siemens 102 TEM operated at 100 keV and JEOL JEM 200 CX with an
for 10 sec. followed by a DI H,O rinse.
The GaAs surface was blown dry with N,. then deposited
treatments
were performed
of l-2
ultra-high
was
to a thickness
of
X low6 torr.
in flowing forming gas
(95% Ar and 5% Hz) for 10 min. at temperatures
between 220
Cross-sectional
tively.
TEM (XTEM) specimens
were prepared
cooled stage.
Plan-
by
resolution
pole piece operated
Energy dispersive
performed
spectrometry
CX TEM/STEM.
A GaAs standard
of the EDS spectra.
was not available, considered
at 200 keV, respec(EDS) of x-rays was
with a Kevex model 3400 ultra-thin-window
tor and System 8000 spectrometer tiftcation
and 480°C. argon ion milling with a liquid nitrogen
Juty 1985
mounted
was used for partial quan-
Since a reliable Pd-Ga standard
the [Pd]:]Ga] ratios reported
below must be
tentative.
TEM images and co~s~nd~~ difhaction patterns from plan-view specimens of samples annealed I Low marination for 10 min. at (a,b) 22o’C and (c,d) 315’C. The diffraction pattern in (b) is the superposition of the polycrystalhne Pd ring pattern and the monocrystalline phase I spot pattern in <211b> zone-axis orientation. Diffraction spots from phases I and II are visible in (d). Fig.
410
detec-
on a JEOL 200
Fig. 2.
Cross sectional
TEM images
275 and 350°C respectively. ships described tation.
in the text.
of (a) the phase i/GaAs
The images Gallium
and (b) the phase II/GaAs
and their corresponding
arsenide
is in
electron
I 1> zone-axis
diffraction
orientation.
interfaces.
patterns
Samples
illustrate
were annealed
the orientation
Phase I and 11 are in ~000
at
relation-
I > zone-axis
orien-
Volume
3, number
9,lO
MATERIALS
July 1985
LETTERS
in Fig. l(c). At higher temperatures
3. Results and Discussion
II is the dominant The plan-view
micrograph
and diffraction
pattern
in Fig. 1
2(b) is a cross-sectional
image of the phase II/GaAs
(a,b) reveal that the first phase formed during low temperature
after annealing
at 35o’C.
annealing
with diffraction
patterns
orientation sectional
is nearly monocrystalline relationship
and has a well-defined
with the GaAs substrate.
Cross-
The inset diffraction from plan-view
phase II is also hexagonal
images from these samples (e.g. Fig. 2(a)) show that
phase I is hexagonal
(eg. 350 and 410°C) phase
phase in direct contact with GaAs.
Figure
interface
pattern
along
samples confirm
that
with
a0 = 0.92 ? 0.01 nm
with
a, = 0.673 * 0.002 nm CO = 0.370
In samples annealed
c, = 0.338 * 0.001 nm. The orientation
rel&ionship
+ 0.005 nm.
ing orientation
below 4Oo”C, phase II exhibits the follow-
relationship
with (100) GaAs:
with (100) GaAs is [OOOl]n // 101l]ciaAr and (213Oh1//
UWGaAs
This orientation
relationship
is evident in Fig. 2(b). Adjacent
Analysis of EDS data suggests a nominal composition of Pd,(GaAs), for phase I. These results are in close agreement
grains of phase II are often observed
with the findings
EDS spectra from grains of phase II yields a nominal
of Kuan [4].
Phase I is the dominant deposited
reaction
state and after annealing
3 15°C [7]. During annealing 4WC,
product
in the as-
at temperatures
at temperatures
at fast diffision
nm.
paths such as grain boundaries,
cracks in the phase I film.
