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InP wires
Microelectronic Engineering 11 (1990) Elsevier Science Publishers B.V.
11
1 l-14
Magnetoresistance
measurements InGaAs/InP
A. Menschig. 4. Physikalisches D 7000
wires
A. Forchel.
B. Roos.
, Universitat
Institut Stuttgart
R. Germann
Stuttgart
. Federal
80
ln microstructured
Pfaffenwaldring
Republic
57
of Germany
W. Heuring Physikalisches
Institut.
Universit;it
Wiirzburg.
D 8700
Wtirzburg
D. Grutzmacher Institut
ANract.
Microstructured
ted
modulation
from
40mK.
The
about
4
and
The
compared
higher
Introd~ctlon. pers and
2D
focused to
etching, to
metal
of
of
wide
wires. level
Most
narrow In
this
paper
In,,sGa.,rAs/InP wire
definition,
low
pressure
quantum
level
wires strong we
The
the
50pm
with
decreasing only
fabrica-
fields
down
wire
very
a distinct
magnetic
were
magnetoresistance
indicating
on
to
width
only
dry
etch
small
resistance
and
maximum
Shubnikov-de-Haas
etch
is
are carrier
doped density
an electron
reduce
to
a lot
pain
transition
of
work
3D
from
has
nanostructures
been
C21 and
C41. by
the
effective
the
observation
be
of
deep
are
or
the
wire
shallow damage
width. of
ascribed
depleted
dry leads
Depleted
1D
effects
in
to
pinning
of
less
thicknesses
should
important
properties be
of
h
*
especially
than etched
20nm
steep
and
C61. in
be observed. and
widths the &
is
and
studies SOurn.
heterostructures localized
two-dimensional
= 100000
0167-9317/90/$3.500 1990, Elsevier Science Publishers B.V.
80nm
double
2DEG
at 2K in the
magnetotransport
between
In .ssGa.aTAs/InP
mobility
optical
layer
fabrication
which
significantly
the
in InGaAs
should
in
the
In particular,
layers
theoretical properties
sidewalls.
known
geometrical used,
now wires
damage.
depleted
typical
the
to
on
fabricated
allowed
etched
potential
on
Up
and
transport
inversion-layer
wires,
the
the
of
GaAs/GaAlAs
dry
pinning
experimental
concentrated
silicon
which
1D effects
with
of
dependence
CSI have
indicate
modulation
crnA2 with
number
investigations
report
wires MOVPE
well.
= 1.3 * 10”
and
finite
B10.3T.
lower
Aachen
80nm
a
width, for
at
etched
layers
1D confinement
channels
between
behaviour.
commonly
particular,
the
wire
interest
Ill,
on
at mid-gap
In,ssGa,,7As/InP
increases
quantum
150nm
in
Therefore
wires
the
wires
depleted
about
Fermi
In
of the
a large
131 or dry
In In.ssGa.47As GaAs.
show
(UCF’s)
recently
significantly
formation
Fermi
wires
dimensionality
GaAs/AlGaAs
widths
0.4pm the
of
depend
the
layer
years
the
defined
properties
widths
All
5Oirrrt
one-dimensional
small
electrostatically The
past
More
two-dimensional on
D 5100
with
magnetoresistance
fluctuations
on
systems.
published
at
Aachen.
fields. the
In
have
value
a negative
resistance
at
wires
heterostructures.
to the
show
reproducible
oscillations
RWTH
= OT. T = 40mK)
(B
wires
Halbleitertechnik.
