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Reliability of InGaAsInP based separate absorption grading multiplication avalanche photodiodes
(~)
Microelectron. Reliab., Vol. 36, No. 7/8, pp. 973-1000, 1996 Copyright © 1996 Elsevier Science Ltd Printed in Great Britain. All rights reserved 0026-2714/96 $15.00+.00
Pergamon
PII :S0026-2714(96)00026-1
REVIEW PAPER RELIABILITY OF InGaAs/InP BASED SEPARATE ABSORPTION GRADING MULTIPLICATION AVALANCHE PHOTODIODES P. MONTANGERO, G.A. AZZINI, H.C. NEITZERT, G. RICCI AND L. SERRA Centro Studi e Laboratori Telecomunicazioni (CSELT), via (3. Reiss Romoli, 274, 10148 ~ Torino, Italy
Abstract An overview over typical defects and reliability aspects regarding the operation of InGaAs/InP avalanche photodiodes for the use in fiberoptic communication systems is given. Measurements
regarding the performance
types of top
illuminated
and stability of different
InGaAs/InP Separate
Absorption
Grading
Multiplication avalanche photodiodes have been compared with special emphasis on the homogeneity of the photoresponse. High resolution scanning optical microscopy measurements allowed
to
misalignment
identify
specific
resulting
in
at different wavelengths
technological
increased
problems.
responsivity
of
Guard the
ring
junction
perimeter have been found on devices from one manufacturer. The responsivity images of the active area of some of the investigated photodiodes showed sharp peaks due to microplasma formation. The impact of these microplasmas on dark current and photocurrent of the devicea has been investigated in detail. A step-stress test performed at successively increasing temperatures resulted in the catastrophic failure of the tested devices from one family. An analysis of the dark current-voltage characteristics before and after degradation leads to the conclusion that a modification of the semiconductor-insulator
interface
properties
caused
a
dramatic
increase in the surface leakage currents. Copyright © 1996 Elsevier Science Ltd
Introduction
Avalanche photodiodes (APDs) are widely used as receivers in long distance fiber-optic communication systems. APDs have, compared to 973
974
P. Montangero et al.
the
conventional
pin
photodiodes,
the
advantage
of
inherent
photocurrent gain in the multiplication regime of the current-voltage characteristics
and
better
noise
performance
bandwidths. The wavelengths around wavelengths
of
communication.
highest
interest
A wavelength
at
high
modulation
1300rim and 1550nm are the for
around
long
distance
1300nm
fiber-optic
corresponds
to
the
absolute dispersion minimum and a relative absorption minimum of a standard
silica fiber,
while the wavelength
region
around
1550nm
corresponds to the absolute absorption minimum of a standard fiber and in the case of a dispersion-shiftet fiber - also to the dispersion minimum. For this wavelength range photodiodes are most commonly made from Ge or from
InP based ternary (InGaAs) and quaternary
(InGaAsP) compounds. It should be mentioned that also HgCdTe has been investigated for this wavelength range [1]. The
InGaAs/InP
material
system
has
for
photodetector
applications several advantages in the long wavelength range compared to Ge, like a better noise figure [2], lower dark current [3] and a high quantum efficiency in a broad wavelength range (1.0-1.6~m) [4]. It has also a better performance than Ge regarding the temperature stability of the dark current and the noise figure [5], making it very attractive for
operation
in
uncontrolled
environments
where
the
ambient
temperature is varying in a wide range. While it was initially thought to be difficult to obtain
high multiplication factors
in the
InGaAs/InP
system [6], state-of-the-art devices achieve rather high photocurrent multiplication values [7]. For the
prediction
of the
reliability of optical
communication
systems, the investigation of the degradation mechanisms of avalanche photodetectors as one of the key components is crucial. The main device parameter change observed during accelerated stress tests at elevated operating
temperatures
performed
on
InGaAs
pin
diodes
without
multiplication was a substantial increase in the dark current [8,9]. The dark current increase has been reported to be induced either by the degradation of the surface passivation layer [6] or by the formation of premature breakdown regions at the perimeter of the active area of the photodiode
[10].
