- Email: [email protected]
Channeled implantation with a parallel scanned ion beam
Nuclear Instruments and Methods North-Holland, Amsterdam
CHANNELED J.F.M.
IMPLANTATION
WESTENDORP,
R. SCHREUTELKAMP FOM-Instiiute
K.T.F.
in Physics
Research
B37/38
WITH A PARALLEL
R.E. KAIM
357
(1989) 357-360
SCANNED
ION BEAM
and C.B. ODLUM
and F.W. SARIS
for Atomic and Molecular Physics, Kruislaan 407, 1098 SJ Amsterdam,
The Netherlands
JANSSEN
Direct axial channeling, with the major crystal axis a!igned with the incident ion beam, can produce deep penetration of dopants at modest ion energies. In addition, damage levels are significantly reduced. When the ion beam is scanned parallel over the wafer, this deep penetration can be achieved at every location on the wafer, provided the change of the angle of incidence across the wafer is smail compared to the critical angle for channeling. Also, if implants in a random direction are done, the implant will be random all across the wafer, resulting in a homogeneous dopant depth profile. Si wafers of up to 150 mm have been impianted under channeling and random conditions. Dopant and lattice damage profiles were measured with Rutherford backscattering and SIMS. The reproducibility and applicability of the axial channeling implant technique are discussed.
1. Introduction One of the principal requirements of ion implantation is that the implant be uniform in dose, with VLSI processing trends imposing stringent limits on allowable dose variation across a wafer. However, an equally important parameter that characterizes an implant is the dopant depth distribution. Theory can adequately predict implantation profiles into amorphous materials [l-3], but in practice most implants in VLSI fabrication are done in single-crystalline Si and GaAs. In singlecrystal lattices there are certain directions along which incident ions have a greatly reduced probability of colliding with lattice atoms. This phenomenon, called channeling, enables ions to be steered into an open axial or planar direction and can give rise to penetration depths as much as an order of magnitude larger than for ions implanted into amorphous material. In addition, the amount of damage to the crystal lattice caused by channeled ions is much less than for ions incident in a nonch~neled direction. The possibility of reducing lattice damage, or of obtaining deeply implanted junctions at modest ion energies, makes deliberate channeling an attractive prospect for some implants. The principal requirement for successful applications of this channeled implant technique is that the degree of channeling should be uniform at all points on the wafer. The probability of an ion being channeled depends on the angle between the ion trajectory and the crystallographic direction: for 0168-583X/89/$03.50 0 Elsevier Science Publishers B.V. (North-Holland Physics Publishing Division)
angles larger than the “critical angle” the probability is greatly reduced. The requirement that channeling should be uniform in a channeled implant therefore implies that the change of angle of incidence across the wafer surface be much less than the critical angle for channeling and that the alignment of the Si wafer with respect to the beam be accurate and reproducible. Ion implanters employ different methods of spreading ions uniformly over the surface of a wafer and the consequent variation of the angle of incidence depends on the type of implanter, as is illustrated in fig. 1. In an implanter where the beam is rastered electrostatically in two dimensions over a single wafer (fig. la) the variation in implant angle across a 150 mm wafer is typically 5 O. In batch implanters employing mechanical rotation of a disc or drum the wafer is tilted away from the plane normal to the rotation axis to achieve clamping of the wafer by the resulting centrifugal force. If the ion beam is also tilted with respect to the axis of rotation (fig. lb), the implant angle changes as the wafer is rotated past the beam. The side-to-side implant angle variation is dependent on the angles involved and on the ratio of the radii of the wafer and the disc, but is typically 2-3” for a 200 mm wafer. Critical channeling angles for the ions used in VLSf implantation range typically from 2O to 4O. Fig. 2 gives calculated [4] values of the critical angle for (100) axial channeling in Si as a function of energy for B, P and As ions. The variation of the implant angle across the wafer for the implanters illustrated in figs. la and lb is of the IV. ION IMPLANTATION
358
J. F. M. Westendorp et al. / Channeled implantation with a parallel scanned ion beam directions, implanted
the maximum wafer diameter that could uniformly amounted to only 38 mm.