The resulting
In addition
between 250 and
This second phase appears
is
to phases I and II, Pd,Ga
XTEM for some annealing ously reported
to nucleate
of our samples.
pores or
conditions
is shown
of diffraction
peak positions
(26’) measured of
Furthermore,
a major phase in previous
412
for PdAs, and phase II’
indexing
calculated
possible
calculated
based on
28 for
indexing
20 for
PdAs,[ 5)
PdAs,
as phase II
phase II
26.6 + 0.2
111
25.8
Oil1
26.6
30.8 + 0.2
200
29.9
2111
31.0
33.5 f 0.2 ‘36.5 & 0.2
212 211
45.5 36.8
072 1 __
33.0
50.7 f 0.2
311
50.6
0112
50.7
70.0 + 0.2 $72.3 + 0.2
420 421
70.4 72.4
0242 __
69.4 __
73.9 * 0.2
332
74.4
2750
74.5
(h - 0.1542nm)
+peak overlaps
with 200 PdGa
*peak overlaps
with 321 PdGa
a previin any
conditions
studies [5,6], our samples contained
from Fig. 1
PI
was detected by
[7]. However,
under annealing
peak position
*assuming CUKCI radiation
of
composi-
(25WC < T < SOOYZ)similar to those which yielded PdAs, as
morphology
Approximate
Analysis
phase, PdAs, [5,6], has not been detected
Table 1. Comparison
to be in twin orientation
[100]oti5 parallel to either [x3O]n or [z3Oin.
tion of Pd,GaAs.
up to
a second phase is formed if the initial Pd thickness
greater than -20
with
and aOIPdAs,] - 0.5982nm
Volume
3, number
MATERIALS
9.10
hexagonal
Pd,GaAs
tifications
of PdAs, were based on x-ray diffraction
as the major phase.
we have compared
the published
experimental
spectra from samples said to contain culated peak positions to the ternary
iden-
data only,
diffraction
July 1985
tory and Ariel Dori of Bell Laboratories, tance.
One of the authors
Table 1
Many valuable
Nicolet of the California
phase, Pd,GaAs.
assis-
discussions
Institute
Dr.
with the EDS ana-
lyses, and Ms. G. King for aiding in the preparation specimens.
solely to PdAs, can also be
for technical
(T.S.) wishes to acknowledge
T.R. Dinger and C. Ether for assistance
PdAs, [5,6] with the cal-
for phase II (-Pd,GaAs).
shows that the peaks attributed attributed
Since previous
LETTERS
of TEM
with Professor
of Technology
M-A.
are also grate-
fully acknowledged.
4. Conclusion 6. References It is clear from these results that the Pd-GaAs low temperatures ternary
phases.
(< 500°C) is dominated
these ternary materials
of silicides as shallow contacts
to silicon.
phases do not involve the inter-
facial accumulation
of arsenic,
ties of MIGaAs/GaAs
interfaces
into the factors which determine
In addition,
studies of the electrical should provide
M. Ogawa, Thin Solid Films, 70, (1980) 181.
123
A. Lahav and M. Eizenberg,
[3j
151
J.O. Olowolafe,
143.
the barrier heights of metallic
Woodall, [6]
[7] Microscopy,
P.S. Ho, M.J. Hovel, J.E. Lewis and J.M.
J. Appl. Phys., 50 (1979) 955.
X-F. Zeng and D.D.L. Chung. J. Vat. Sci. Technol.,
21
(1982) 611.
would like to thank the staff of the National
Center for Electron
and
T.S. Kuan, Mat. Res. Sac. Symp. Proc. Vol. -31 (1984)
5. Acknowledgements The authors
J.L. Freeouf, T.S. Kuan, T.N. Jackson
[4]
proper-
new insight
P. Oelhafen,
P.E. Batson, J. Vat. Sci. Techol., Bl (1983) 588.
since
phases on n and p type GaAs.
Appl. Phys. Len., 45 (1984)
256.
as
to the application
the reactions
to form MIGaAs
[l]
and the reac-
phases may find application
in direct analogy
of
can be limited
by proper choices of the initial Pd layer thickness shallow contact
at
by the formation
If the lateral inhomogeneities
tion temperature,
reaction
Lawrence
T. Sands, V.G. Keramidas,
R. Gronsky
and J. Wash-
bum, Thin Solid Films (1985) in press.