For a comprehensive
study
of the
dark
current
mechanisms in pin-diodes the reader is referred to Ref. [11]. In addition to the former mentioned degradation mechanism, which
Multiplication avalanche photodiodes
975
is common for pin-diodes with and without photocarrier multiplication, the performance of avalanche photodiodes is additionally limited by the existence of small spots within the active region of the device, where the breakdown voltage is significantly lowered in comparison to the surrounding area [12,13]. This type of defect, which has been referred to as "microplasma," is already described in the very early literature about silicon pn-diodes [14,15,16]. Besides degrading the homogeneity of
the
photoresponse
of
the
avalanche
photodiode,
microplasma
formation is as well one of the reasons for an increase in the electrical noise of the APDs [15,17]. It corresponds to a local increase in the electric field
in the
multiplication
layer of the avalanche diode. In
particular the correlation between the microplasma density and the density
of
dislocations
in
the
semiconductor
layers
has
been
investigated. For InGaAs APDs some authors find approximately the same microplasma and dislocation density [18,19]. Others report for GaAs on Si [20], Si [21] and InGaAs [22] APDs that the microplasma density is orders of magnitude lower than the dislocation density. In t h e latter case it has been argued that only the decorated dislocations create
electrically
active
defect
sites
or
that
other
crystal
imperfections may be responsible for the microplasma formation [23]. It has been proposed that the dislocations cause a local enhancement of the
dopant
concentration
which
increases
the
electric
field
and
therefore leads to a local decrease of the avalanche breakdown voltage [18]. Local changes in the electric field strength in the multiplication layer can also be due to variations in the layer thicknesses or doping instabilities
[23],
The degradation of the metallic contacts [24] is another problem, which limits the long term stability of InGaAs avalanche photodiodes. Similar problems are already known for Ge APDs, where for example fast AI diffusion has been observed [25]. Here we will focus more on problems that are relevant in the normal temperature operating range of the avalanche photodetectors. Recently in some laboratories other types of InGaAs/InP APDs, which are - to our knowledge - not yet commercially available, have been realized. For example a charge layer has been inserted into the
976
P. Montangero
et al.
SAGM structure and the resulting SAGCM InGaAs high modulation 100GHz
based APDs exhibited
speed with a gain-bandwidth product higher than
[26] and low noise operation [5]. The substitution of the
homogeneous
multiplication
region by superlattice
[27] and multi-
quantum-well [28] structures enables the operation of these detectors in
the
single-carrier-initiated,
single-carrier-multiplication
mode.
This results in very low excess noise and allows for the operation of the device in the regime with high photocarrier multiplication [29], resulting
in elevated gain-bandwidth products.
Staircase APDs, as
proposed for operation at rather low applied voltages [30] have recently been realized using the GaAs/AIGaAs [31] and the InAIGaAs material systems [32]. To our knowledge reliability data on this kind of advanced structures is not yet available. In the present study we will give a short introduction to the electro-optical
characteristics
of
InGaAs/InP
Separate
Absorption
Grading Multiplication (SAGM)APDs, showing the results obtained on devices of four different manufacturers. Then we will demonstrate the existence of some of the above mentioned defects and more in detail study the microplasma formation and other inhomogeneities in the photoresponse. Additionally the degradation of these devices during a bias step-stress test at increasing temperatures has been monitored and the performances before and after degradation will be discussed. The physical mechanisms leading to the failure of some devices during this step-stress test will be discussed.
Experimental A)
Device Structures
In this work we report measurements families
of
commercially
available
performed avalanche
on four different photodiodes
from
different manufacturers. All the four APD families (labelled A,B,C,D), whose
schematical
cross
sections
are
given
in
Fig.l,
are
top
illuminated Separate Absorption Grading Multiplication (SAGM) APDs. They are specified to conform with the requirements of fiber-optic communication systems. I-or a description of the different types of InP based APDs the reader is referred to [33].