In ,S3Ga,47As doped
resistivity
times
damage.
fur
cm’/Vs.
in
the
grown
by
a 12nm
electron
of
For
gas
InGaAs is N2D
12
A. Menschig
Sample
Z4eparation
fabricated
by
lithography used.
aM-CMS on,
resists the
has
high
some
various
between ration
80nm
Exposure resist
gas
mixture
depths On
and
at
were
advantage
that
each
microscope.
perature
measurements
the
into
magnetotransport
the
energies etch
etch
(65nm) of
gold-wire out the
experiments
C81. Compared
for
x-ray
contrast
a series 20pm
of
long
(y
we
spot
SOpm wires
>
used
sizes
of
a SOkV
accele-
1Onm
to
were with
different
the
with
with
exactly
the were field
a lock-in
the
were of to
same measured
a 80nm
with
at
perpendicular
Figure
etch
the
This
wire.
refrigerator was
ArIO spacer
has
technological
the
technique
an
well.
widths.
contact
oriented
and
quantum
different
picture
dilution
layer
InGaAs/InP
wires used
doping
25nm.
used.
. Two
the
a
wires widths
milling
11 wires
8),
long
by ion
and
through
to
with
80 $/cm’(aM-CMS)
in which
were
applicati-
SOOeV
in a He3/He4 magnetic
40nm high
exposure
250eV
an SEM
bonds
an expe-
CXM-CMS
heterostructure
of
1 shows
of
with
of
resist
of
fabricated
dimensions
with
and
pads, beam
C71.
of
beam
current
(S2nm),
a set
was
Figure
carried
40mK
electron beam
tone
contact electron
available to
a very
solutions
a series
by
developed
consists
and
(RAY-PN)
prepared
geometrical
were and
the
etched
wire
pattern
SOOpA
down
example
in aqueous
SOpm)
For
to
a deep
we
The
4K
up
a medium
meters.
surements
to
was
electron
ween
resist
(120nm
40 PC/cm*
and
sample
defined
negative
originally
for
defined
commercially
patterns
RAY-PN,
advantages:
acceleration
used:
removed, each
of
pattern
resist
of
were
sensitive,
and the
definition
beam
420nm.
20pA
doses
The
were
widths
voltage,
)
AuGe/Ni/Cr/Au
wires
an electron
no degradation
lithographically
with
the
interesting and
As
( RAY-PN
allow
electron
sensitivity
The
etching. resist
measurements
alloyed
In .s3Ga,,7As
lithography,
dry
electron
Both
Between
and measurement.
optical
and
rimental
et al. / Magnetoresistance
mainly
For
sample.
a
the
parascanning low
tem-
The
mea-
temperatures to
the
bet-
2DEG.
used.
1:
A SEM picture of a 80nm InGaAs/ InP wire fabricated
with a RAYPN
etch mask and dry etch techmque.
For
13
A. Menschig et al. I Magnetoresistance measurements Experimental results. Figure 2 depicts GaAs
wires
at
widths below ring
40mK
for
zero
the resistivity
magnetic
iurn. This is due to the influence
at the etched
temperature
sidewalls
the resistivity
4 higher than the constant
InGaAdlnP
charge
or
resistivity
depleted
(medium
value defined
Ar/o,
.
a.
T-M
active
surements are nearly Maile et al. 181.
wire
width
identical
therefore
By performing
magnetotransport of
the
electron
values
Typical
fields
2) At fields defined
should
magnetic
appear for
wire width. good
negative
region
field
from
depleted
layer
here from
resistance
mea-
in
experiments
40mK
optical
we
have investigated
curves
of
3 . Four features
magnetoresistance
a distinct
scales
decreasing
resistance amplitudes
with
a 80 nm
by
the
and a
should be menti-
usually
with cyclotron
fluctuations (universal
resistance the
magnetic
The half height position
agreement
calculated
resistance.
attributed
to
is observed.
but very irregular
3) In the same field
at
resistance
in figure
B 1 0.3 T reproduceable
periodicity
sponding
the typical
effects
20nm and the
extracted
determined
measurements gas.
190nm wire taken at 40mK are plotted oned. low
is about
layer widths
with
dimensionality
very
leads to a cut-off
width for finite
1OJ wire width I_, / n:
30nm. The values for the depleted
1) At
polation
8 -110,4
I~~~~,
weak localisation
- width dependence
wires at 40mK.
63nm
geometric01
electrical
width dependence
4.2K and 300K. A linear extra-
.
0.
52nm
ld
The
of
wires at 40mK.
of InGaAs
. .
this
2:
Conductivity
. .