Recently,
a new ion implanter
to the market parallel, neled
which, because
has the potential
on wafers
is a serial
trostatic/mechanical zontal
the
the beam
implant
scanned than
(c)
magnet
angle by
beam.
0.35O
than 0.5O
side-to-side
same order
of magnitude
as the critical
with these implanters
tion is not maintained of a wafer.
while
An implant
angles.
Conse-
a well channeled
condi-
scanning
performed
to axial channeling harness
the effect
As a result,
in the industry
common
practice
the incident
for axial
An attempt doping
channeling ASM-220
of seeking
to
the strategy
150 mm, n-type
which
between
uniformity
was
scan system using double
eliminates
ion implantation et al. [6]. Although
achieved
electrostatic
with
a parallel
deflection
in both
CRITlCAL ANGLE FOR AXIAL (100) CHANNELNG
at various while
the twist
on the wafer plantation
axial in the
orienta-
of energies
while for the B+ implants The implants
corresponds being
defined
and the wafer
or rota-
to the major
horizontally.
damage
profiles
backscattering
as
normal
to the azimuthal
positioned
vari-
were performed
the tilt being
the ion beam
ion-induced
flat
After
im-
were measured
and channeling
with 1
angle of 170 O. Other wafers
were annealed
at 950 o C for 30 minutes
dry nitrogen
after implant and
sheet
resistance
on a Prometrix
performed
using
profiles
were
primary
beam
rastered
profiles
were
recorded
beam rastered analysed
RS-30
measurements system.
a Cameca determined
(M/AM
SIMS
IMS with
in
were analysis
3f instrument. a 10.5
keV
0:
over 350 km X 350 pm, while P using
a 14.5
keV
Cs+
primary
over 250 pm x 250 pm. In both cases
area of 60 pm diameter
phosphorus
I
substrate
MeV He ions at a detection
Boron
DEV,AT,ON FROM PARALLELI%
of (100)
tional angle. A twist of 0 o corresponds
was
40
of uniform implanted
P+ and B+ ions
tilt and twist angles,
performed
/-
in Si (see
100 and 200 keV. The dose for the P+ implants
using Rutherford
D0
with
the angle between channeled
less
channeling
(100)
Si wafers
tion were implanted
ous doses were employed.
by Nishi
and
less than
2. Experimental
away from
to perform
the
implanter.
is to tilt the wafer normal
been reported
of
to be less
[9], i.e. much
150 mm Si wafers
was 2 X 1Ol4 ions/cm2,
by 5-7”
has been shown
we will give evidence
across
it [5]. The
direction
is only
for a 150 mm wafer
to avoid
beam
has been
due
axial channeling.
has already high
condi-
on the wafer and
instead
of direct axial channeling,
adopted
direct
these
depth variations
at some locations
less or none at others.
wafer
parallelism
over the surface
under
tions will give rise to large junction
dimension this system,
fig. 2). In this article
quently,
the
from
The deviation
angle
of a nonuni-
With
across
deviation
for a 200 mm wafer
the critical
electrostatically
by means
translated.
elec-
In the hori-
[8]. In the vertical
variation
the
chan-
as 200 mm.
with a hybrid
is scanned
is mechanically
determined
Fig. 1. Schematic representation of different ion beam scanning techniques employed in (a) an X-Y electrostatically scanned implanter, (b) a batch implanter and (c) the ASM-220.
implanter
scan is achieved
form field dipole the wafer
applying
as large
scan [7] (see fig. lc).
direction
and a parallel
introduced
its beam scan is accurately
of successfully
ion implantation
The ASM-220
has been
be
measurements
> 4000)
was
was chosen.
high
necessary
mass
to separate
For
an the
resolution “P
from
30Si1H. SO
120
160
2w
IDN ENERGY (keb’)
Fig. 2. Critical angle for axial (110) charmeling in Si as a function of ion energy, for As, P and B ions. The deviation from parallelism in the ASM-220 is shown for comparison.