#C
n - kiGa,~P
n - kiP
n" - InP
#A
Fig.1
_~/tl
SHALLOW - O R
SI Nx (PASSIVATION)
/ IJi
#D
GRADED LAYER /
p - ELECTRODE (TI/Pt/Au)
SiN
k
.
n - Inp
n" InGmAi
I CONTACT
Separate Absorption Grading Multiplication InGaAs/InP APDs
PASSIVATICN
n " - kip
Si IMPLANT
n+ kiP (SUBSTRATE)
CONTACT
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1
InP Substrale
n - InGa~
n - InGaAsp
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Schematic cross section of the four different families of
I
n - ELECTRODE
n + - ~ P SUB.
n - I n P BUFFER
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1__ ,.~..ACE
p - ELECTRODE
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p+ - REGION
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n - InP
n" InGaAs
n" ktGaAsP
n - InP
p - ELECTRODE
0 0
g
E
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F,"
m-
978
P. Montangero et aL
More than 12 APDs from each manufacturer have been characterized and most results reported here give an idea of the typical behaviour of the devices from each family. The insertion of an InGaAsP grading layer between the InGaAs absorption layer and the InP multiplication layer reduces the hole pileup at the valence band discontinuity and enables therefore the operation at higher modulation frequencies [34]. The active area of the device B is about 801.tin wide while for devices A,C and D it is 50gm wide and they are all illuminated from the top. The main differences between the investigated APD families is the definition of the lateral confinement and the guard ring structure. The photodetectors from the family A exhibit a very simple structure with only one guard-ring and with a multiplication layer defined by the p+ diffusion in the n--InP. The guard ring is created by ion implantation. In the family B the multiplication region is defined by a n-lnP mesa buried into the n--InP layers and a guard ring at the junction edges [35]. Devices C have two guard rings with a PLEG structure (Preferential Lateral Extended Guard-ring) [4]. For the
APDs from family D the multiplication area is obtained by
silicon implantation and not by the growth of a suitably doped layer as in the
other
implanted
structures
[36];
the
p+
region is larger than the Si
area in order to prevent edge breakdown at the curved
junction. This solution is alternative to the guard-ring implementation.
B)
Measurements techniaues
Dark current voltage (IV) characteristics of the avalanche photodiodes have
been
measured
different temperatures. illumination intensities
with (about
a
with
a semiconductor
parameter
analyzer at
The photocurrent has been measured laser
diode
at
100nW),
using
a
1550nm lock-in
at
low
technique
under
illumination with
a low
frequency modulation (f=4kHz) of the light source. To avoid casual results due to inhomogeneities of the photoresponse, the laser spot has been defocused to cover about 80% of the active photodiodes area. In the case of the characterization of a microplasma site, the incident light beam has been focused to the relevant part of the APD with a spot diameter of about l~m. In this latter case much lower light intensities (between 0.3nW and 8nW) have been used for characterization.
Multiplication avalanche photodiodes
979
High resolution imaging of the photoresponse of the APDs has been clone at different wavelengths and at different applied bias voltages using a scanning wavelengths
optical microscope
(SOM).
846nm, 880nm and 1320nm
Laser diodes at the
have been used as light
sources. Light with a wavelength of 1320nm is mainly absorbed in the InGaAs layer and probes therefore the photoelectric properties of the APDs under normal operation. Light at wavelengths of 846nm or 880nm is mainly absorbed in the upper InP layer and is used in this study for diagnostic
purposes.
responsivity
The
mapping,
light power
will
be
given
densities in the
(Io), used for the
figure
captions.
The
measurement setup has been described in detail elsewhere [37,38].
Results
A)
and
Discussion
Dark and photocurrent voltage characteristics before dearadation
A comparison
of the
current-voltage
(IV)
characteristics
at room
temperature of the four families of APDs is shown in Fig.2.
All diodes
exhibit at low applied bias voltages rather low dark current (Id) values,
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D #
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Fig.2
J
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=
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-50 VOLTAGE (V)
,
,
10-10
10-12
,
-100
-50 VOLTAG E (V)
- 1O0
Reverse IV characteristic, measured at 20°C without and with illumination at 1550nm for the four different APD types
P. Montangero et at.
980
which rapidly increase when the voltage reaches a threshold value. This threshold
corresponds
to the
punch-through
depletion
zone extends down to the
voltage,
InGaAs/InP
at which
interface.
the
Type
B
exhibits additionally a second rise of the dark current at about 23V. Also type D shows a small second increase of the dark current (in this case at about 28V ). The reverse dark current (Id) in this kind of APDs is mainly dominated (g-r)
current,
by two contributions:
which
interface defects,
increases
with
and additionally
the generation-recombination
increasing
by surface
density
of bulk and
leakage currents. The
leakage current at the surface can often be distinguished from bulk current contributions, because it is in general not multiplied at higher bias voltages. For APD families D and B only, the growth of the InP multiplication and
the
layer has been interrupted for the silicon
definition
of the
mesa
structure
respectively.