At
a factor
Inset:
. .
200
wire
wire widths.
of InGaAs
.
I
L ; u
etch depth
regions.
Resistivity InGaAvlnP j60
for
by e.g. scatte-
is only about
by the larger
¶d
l
sidewall
Figure
of the In-
increases
sidewall
etch)
#80
T=4OmK
dependence
resistivity
of the wire
carrier
of a 80nm wire
- width
The
field.
wire
field,
if
which
have no
fluctuations).
maximum is obvious. The correA rise in magnetoresistance
width.
the cyclotron
and the field
diameters
appear
conductance
position
and cyclotron
diameter
reaches
of the maximum
radii positions,
the
are in
respectively,
the 2D carrier density and the measured wire widths.
4) At
higher magnetic fields typical Shubnikov-de-Haas oscillations are observed. of the quantum numbers of the The inset of figure 3 shows a usual fan diagram magnetoresistance minima plotted versus the reciprocal magnetic field. No deviation from the linear l/B dependence down to 0.8 T is found for wires wider than 310nm. But pronounced tes
the formation
deviations
are obvious
of 1D subbands
C91.
for
the smaller
wires.
The
deviation
indica-
A. Menschig et al. I Magnetoresistance measurements
14
lnGa,&/lnP
#8()
InGaAs/lnP
l
#80
. . ..****.*.3lonm
c 40_
01
6
5
I
I
1
2.5
0
I
7.5 field
rnogn~k~
10.0
[ T I
Figure 3: Two typical curves of longitudinal resistance (80nm and 190nm wire width) at 40mK are shown. The inset depicts procal magnetic
field
Ihe dependence
for different
of Landau level number over Ihe reci-
wire widths (310nm.
190nm.
150nm.
IlOnm and
80nm).
COZZC~US~OXI. We have a finite res down ductance
to 80nm. fluctuations
with large
nikov-de-Haas-oscillations surface
scattering
due
in our medium
and G. Landwehr
RAY-PN.
for
the experimental
K. Thonke state.
and K. Pressel
for
A. Benoit. C.P. Umbach. R.B. Laibowitz.
stimulating
making
assistance the help
universal
in the periodicity
ID subbands
corporation
We acknowledge
. We thank K. Grijtsch
Steinmetz
of
InGaAs/InP
we found and
of
an
their
discussions
with
available
at the
with
for providing
his analyzing
He3/He4
-
M.L. Roukes. A. Scherer. S.J. Allen,
the measurements
experimenM. Pilkuhn
cryostate
R.A. Webb; Phys. Rev. Lett. 58
H.G. Craighead.
, 2343 (1987)
T. Demel. D. Heitmann. P. Grambow. K. Ploog, Appl.
Phys. Lell. 53
B.E. Maile.
Appl. Phys. Lett. 54
R. Dammel. K.-F. D&sel. J. Lingnau. J. Theis: Microelectr. B.E. Maile.
A. Forchel.
R. Germann. A. Menschig.
Eng. 7
J.P. Harbison,
H.P. Meier; J. Vat.
G. Roos. H. van Houten: Phys. Rev. B37
2176 (1988) 1552 (1989)
. 575 (1988)
2308 (1988) K.-F. Berggren.
951 (1982)
, 1769 (1986)
R.M. Ruthen. E.D. Beebe,
R. Germann. D. Griitzmacher;
10118 (1988)
N. and
at our magnet-cryo-
, 3011 (1987)
A. Forchel.
of
program,
dilution
T.J. Thornton. D.J. Newson. M. Pepper; Phys. Rev. Lett. 57
Phys. Rev. Lett. 59
the Shub-
influence
W.J. Skocpol. L.D. Jackel. E.L. Hu. R.E Howard, L.A. Fetter; Phys. Rev. Lett. 49 K.-F. Berggren.
wicon-
transport.
We thank the Hoechst
system
changes
formation field
deep etched
measurements
amplitudes, to
on low magnetic
A&owledgement. tal resist
resistance
In the magnetotransport
Sci. Technol.