3. Results Fig.
3 shows
spectra
measured
1 MeV
He Rutherford
on wafers
implanted
backscattering with 100 keV P+
J. F.M. Westendorp et al. / Channeled implantation
1OOkeV
*---_
t
DEPTH
P++Si
with a parallel scanned ion beam
359
(100).6’
(urn)
Fig. 5. SIMS depth profiles for random and channeled phosphorus implants into silicon.
B--__.c_-___-_____
Fig. 3. 1 MeV He Rutherford backscattering spectra for random aad channeled phosphorusimplants into silicon.
ions under different tilt and twist angles. The random implant was performed at a tilt angle of 10 o and a twist of 150, while in the case of the channeled implant both angles were 0 O. The difference between the two cases is striking: the random implant yields a damage profile that peaks at a depth of about 1000 A, which is consistent with a TRIM [3] calculation for a 100 keV P+ implant into amorphous Si, while for the channeled implant the bulk of the damage is produced much deeper in the substrate, with a peak at roughly 1650 A. In addition, the overall damage level is significantly reduced for the channeled implant. This implies that for the 0” implants the bulk of the implanted ions are well
channeled and are deposited at greater depths. Most importantly, however, channeling spectra measured at three locations along a line parallel to the horizontal electrostatic scan direction (see fig. lc.) show identical damage depth profiles. This means that the well channeled condition is maintained all across the wafer. Sheet resistance measurements constitute a very sensitive measure of junction depth uniformity on implanted wafers. Therefore wafers were implanted under the same channeled and random conditions as above and sheet resistance maps were recorded. The maps in fig. 4 show that the mean sheet resistance of the channeled implant (fig. 4a) is 20% lower than for the random implant (fig. 4b). However, there is no degradation of uniformity on the channeled implanted wafer of the
WNNfLEDMPVINT 2 1OOke” P .2E14 0NSlCM c MAN
=.71x = 206.6
J-L/~
Fig. 4. Sheet resistance maps for random and channeled phosphorus implants into silicon. The sheet resistance is measured on 81 sites on the wafer, (I is the standard deviation in percent. IV. ION IMPLANTATION
360
J.F.M.
Westendorp
et al. / Channeled
implantation
with a parallel
scanned
ion beam
4. Discussion The
above
results
demonstrating It has been
shown
a significant
while
yields
still
step
of channeled
that channeled
150 mm Si wafers depths
are
the feasibility
much
ion implantation larger
maintaining
towards
implantation.
good
uniformity.
Since
the parallelism
of the beam
scan
in the ASM-220
been
over
field
of 250
qualified
reason
to expect
a scan
that similar
on
ion penetration
uniformity
mm,
has
there
is
can be attained
for 200 mm wafers. For channeled cable
ion implantation
technique
and
in VLSI
wafer-to-wafer
These graphic
orientation
standard enting
wafers)
have
surface
perpendicular
study of the effects
conducted.
reproducible the
from wafer
dependence
measurements about dopant profiling performed Fig. 6. SIMS depth
profiles for random and channeled boron implants into silicon.
wafers.
type
expect
References
one
contour
would
Finally,
Si wafers
ions under identical as above
profiles
by SIMS.
observed. plants
penetration
depth along
B+ (b).
From
profiles,
depth
species for
for the chan-
Fig.
6 shows
with 2 x 1015 ions/cm’ at
three
are identical.
channeled
condition
This
again
is maintained
these of 200
that SIMS
different
to the horizontal
locations
electrostatic
means across
is im-
B+ implant
fig. 6b it is also evident
direction,
profile
for channeled
5 X 1015 ions/cm*
measured
a line parallel
conditions
tail in the depth
B + ions.
with
for a 100 keV,
(a) and for an implant keV
P+ and B+
of the implanted
tail is not observed
performed
profiles
with
and random
Fig. 5 shows depth profiles
a profound
This
(i.e.
on
results
been
do not provide depth profiles.