Berkeley Labora-
413
3, number
MATERIALS
9,lO
TERNARY PHASES IN THE Pd-GaAs
July 1985
LETTERS
SYSTEM :
IMPLICATIONS FOR SHALLOW CONTACTS TO GaAs * T. SANDS ** , V.G. KERAMIDAS Bell Communications
Research Inc., Murray Hill, NJ 07974,
USA
R. GRONSKY and J. WASHBURN Materials and Molecular Research Division, Lawrence Berkeley Loboratory, Berkeley, CA 94720, Received
Ternary
USA
9 May 19 85
phases of the type MXAmBV prepared
useful materials
for forming
tron microscopy
study of the Pd-GaAs
type MXAmBV (Pd,(GaAs),
reaction
and Pd,GaAs).
stalline films of Pd,(GaAs),, films are analogous
by solid-phase
shallow and adherent
reaction
between a metal, M, and a substrate,
to III-V semiconductors.
appropriate
accumulations
AmBv, are potentially
In this letter, the results of a transmission
It is shown that the first two reaction
are presented.
By choosing
free of interfacial
to silicide contacts
contacts
metal thicknesses
products
are ternary
and annealing temperatures, uniform monocryAs contacts to GaAs, these PdxGaAs
of As and Ga, can be obtained.
to silicon
1. Introduction
completely
satisfy in practice,
there is recent evidence
phases of the form MxGaAs do exist, specifically Integration iconductor laterally
and miniaturization
devices necessitate uniform
cal perspective,
potentially
of III-V compound
the development
and adherent
contacts.
III-V substrate
to promote
adhesion
is the first phase to form during
annealing
However,
materials
tures above 400°C results in the decomposition
must meet
and this reaction
must
morphologies
(b) The deposited
metal so
interface.
in a thin film
end phase (rich in the group Bland
ments) with a composition tage of such contacts properties
of MXA’nBV. The principle
is that their electrical
would not be dominated
(c)
Pd,Ga
and PdAs, after annealing
Because of the potential
order to identify the compounds
described.
to
system in
formed during low tempera-
(TEM) study of the Pd-GaAs
development
given in reference
2. Experimental Gallium
reaction
It is shown that the first two reaction
phases of the type PdXGaAs. morphological
*This work was supported by the Director, Office of Energy Research, Office of Basic Energy Sciences, Materials Science Division of the US. Department of Energy under Contract No. DE-AC03-76SF00098. “Work performed as a visiting Industrial Fellow at the Center for Advanced Materials, Lawrence Berkeley Laboratory. Berkeley, CA 94720
phases as
the Pd-GaAs
In this letter, the results of a transmission
near the interface. or impossible
of ternary
and to resolve some of the discrepancies
ated nonstoichiometry
may be difficult
we have investigated
vious studies. tron microscope
of the semiconductor
PdGa after of PdGa,
ture annealing
or by the associ-
these criteria
at 250°C.
at 350°C.
importance
advan-
tions of either group III or group V elements Although
is a metastable
and a combination
contact
accumula-
of Ni,GaAs
that Ni,GaAs
phases after annealing
at this temperature
materials,
at tempera-
[5,6] claimed to have observed
V ele-
and mechanical
by interfacial
annealing
annealing
et al. ]3] and Kuan [4] have reported
of PdzGaAs
Earlier investigators
The reaction
of a stable ternary
into NiGa and NiAs, suggesting the formation
that voids are not formed at the contact/A’nB” resulting
of Ni on GaAs.
phase 111. Both Oelhafen
on
species during the reaction
should go to completion,
[1,2]and Pd [3,4]. Ogawa [I] and Lahav and Eizenberg ]2]
From the metallurgi-
of contact
the 10 nm scale is to be achieved. moving
Ni
metal should react with the
occur in the solid state if control
should be the dominant
sem-
of shallow,
that
for the metals
have shown that Ni,GaAs
useful contact
several criteria: (a) The deposited
elec-
phases of the
elecare
products
A detailed description of the Pd-Ga-As
in pre-
are
of the
reacted layer is
7.