B6
11
1 l-14
Magnetoresistance
measurements InGaAs/InP
A. Menschig. 4. Physikalisches D 7000
wires
A. Forchel.
B. Roos.
, Universitat
Institut Stuttgart
R. Germann
Stuttgart
. Federal
80
ln microstructured
Pfaffenwaldring
Republic
57
of Germany
W. Heuring Physikalisches
Institut.
Universit;it
Wiirzburg.
D 8700
Wtirzburg
D. Grutzmacher Institut
ANract.
Microstructured
ted
modulation
from
40mK.
The
about
4
and
The
compared
higher
Introd~ctlon. pers and
2D
focused to
etching, to
metal
of
of
wide
wires. level
Most
narrow In
this
paper
In,,sGa.,rAs/InP wire
definition,
low
pressure
quantum
level
wires strong we
The
the
50pm
with
decreasing only
fabrica-
fields
down
wire
very
a distinct
magnetic
were
magnetoresistance
indicating
on
to
width
only
dry
etch
small
resistance
and
maximum
Shubnikov-de-Haas
etch
is
are carrier
doped density
an electron
reduce
to
a lot
pain
transition
of
work
3D
from
has
nanostructures
been
C21 and
C41. by
the
effective
the
observation
be
of
deep
are
or
the
wire
shallow damage
width. of
ascribed
depleted
dry leads
Depleted
1D
effects
in
to
pinning
of
less
thicknesses
should
important
properties be
of
h
*
especially
than etched
20nm
steep
and
C61. in
be observed. and
widths the &
is
and
studies SOurn.
heterostructures localized
two-dimensional
= 100000
0167-9317/90/$3.500 1990, Elsevier Science Publishers B.V.
80nm
double
2DEG
at 2K in the
magnetotransport
between
In .ssGa.aTAs/InP
mobility
optical
layer
fabrication
which
significantly
the
in InGaAs
should
in
the
In particular,
layers
theoretical properties
sidewalls.
known
geometrical used,
now wires
damage.
depleted
typical
the
to
on
fabricated
allowed
etched
potential
on
Up
and
transport
inversion-layer
wires,
the
the
of
GaAs/GaAlAs
dry
pinning
experimental
concentrated
silicon
which
1D effects
with
of
dependence
CSI have
indicate
modulation
crnA2 with
number
investigations
report
wires MOVPE
well.
= 1.3 * 10”
and
finite
B10.3T.
lower
Aachen
80nm
a
width, for
at
etched
layers
1D confinement
channels
between
behaviour.
commonly
particular,
the
wire
interest
Ill,
on
at mid-gap
In,ssGa,,7As/InP
increases
quantum
150nm
in
Therefore
wires
the
wires
depleted
about
Fermi
In
of the
a large
131 or dry
In In.ssGa.47As GaAs.
show
(UCF’s)
recently
significantly
formation
Fermi
wires
dimensionality
GaAs/AlGaAs
widths
0.4pm the
of
depend
the
layer
years
the
defined
properties
widths
All
5Oirrrt
one-dimensional
small
electrostatically The
past
More
two-dimensional on
D 5100
with
magnetoresistance
fluctuations
on
systems.
published
at
Aachen.
fields. the
In
have
value
a negative
resistance
at
wires
heterostructures.
to the
show
reproducible
oscillations
RWTH
= OT. T = 40mK)
(B
wires
Halbleitertechnik.
In ,S3Ga,47As doped
resistivity
times
damage.
fur
cm’/Vs.
in
the
grown
by
a 12nm
electron
of
For
gas
InGaAs is N2D
12
A. Menschig
Sample
Z4eparation
fabricated
by
lithography used.
aM-CMS on,
resists the
has
high
some
various
between ration
80nm
Exposure resist
gas
mixture
depths On
and
at
were
advantage
that
each
microscope.
perature
measurements
the
into
magnetotransport
the
energies etch
etch
(65nm) of
gold-wire out the
experiments
C81. Compared
for
x-ray
contrast
a series 20pm
of
long
(y
we
spot
SOpm wires
>
used
sizes
of
a SOkV
accele-
1Onm
to
were with
different
the
with
with
exactly
the were field
a lock-in
the
were of to
same measured
a 80nm
with
at
perpendicular
Figure
etch
the
This
wire.
refrigerator was
ArIO spacer
has
technological
the
technique
an
well.
widths.
contact
oriented
and
quantum
different
picture
dilution
layer
InGaAs/InP
wires used
doping
25nm.
used.