measurements on
channeled
are
ion
in ori-
beam.
look
very prom-
therefore
because
sheet
unambiguous Additional
for
to be extremely
However,
mobility,
and
An
is now
and uniformity
found
to wafer.
carrier
for SEMI
information
SIMS
and C-V
presently
randomly
of
resistance
being
implanted
flat).
with a dose of 2 X 1014 ions/cm*.
the enhanced implant,
in parallelism
were implanted
a 100 keV P+ implant Besides
errors
to the major
channeled
and depth
were recorded
neled
for
lines perpendicular
have
(lo
of these tolerances
Preliminary
implants
addressed. in crystallo-
tolerances
to the
ising since the mean sheet resistance channeled
to be
by the tolerance
of the wafer
an appli-
of reproducibility
and the mechanical
the wafer
extended being
uniformity
will be determined
to become
the issues
scan
that the well the wafer.
[l] J. Lindhard, M. Scharff and H. Schiott, K. Dan. Vidensk. Selsk. Mat. Fys. Medd. 33 (1963) 1. [2] K.B. Winterbon, Ion Implantation Range and Energy Deposition Distributions, vol. 2 (Plenum, New York, 1975). [3] J.F. Ziegler, J.P. Biersack and U. Littmark, The Stopping and Ranges of Ions in Solids, vol. 1 (Pergamon Press, New York, 1984). [4] MI. Current, N.L. Turner, T.C. Smith and D. Crane, Nucl. Instr. and Meth. B6 (1985) 336. [5] K. Cho, W.R. Allen, T.G. Finstad, W.K. Chu, J. Liu and J.J. Wortman, Nucl. Instr. and Meth. B7/8 (1985) 265. [6] H. Nishi, T. Inada, T. Sakurai, T. Kaneda, T. Hisatsugu and T. Furuya, J. Appl. Phys. 49 (1978) 608. [7] ASM-220 Ion Implanter, ASM Ion Implant, Beverly, MA, USA. [8] U.S. Patent No. 4,276,477. [9] R.E. Kaim and J.F.M. Westendorp, to be published.
CHANNELED J.F.M.
IMPLANTATION
WESTENDORP,
R. SCHREUTELKAMP FOM-Instiiute
K.T.F.
in Physics
Research
B37/38
WITH A PARALLEL
R.E. KAIM
357
(1989) 357-360
SCANNED
ION BEAM
and C.B. ODLUM
and F.W. SARIS
for Atomic and Molecular Physics, Kruislaan 407, 1098 SJ Amsterdam,
The Netherlands
JANSSEN
Direct axial channeling, with the major crystal axis a!igned with the incident ion beam, can produce deep penetration of dopants at modest ion energies. In addition, damage levels are significantly reduced. When the ion beam is scanned parallel over the wafer, this deep penetration can be achieved at every location on the wafer, provided the change of the angle of incidence across the wafer is smail compared to the critical angle for channeling. Also, if implants in a random direction are done, the implant will be random all across the wafer, resulting in a homogeneous dopant depth profile. Si wafers of up to 150 mm have been impianted under channeling and random conditions. Dopant and lattice damage profiles were measured with Rutherford backscattering and SIMS. The reproducibility and applicability of the axial channeling implant technique are discussed.