Methods
arsenide
substrates
with (100) orientation
were
409
MATERIALS LETTERS
Volume 3, number 9,lO
prepared for metal deposition by immersion into a 9: 1 DI H,O:HCI
solution
Palladium
by electron beam evaporation
50 nm at a rate of 0.6 rim/s in a vacuum Annealing
view and XTEM specimens were observed in a Siemens 102 TEM operated at 100 keV and JEOL JEM 200 CX with an
for 10 sec. followed by a DI H,O rinse.
The GaAs surface was blown dry with N,. then deposited
treatments
were performed
of l-2
ultra-high
was
to a thickness
of
X low6 torr.
in flowing forming gas
(95% Ar and 5% Hz) for 10 min. at temperatures
between 220
Cross-sectional
tively.
TEM (XTEM) specimens
were prepared
cooled stage.
Plan-
by
resolution
pole piece operated
Energy dispersive
performed
spectrometry
CX TEM/STEM.
A GaAs standard
of the EDS spectra.
was not available, considered
at 200 keV, respec(EDS) of x-rays was
with a Kevex model 3400 ultra-thin-window
tor and System 8000 spectrometer tiftcation
and 480°C. argon ion milling with a liquid nitrogen
Juty 1985
mounted
was used for partial quan-
Since a reliable Pd-Ga standard
the [Pd]:]Ga] ratios reported
below must be
tentative.
TEM images and co~s~nd~~ difhaction patterns from plan-view specimens of samples annealed I Low marination for 10 min. at (a,b) 22o’C and (c,d) 315’C. The diffraction pattern in (b) is the superposition of the polycrystalhne Pd ring pattern and the monocrystalline phase I spot pattern in <211b> zone-axis orientation. Diffraction spots from phases I and II are visible in (d). Fig.
410
detec-
on a JEOL 200
Fig. 2.
Cross sectional
TEM images
275 and 350°C respectively. ships described tation.
in the text.
of (a) the phase i/GaAs
The images Gallium
and (b) the phase II/GaAs
and their corresponding
arsenide
is in
electron
I 1> zone-axis
diffraction
orientation.
interfaces.
patterns
Samples
illustrate
were annealed
the orientation
Phase I and 11 are in ~000
at
relation-
I > zone-axis
orien-
Volume
3, number
9,lO
MATERIALS
July 1985
LETTERS
in Fig. l(c). At higher temperatures
3. Results and Discussion
II is the dominant The plan-view
micrograph
and diffraction
pattern
in Fig. 1
2(b) is a cross-sectional
image of the phase II/GaAs
(a,b) reveal that the first phase formed during low temperature
after annealing
at 35o’C.
annealing
with diffraction
patterns
orientation sectional
is nearly monocrystalline relationship
and has a well-defined
with the GaAs substrate.
Cross-
The inset diffraction from plan-view
phase II is also hexagonal
images from these samples (e.g. Fig. 2(a)) show that
phase I is hexagonal
(eg. 350 and 410°C) phase
phase in direct contact with GaAs.
Figure
interface
pattern
along
samples confirm
that
with
a0 = 0.92 ? 0.01 nm
with
a, = 0.673 * 0.002 nm CO = 0.370
In samples annealed
c, = 0.338 * 0.001 nm. The orientation
rel&ionship
+ 0.005 nm.
ing orientation
below 4Oo”C, phase II exhibits the follow-
relationship
with (100) GaAs:
with (100) GaAs is [OOOl]n // 101l]ciaAr and (213Oh1//
UWGaAs
This orientation
relationship
is evident in Fig. 2(b). Adjacent
Analysis of EDS data suggests a nominal composition of Pd,(GaAs), for phase I. These results are in close agreement
grains of phase II are often observed
with the findings
EDS spectra from grains of phase II yields a nominal
of Kuan [4].
Phase I is the dominant deposited
reaction
state and after annealing
3 15°C [7]. During annealing 4WC,
product
in the as-
at temperatures
at temperatures
at fast diffision
nm.
paths such as grain boundaries,
cracks in the phase I film.