. Two
the
a
wires widths
milling
11 wires
8),
long
by ion
and
through
to
with
80 $/cm’(aM-CMS)
in which
were
applicati-
SOOeV
in a He3/He4 magnetic
40nm high
exposure
250eV
an SEM
bonds
an expe-
CXM-CMS
heterostructure
of
1 shows
of
with
of
resist
of
fabricated
dimensions
with
and
pads, beam
C71.
of
beam
current
(S2nm),
a set
was
Figure
carried
40mK
electron beam
tone
contact electron
available to
a very
solutions
a series
by
developed
consists
and
(RAY-PN)
prepared
geometrical
were and
the
etched
wire
pattern
SOOpA
down
example
in aqueous
SOpm)
For
to
a deep
we
The
4K
up
a medium
meters.
surements
to
was
electron
ween
resist
(120nm
40 PC/cm*
and
sample
defined
negative
originally
for
defined
commercially
patterns
RAY-PN,
advantages:
acceleration
used:
removed, each
of
pattern
resist
of
were
sensitive,
and the
definition
beam
420nm.
20pA
doses
The
were
widths
voltage,
)
AuGe/Ni/Cr/Au
wires
an electron
no degradation
lithographically
with
the
interesting and
As
( RAY-PN
allow
electron
sensitivity
The
etching. resist
measurements
alloyed
In .s3Ga,,7As
lithography,
dry
electron
Both
Between
and measurement.
optical
and
rimental
et al. / Magnetoresistance
mainly
For
sample.
a
the
parascanning low
tem-
The
mea-
temperatures to
the
bet-
2DEG.
used.
1:
A SEM picture of a 80nm InGaAs/ InP wire fabricated
with a RAYPN
etch mask and dry etch techmque.
For
13
A. Menschig et al. I Magnetoresistance measurements Experimental results. Figure 2 depicts GaAs
wires
at
widths below ring
40mK
for
zero
the resistivity
magnetic
iurn. This is due to the influence
at the etched
temperature
sidewalls
the resistivity
4 higher than the constant
InGaAdlnP
charge
or
resistivity
depleted
(medium
value defined
Ar/o,
.
a.
T-M
active
surements are nearly Maile et al. 181.
wire
width
identical
therefore
By performing
magnetotransport of
the
electron
values
Typical
fields
2) At fields defined
should
magnetic
appear for
wire width. good
negative
region
field
from
depleted
layer
here from
resistance
mea-
in
experiments
40mK
optical
we
have investigated
curves
of
3 . Four features
magnetoresistance
a distinct
scales
decreasing
resistance amplitudes
with
a 80 nm
by
the
and a
should be menti-
usually
with cyclotron
fluctuations (universal
resistance the
magnetic
The half height position
agreement
calculated
resistance.
attributed
to
is observed.
but very irregular
3) In the same field
at
resistance
in figure
B 1 0.3 T reproduceable
periodicity
sponding
the typical
effects
20nm and the
extracted
determined
measurements gas.
190nm wire taken at 40mK are plotted oned. low
is about
layer widths
with
dimensionality
very
leads to a cut-off
width for finite
1OJ wire width I_, / n:
30nm. The values for the depleted
1) At
polation
8 -110,4
I~~~~,
weak localisation
- width dependence
wires at 40mK.
63nm
geometric01
electrical
width dependence
4.2K and 300K. A linear extra-
.
0.
52nm
ld
The
of
wires at 40mK.
of InGaAs
. .
this
2:
Conductivity
. .