implantation The
rapid
increase of Id for a threshold value of the bias voltage above the punchthrough voltage, which is only present for this two families of APDs, may therefore be explained by an increased number of defect states at this internal interface and hence a rapid increase of the g-r current, when the depletion zone extends down to this region. An alternative interpretation of this rapid current increase for devices of family B and D could be the existence of two different punch-through voltages in the center of the device and in the outside region due to lateral dopant variation in these APD families [5]. Some diodes from the APDs of family A show at a reverse bias voltage of around 30V a significative
increase in the slope of the
current-voltage
clearly
characteristics.
More
than
for
the
diode
presented in Fig.2, this is observed in the characteristics of another APD presented
in Fig.14. The effect might be due to an onset of
tunnelling breakdown before the onset of avalanche breakdown at 63V, which degrades the photodetector performance of this device. For the device of the family C a plateau-like feature in the dark current just before the beginning of the avalanche multiplication has been observed. In the following
the avalanche
breakdown
voltage
(Vb)will
be
defined as the voltage where the reverse dark current equals 100~A. This breakdown occurs at room temperature in a range between 60V and 75V for families A,B and C, whereas the type D APDs exhibit higher breakdown voltages between 82V and 88V. The onset of breakdown is
Multiplication
avalanche
981
photodiodes
sharp for family C and more gradual in the case of family A, B and D. A reason for a more gradual increase may be either the early onset of tunneling breakdown or microplasma formation. The latter effect will be
looked
at
in more
detail
by high
resolution
mapping
of the
responsivity of the APDs in the next chapter. The comparison of the IV characteristics of the four families under illumination is also shown in Fig.2. The light intensities have in this case been chosen to give the same diode current of 100nA for all APDs at
the
punch-through
voltage.
In
the
photocurrent-voltage
characteristics of all four APD types one can clearly see the onset of charge
carrier
multiplication.
In Fig.3 the photocurrent (Iph), determined by lock-in technique has been plotted as a function of the applied bias voltage. Iph is almost negligible at low bias voltages and increases sharply at the punch through
voltage.
photocurrent
Increasing
starts
to
the
rise
bias
again.
voltage
This
is
still the
further, onset
the
of
the
multiplication regime, which is the voltage range where the APD is actually operated. All four APD types exhibit appreciable photocurrent gain. Under the assumption that the photocurrent value at the beginning
10-4
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10-4
#A
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,
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10-6 uJ
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10-10
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0-
1` 1` t,
10-12 0
10-12
-100
-5O
VOLTAGE (V)
10-4
~" z ILl E
n"
G.
10-8
J~
•••
,
,
i
i
,
,
,
_~#D
#C
I - 10-6 Z LU
i
-50 VOLTAGE (V)
10-4 i i
¢~
,
0
10-6
-100
~ 5 lO-8
10-10 n
1
.5
10-10
1`1` 10-12 0
Fig.3
,
i
i
i i , ~ , -50 VOLTAGE (V)
i
i
10-12 -100
i
i
i
i
i
i
-50 VOLTAGE(V)
=
i
~ i
-I00
Inverse of the multiplication factor and photocurrent as a function of the reverse bias voltage measured at 20°C under illumination at 1550nm for the four different APD types
982
P. Montangeroet
al.
of the plateau equals a photocurrent multiplication factor (M) of 1, in Fig.3 the inverse of the multiplication factor has been plotted as well in function of the applied bias voltage. An alternative definition for the breakdown voltage is given as the voltage where M approaches infinity. This can be obtained by the extrapolation of the dependence of 1/M vs. bias voltage to l/M=0. For device A this gives a breakdown voltage of 65V, for device B of 68.5V and for device C of 66V. An analytical expression, which is in good agreement with the presented results for all four devices, has been given in literature for the voltage dependence of M [39]. M-
I_(V-R,It/p (1)
where p is a constant with typical values between 1 and 2, Vb is the breakdown voltage, Rs the series resistance of the APD and It the total multiplied current
current.