The resulting
In addition
between 250 and
This second phase appears
is
to phases I and II, Pd,Ga
XTEM for some annealing ously reported
to nucleate
of our samples.
pores or
conditions
is shown
of diffraction
peak positions
(26’) measured of
Furthermore,
a major phase in previous
412
for PdAs, and phase II’
indexing
calculated
possible
calculated
based on
28 for
indexing
20 for
PdAs,[ 5)
PdAs,
as phase II
phase II
26.6 + 0.2
111
25.8
Oil1
26.6
30.8 + 0.2
200
29.9
2111
31.0
33.5 f 0.2 ‘36.5 & 0.2
212 211
45.5 36.8
072 1 __
33.0
50.7 f 0.2
311
50.6
0112
50.7
70.0 + 0.2 $72.3 + 0.2
420 421
70.4 72.4
0242 __
69.4 __
73.9 * 0.2
332
74.4
2750
74.5
(h - 0.1542nm)
+peak overlaps
with 200 PdGa
*peak overlaps
with 321 PdGa
a previin any
conditions
studies [5,6], our samples contained
from Fig. 1
PI
was detected by
[7]. However,
under annealing
peak position
*assuming CUKCI radiation
of
composi-
(25WC < T < SOOYZ)similar to those which yielded PdAs, as
morphology
Approximate
Analysis
phase, PdAs, [5,6], has not been detected
Table 1. Comparison
to be in twin orientation
[100]oti5 parallel to either [x3O]n or [z3Oin.
tion of Pd,GaAs.
up to
a second phase is formed if the initial Pd thickness
greater than -20
with
and aOIPdAs,] - 0.5982nm
Volume
3, number
MATERIALS
9.10
hexagonal
Pd,GaAs
tifications
of PdAs, were based on x-ray diffraction
as the major phase.
we have compared
the published
experimental
spectra from samples said to contain culated peak positions to the ternary
iden-
data only,
diffraction
July 1985
tory and Ariel Dori of Bell Laboratories, tance.
One of the authors
Table 1
Many valuable
Nicolet of the California
phase, Pd,GaAs.
assis-
discussions
Institute
Dr.
with the EDS ana-
lyses, and Ms. G. King for aiding in the preparation specimens.
solely to PdAs, can also be
for technical
(T.S.) wishes to acknowledge
T.R. Dinger and C. Ether for assistance
PdAs, [5,6] with the cal-
for phase II (-Pd,GaAs).
shows that the peaks attributed attributed
Since previous
LETTERS
of TEM
with Professor
of Technology
M-A.
are also grate-
fully acknowledged.
4. Conclusion 6. References It is clear from these results that the Pd-GaAs low temperatures ternary
phases.
(< 500°C) is dominated
these ternary materials
of silicides as shallow contacts
to silicon.
phases do not involve the inter-
facial accumulation
of arsenic,
ties of MIGaAs/GaAs
interfaces
into the factors which determine
In addition,
studies of the electrical should provide
M. Ogawa, Thin Solid Films, 70, (1980) 181.
123
A. Lahav and M. Eizenberg,
[3j
151
J.O. Olowolafe,
143.
the barrier heights of metallic
Woodall, [6]
[7] Microscopy,
P.S. Ho, M.J. Hovel, J.E. Lewis and J.M.
J. Appl. Phys., 50 (1979) 955.
X-F. Zeng and D.D.L. Chung. J. Vat. Sci. Technol.,
21
(1982) 611.
would like to thank the staff of the National
Center for Electron
and
T.S. Kuan, Mat. Res. Sac. Symp. Proc. Vol. -31 (1984)
5. Acknowledgements The authors
J.L. Freeouf, T.S. Kuan, T.N. Jackson
[4]
proper-
new insight
P. Oelhafen,
P.E. Batson, J. Vat. Sci. Techol., Bl (1983) 588.
since
phases on n and p type GaAs.
Appl. Phys. Len., 45 (1984)
256.
as
to the application
the reactions
to form MIGaAs
[l]
and the reac-
phases may find application
in direct analogy
of
can be limited
by proper choices of the initial Pd layer thickness shallow contact
at
by the formation
If the lateral inhomogeneities
tion temperature,
reaction
Lawrence
T. Sands, V.G. Keramidas,
R. Gronsky
and J. Wash-
bum, Thin Solid Films (1985) in press.
Berkeley Labora-
413