At
a factor
Inset:
. .
200
wire
wire widths.
of InGaAs
.
I
L ; u
etch depth
regions.
Resistivity InGaAvlnP j60
for
by e.g. scatte-
is only about
by the larger
¶d
l
sidewall
Figure
of the In-
increases
sidewall
etch)
#80
T=4OmK
dependence
resistivity
of the wire
carrier
of a 80nm wire
- width
The
field.
wire
field,
if
which
have no
fluctuations).
maximum is obvious. The correA rise in magnetoresistance
width.
the cyclotron
and the field
diameters
appear
conductance
position
and cyclotron
diameter
reaches
of the maximum
radii positions,
the
are in
respectively,
the 2D carrier density and the measured wire widths.
4) At
higher magnetic fields typical Shubnikov-de-Haas oscillations are observed. of the quantum numbers of the The inset of figure 3 shows a usual fan diagram magnetoresistance minima plotted versus the reciprocal magnetic field. No deviation from the linear l/B dependence down to 0.8 T is found for wires wider than 310nm. But pronounced tes
the formation
deviations
are obvious
of 1D subbands
C91.
for
the smaller
wires.
The
deviation
indica-
A. Menschig et al. I Magnetoresistance measurements
14
lnGa,&/lnP
#8()
InGaAs/lnP
l
#80
. . ..****.*.3lonm
c 40_
01
6
5
I
I
1
2.5
0
I
7.5 field
rnogn~k~
10.0
[ T I
Figure 3: Two typical curves of longitudinal resistance (80nm and 190nm wire width) at 40mK are shown. The inset depicts procal magnetic
field
Ihe dependence
for different
of Landau level number over Ihe reci-
wire widths (310nm.
190nm.
150nm.
IlOnm and
80nm).
COZZC~US~OXI. We have a finite res down ductance
to 80nm. fluctuations
with large
nikov-de-Haas-oscillations surface
scattering
due
in our medium
and G. Landwehr
RAY-PN.
for
the experimental
K. Thonke state.
and K. Pressel
for
A. Benoit. C.P. Umbach. R.B. Laibowitz.
stimulating
making
assistance the help
universal
in the periodicity
ID subbands
corporation
We acknowledge
. We thank K. Grijtsch
Steinmetz
of
InGaAs/InP
we found and
of
an
their
discussions
with
available
at the
with
for providing
his analyzing
He3/He4
-
M.L. Roukes. A. Scherer. S.J. Allen,
the measurements
experimenM. Pilkuhn
cryostate
R.A. Webb; Phys. Rev. Lett. 58
H.G. Craighead.
, 2343 (1987)
T. Demel. D. Heitmann. P. Grambow. K. Ploog, Appl.
Phys. Lell. 53
B.E. Maile.
Appl. Phys. Lett. 54
R. Dammel. K.-F. D&sel. J. Lingnau. J. Theis: Microelectr. B.E. Maile.
A. Forchel.
R. Germann. A. Menschig.
Eng. 7
J.P. Harbison,
H.P. Meier; J. Vat.
G. Roos. H. van Houten: Phys. Rev. B37
2176 (1988) 1552 (1989)
. 575 (1988)
2308 (1988) K.-F. Berggren.
951 (1982)
, 1769 (1986)
R.M. Ruthen. E.D. Beebe,
R. Germann. D. Griitzmacher;
10118 (1988)
N. and
at our magnet-cryo-
, 3011 (1987)
A. Forchel.
of
program,
dilution
T.J. Thornton. D.J. Newson. M. Pepper; Phys. Rev. Lett. 57
Phys. Rev. Lett. 59
the Shub-
influence
W.J. Skocpol. L.D. Jackel. E.L. Hu. R.E Howard, L.A. Fetter; Phys. Rev. Lett. 49 K.-F. Berggren.
wicon-
transport.
We thank the Hoechst
system
changes
formation field
deep etched
measurements
amplitudes, to
on low magnetic
A&owledgement. tal resist
resistance
In the magnetotransport
Sci. Technol.
B6