1. Introduction One of the principal requirements of ion implantation is that the implant be uniform in dose, with VLSI processing trends imposing stringent limits on allowable dose variation across a wafer. However, an equally important parameter that characterizes an implant is the dopant depth distribution. Theory can adequately predict implantation profiles into amorphous materials [l-3], but in practice most implants in VLSI fabrication are done in single-crystalline Si and GaAs. In singlecrystal lattices there are certain directions along which incident ions have a greatly reduced probability of colliding with lattice atoms. This phenomenon, called channeling, enables ions to be steered into an open axial or planar direction and can give rise to penetration depths as much as an order of magnitude larger than for ions implanted into amorphous material. In addition, the amount of damage to the crystal lattice caused by channeled ions is much less than for ions incident in a nonch~neled direction. The possibility of reducing lattice damage, or of obtaining deeply implanted junctions at modest ion energies, makes deliberate channeling an attractive prospect for some implants. The principal requirement for successful applications of this channeled implant technique is that the degree of channeling should be uniform at all points on the wafer. The probability of an ion being channeled depends on the angle between the ion trajectory and the crystallographic direction: for 0168-583X/89/$03.50 0 Elsevier Science Publishers B.V. (North-Holland Physics Publishing Division)
angles larger than the “critical angle” the probability is greatly reduced. The requirement that channeling should be uniform in a channeled implant therefore implies that the change of angle of incidence across the wafer surface be much less than the critical angle for channeling and that the alignment of the Si wafer with respect to the beam be accurate and reproducible. Ion implanters employ different methods of spreading ions uniformly over the surface of a wafer and the consequent variation of the angle of incidence depends on the type of implanter, as is illustrated in fig. 1. In an implanter where the beam is rastered electrostatically in two dimensions over a single wafer (fig. la) the variation in implant angle across a 150 mm wafer is typically 5 O. In batch implanters employing mechanical rotation of a disc or drum the wafer is tilted away from the plane normal to the rotation axis to achieve clamping of the wafer by the resulting centrifugal force. If the ion beam is also tilted with respect to the axis of rotation (fig. lb), the implant angle changes as the wafer is rotated past the beam. The side-to-side implant angle variation is dependent on the angles involved and on the ratio of the radii of the wafer and the disc, but is typically 2-3” for a 200 mm wafer. Critical channeling angles for the ions used in VLSf implantation range typically from 2O to 4O. Fig. 2 gives calculated [4] values of the critical angle for (100) axial channeling in Si as a function of energy for B, P and As ions. The variation of the implant angle across the wafer for the implanters illustrated in figs. la and lb is of the IV. ION IMPLANTATION
358
J. F. M. Westendorp et al. / Channeled implantation with a parallel scanned ion beam directions, implanted
the maximum wafer diameter that could uniformly amounted to only 38 mm.
Recently,
a new ion implanter
to the market parallel, neled
which, because
has the potential
on wafers
is a serial
trostatic/mechanical zontal
the
the beam
implant
scanned than
(c)
magnet
angle by
beam.
0.35O
than 0.5O
side-to-side
same order
of magnitude
as the critical
with these implanters
tion is not maintained of a wafer.
while
An implant
angles.
Conse-
a well channeled
condi-
scanning
performed
to axial channeling harness
the effect
As a result,
in the industry
common
practice
the incident
for axial
An attempt doping
channeling ASM-220
of seeking
to
the strategy
150 mm, n-type
which
between
uniformity
was
scan system using double
eliminates
ion implantation et al. [6]. Although
achieved
electrostatic
with
a parallel
deflection
in both
CRITlCAL ANGLE FOR AXIAL (100) CHANNELNG
at various while
the twist
on the wafer plantation
axial in the
orienta-
of energies
while for the B+ implants The implants
corresponds being
defined
and the wafer
or rota-
to the major
horizontally.
damage
profiles
backscattering
as
normal
to the azimuthal
positioned
vari-
were performed
the tilt being
the ion beam
ion-induced
flat
After
im-
were measured
and channeling
with 1
angle of 170 O. Other wafers
were annealed
at 950 o C for 30 minutes
dry nitrogen
after implant and
sheet
resistance
on a Prometrix
performed
using
profiles
were
primary
beam
rastered
profiles
were
recorded
beam rastered analysed
RS-30
measurements system.
a Cameca determined
(M/AM
SIMS
IMS with
in
were analysis
3f instrument. a 10.5
keV
0:
over 350 km X 350 pm, while P using
a 14.5
keV
Cs+
primary
over 250 pm x 250 pm. In both cases
area of 60 pm diameter
phosphorus
I
substrate
MeV He ions at a detection
Boron
DEV,AT,ON FROM PARALLELI%
of (100)
tional angle. A twist of 0 o corresponds
was
40
of uniform implanted
P+ and B+ ions
tilt and twist angles,
performed
/-
in Si (see
100 and 200 keV. The dose for the P+ implants
using Rutherford
D0
with
the angle between channeled
less
channeling
(100)
Si wafers
tion were implanted
ous doses were employed.