For even higher applied
of all four APD types
is again
bias voltages
dominated
the total
by the sharply
increasing dark current. In Fig.4 the temperature dependence of the dark current-voltage curve of a SAGM APD in the temperature range between 20°C and 100°C is shown for a device
of the family
B. Basically two temperature
lO-4
,o-71 I 10-11~ 10-121" 0 Fig.4
~
~
,
~
I , -50 VOLTAGE(V)
~
f
J -100
Reverse dark IV characteristic, measured at different temperatures between 20°C and 100°C (in steps of 10°C) for an APD from family B
Multiplication avalanche photodiodes
983
dependent changes have been observed. The avalanche breakdown voltage and the dark current are both increasing while increasing the operating temperature. The first effect is indeed a check that the breakdown mechanism is due to avalanche multiplication, because the alternative breakdown mechanism - i.e. tunnelling breakdown - shows the inverse temperature dependence [40]. In all four cases, Vb increases linearly with increasing temperature, following Eq.(2):
(2)
Vb(T)=Vb(To)(I+~(T-To))
with
positive temperature
coefficients
(p)
between
1.42.10"3°C "1
(family B) and 2.32.10"3°C "1 (family D). We took 273K as the reference temperature [7].
Also
(To). Similar values of I~ have been reported in literature the
generation-recombination
current
increases
with
increasing temperature. This effect causes the monotonic dark current increase with an increase in measurement temperature
below the
breakdown voltage regime. In general an activation energy (Ea)for the current in this regime can be defined and the change of dark current activation energy during an accelerated life test will be discussed in the last chapter.
B) Imaging of the resDonsivitv
For more than 12 samples each of all four types of APDs, high resolution
responsivity
images
have
been
taken
at
different
wavelengths and with different intensities of the probing light, varying in a wide range the applied bias voltages. Here we show in the beginning first
some
responsivity
images
of
APDs
with
a
homogeneous
photoresponse, followed with images of APDs, which display different kinds
of local
defects that have already been mentioned
in the
introduction. Most of the responsivity images presented here have been taken with applied bias voltages in the operating range of the APD, close to the avalanche breakdown regime. Typical photocurrent multiplication values in this regime range between 20 and 30. Local maxima in the photocurrent gain due to microplasma breakdown have been observed in all
investigated
APD
families,
but
with
very
different
rates
of
984
P. Montangero et al.
occurence. Microplasma breakdown has been observed for only one device out of 14 APDs from family B while almost every device from family D exhibited these type of defect. Also for APDs from family A microplasma breakdown has been frequently observed. APDs
of family
C showed
in general
a very homogeneous
photoresponse at all measured wavelengths. This is for example shown in Fig.5, where the responsivity image of an APD of the family C measured
at
62V
with
an
excitation
wavelength
of
1320nm
is
presented. At this wavelength, which is as well one of the wavelengths of interest for the application of the APD, the light is absorbed in the InGaAs layer and one gets information about the bulk properties of the photodiodes.
In order to get more detailed information
about the
homogeneity of the junction edge and guard ring region we mapped the same device at a wavelength of 880nm. It has been suggested in literature to use this probing wavelength for the investigated type of APDs in order to check for irregularities situated in the InP layer near the surface [41]. The result is shown in Fig.6. At this wavelength the photoresponse from the guard ring region is observed as well, which manifests itself in the ring with increased photoresponse surrounding the active diode region. In this case the photoresponse in the active region and also in the region of the guard ring is homogeneous.
Fig.5
Image of the responsivity of an APD of the family C, measured at 1320nm, Vbias=62V, Io=5W/cm2
Multiplication avalanche photodiodes
Fig.6
985
Image of the responsivity of an APD of the family C, measured at 880nm, Vbias=62V, Io=15W/cm 2
The
characterization
of an APD with a local
photoresponse
irregularity in the guard ring region is shown in Fig.7. In this case an APD of family A has been mapped at 880nm with an applied reverse bias voltage of 40V, well below the avalanche breakdown regime. A sharp
Fig.7
Image of the responsivity of an APD of the family A, measured at 880nm, Vbias=40V, Io=15W/cm2
P. Montangero et al.
986
peak in the photoresponse situated on the guard ring can be observed. Devices with such irregularities have a high failure probability, when operated in the multiplication regime [41]. Another common problem in this
APD
family
was
mask
misalignment
during
processing.