by Nishi
and
less than
2. Experimental
away from
to perform
the
implanter.
is to tilt the wafer normal
been reported
of
to be less
[9], i.e. much
150 mm Si wafers
was 2 X 1Ol4 ions/cm2,
by 5-7”
has been shown
we will give evidence
across
it [5]. The
direction
is only
for a 150 mm wafer
to avoid
beam
has been
due
axial channeling.
has already high
condi-
on the wafer and
instead
of direct axial channeling,
adopted
direct
these
depth variations
at some locations
less or none at others.
wafer
parallelism
over the surface
under
tions will give rise to large junction
dimension this system,
fig. 2). In this article
quently,
the
from
The deviation
angle
of a nonuni-
With
across
deviation
for a 200 mm wafer
the critical
electrostatically
by means
translated.
elec-
In the hori-
[8]. In the vertical
variation
the
chan-
as 200 mm.
with a hybrid
is scanned
is mechanically
determined
Fig. 1. Schematic representation of different ion beam scanning techniques employed in (a) an X-Y electrostatically scanned implanter, (b) a batch implanter and (c) the ASM-220.
implanter
scan is achieved
form field dipole the wafer
applying
as large
scan [7] (see fig. lc).
direction
and a parallel
introduced
its beam scan is accurately
of successfully
ion implantation
The ASM-220
has been
be
measurements
> 4000)
was
was chosen.
high
necessary
mass
to separate
For
an the
resolution “P
from
30Si1H. SO
120
160
2w
IDN ENERGY (keb’)
Fig. 2. Critical angle for axial (110) charmeling in Si as a function of ion energy, for As, P and B ions. The deviation from parallelism in the ASM-220 is shown for comparison.
3. Results Fig.
3 shows
spectra
measured
1 MeV
He Rutherford
on wafers
implanted
backscattering with 100 keV P+
J. F.M. Westendorp et al. / Channeled implantation
1OOkeV
*---_
t
DEPTH
P++Si
with a parallel scanned ion beam
359
(100).6’
(urn)
Fig. 5. SIMS depth profiles for random and channeled phosphorus implants into silicon.
B--__.c_-___-_____
Fig. 3. 1 MeV He Rutherford backscattering spectra for random aad channeled phosphorusimplants into silicon.
ions under different tilt and twist angles. The random implant was performed at a tilt angle of 10 o and a twist of 150, while in the case of the channeled implant both angles were 0 O. The difference between the two cases is striking: the random implant yields a damage profile that peaks at a depth of about 1000 A, which is consistent with a TRIM [3] calculation for a 100 keV P+ implant into amorphous Si, while for the channeled implant the bulk of the damage is produced much deeper in the substrate, with a peak at roughly 1650 A. In addition, the overall damage level is significantly reduced for the channeled implant. This implies that for the 0” implants the bulk of the implanted ions are well
channeled and are deposited at greater depths. Most importantly, however, channeling spectra measured at three locations along a line parallel to the horizontal electrostatic scan direction (see fig. lc.) show identical damage depth profiles. This means that the well channeled condition is maintained all across the wafer. Sheet resistance measurements constitute a very sensitive measure of junction depth uniformity on implanted wafers. Therefore wafers were implanted under the same channeled and random conditions as above and sheet resistance maps were recorded. The maps in fig. 4 show that the mean sheet resistance of the channeled implant (fig. 4a) is 20% lower than for the random implant (fig. 4b). However, there is no degradation of uniformity on the channeled implanted wafer of the
WNNfLEDMPVINT 2 1OOke” P .2E14 0NSlCM c MAN
=.71x = 206.6
J-L/~
Fig. 4. Sheet resistance maps for random and channeled phosphorus implants into silicon. The sheet resistance is measured on 81 sites on the wafer, (I is the standard deviation in percent. IV. ION IMPLANTATION
360
J.F.M.
Westendorp
et al. / Channeled
implantation
with a parallel
scanned
ion beam
4. Discussion The
above
results
demonstrating It has been
shown
a significant
while
yields
still
step
of channeled
that channeled
150 mm Si wafers depths
are
the feasibility
much
ion implantation larger
maintaining
towards
implantation.
good
uniformity.
Since
the parallelism
of the beam
scan
in the ASM-220
been
over
field
of 250
qualified
reason
to expect
a scan
that similar
on
ion penetration
uniformity
mm,
has
there
is
can be attained
for 200 mm wafers. For channeled cable
ion implantation
technique
and
in VLSI
wafer-to-wafer
These graphic
orientation
standard enting
wafers)
have
surface
perpendicular
study of the effects
conducted.
reproducible the
from wafer
dependence
measurements about dopant profiling performed Fig. 6. SIMS depth
profiles for random and channeled boron implants into silicon.
wafers.
type
expect
References
one
contour
would
Finally,
Si wafers
ions under identical as above
profiles
by SIMS.
observed. plants
penetration
depth along
B+ (b).
From
profiles,
depth
species for
for the chan-
Fig.
6 shows
with 2 x 1015 ions/cm’ at
three
are identical.
channeled
condition
This
again
is maintained
these of 200
that SIMS
different
to the horizontal
locations
electrostatic
means across
is im-
B+ implant
fig. 6b it is also evident
direction,
profile
for channeled
5 X 1015 ions/cm*
measured
a line parallel
conditions
tail in the depth
B + ions.
with
for a 100 keV,
(a) and for an implant keV
P+ and B+
of the implanted
tail is not observed
performed
profiles
with
and random
Fig. 5 shows depth profiles
a profound
This
(i.e.
on
results
been
do not provide depth profiles.
measurements on
channeled
are
ion
in ori-
beam.
look
very prom-
therefore
because
sheet
unambiguous Additional
for
to be extremely
However,
mobility,
and
An
is now
and uniformity
found
to wafer.
carrier
for SEMI
information
SIMS
and C-V
presently
randomly
of
resistance
being
implanted
flat).
with a dose of 2 X 1014 ions/cm*.
the enhanced implant,
in parallelism
were implanted
a 100 keV P+ implant Besides
errors
to the major
channeled
and depth
were recorded
neled
for
lines perpendicular
have
(lo
of these tolerances
Preliminary
implants
addressed. in crystallo-
tolerances
to the
ising since the mean sheet resistance channeled
to be
by the tolerance
of the wafer
an appli-
of reproducibility
and the mechanical
the wafer
extended being
uniformity
will be determined
to become
the issues
scan
that the well the wafer.
[l] J. Lindhard, M. Scharff and H. Schiott, K. Dan. Vidensk. Selsk. Mat. Fys. Medd. 33 (1963) 1. [2] K.B. Winterbon, Ion Implantation Range and Energy Deposition Distributions, vol. 2 (Plenum, New York, 1975). [3] J.F. Ziegler, J.P. Biersack and U. Littmark, The Stopping and Ranges of Ions in Solids, vol. 1 (Pergamon Press, New York, 1984). [4] MI. Current, N.L. Turner, T.C. Smith and D. Crane, Nucl. Instr. and Meth. B6 (1985) 336. [5] K. Cho, W.R. Allen, T.G. Finstad, W.K. Chu, J. Liu and J.J. Wortman, Nucl. Instr. and Meth. B7/8 (1985) 265. [6] H. Nishi, T. Inada, T. Sakurai, T. Kaneda, T. Hisatsugu and T. Furuya, J. Appl. Phys. 49 (1978) 608. [7] ASM-220 Ion Implanter, ASM Ion Implant, Beverly, MA, USA. [8] U.S. Patent No. 4,276,477. [9] R.E. Kaim and J.F.M. Westendorp, to be published.