To
illustrate this problem, in Fig.8 photoresponse images of another APD from family A, which have been taken at different wavelengths and bias voltages are shown. In this case the photoresponse maps are displayed in a manner, that bright areas on the plot correspond to areas of high photocurrent. The black areas within the bright lines correspond to the metallization. The photoresponse map taken at 880nm with 0V applied bias (Fig.8 A) reveals the misalignment of the active area of the photodiode
with
respect
to
the
surrounding
metallization.
The
responsivity map of this APD, measured at an applied bias voltage of 62V (Fig.8 B) exhibits clearly an enhanced response at two points near the metallization outside of the active area. To enable an easier identification of this areas of punctual higher photoresponse with respect to the geometry of the device, in Fig.8C both maps at 880nm and 1320nm (Fig.8A and Fig.8B) are superimposed. A sharp local irregularity in the photoresponse due to microplasma breakdown is evidenced in Fig.9 for a device from family A biased at 65V. In this case the probing wavelength was 846nm, which is strongly absorbed in the top InP layers, including the multiplication layer. Also the overall homogeneity of the photoresponse of this device in the other parts of the active region is rather poor. Increasing only slightly the applied bias voltage, the responsivity map changes completely. This is seen in Fig.10, where the same APD as in Fig.9 has been mapped, but applying a bias voltage of 66V. Now the photoresponse is still quite inhomogeneous, microplasma,
but the
evidenced
sharp in
enhancement
Fig.9 cannot
at the
be seen
site
of the
anymore.
This
illustrates an often mentioned property of microplasma breakdown, which is limitation of the photocurrent due to the creation of a space charge induced by the high local current itself [16]. Increasing the bias voltage further to a value slightly below breakdown, even a reduced photoresponse may be observed on the microplasma site.
It may
therefore be possible that the APD presented in Fig.9 and Fig.10 contains other microplasmas, which
become visible at other bias
voltages. Consequently in the presence of microplasmas it is not
Multiplication avalanche photodiodes
997
P. Montangero et al.
988
i Fig.9
Image of the responsivity of an APD of the family A, measured at 846nm, Vbias=65V, Io=20W/cm 2
Fig.10 Responsivity image of an APD of the family A, measured at 846nm, Vbias=66V, Io=20W/cm 2
Fig.8
Image of the responsivity of an APD of the family A, measured at different wavelengths A) 880nm, Vbias=0V, Io=15W/cm2 B)
1320nm, Vbias=62V, Io=5W/cm 2
C) Superimposed image of A) and B) Bright areas correspond to high photocurrents values.
Multiplication avalanche photodiodes
989
Fig.11 Image of the responsivity of an APD of the family D, measured at 1320nm, Vbias=77V, Io--5W/cm2 sufficient to characterize the homogeneity of an APD only at one value of the bias voltage. The responsivity of almost all the APDs from family D suffered from a unique type of inhomogeneity, which is reported in Fig.11. The photoresponse appears as a series of parallel stripes separated by lower responsivity zones. It should be noted that the same stripes have been observed in the surface morphology of the device, taken with the scanning optical microscope in the differential phase contrast mode. For more details the reader is referred to [42]. Most probably growth i n h o m o g e n e i t i e s or problems related to the substrate surface induce this anomalous behaviour. The local behaviour of the photocurrent-voltage characteristics of the above characterized APD from family D is shown in Fig.12 measured in
two
different
points,
at
the
site
of
a
microplasma
comparison, in the center of the active area. The
local
and,
for
breakdown
voltage - estimated by the linear extrapolation of the I/M curve - is about 10V lower at the microplasma site than in the center of the active area. C)
Temperature
ste~)-stress
Two APDs of each family have been stressed at a constant voltage and at successively increasing temperatures. For the applied bias voltage
990
P. Montangero et al. 10-4 10-5
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;,
#B
~'~
~1
1
,p,/oeo'erl - - ~ , ~ - ~ - - ~ ' ~
Iph (max)
10-11
-50
-100
VOLTAGE (V) Fig.12 Photocurrent (Iph) and I/M as a function of the reverse bias voltage measured at 20°C under illumination within (max) and outside (center) of the microplasma region for an APD of the family D. The incident light intensities were about 8nW for the measurement in the center and 0.3nW for the measurements on the microplasma site.
during this step-stress test a value of 90% of the breakdown voltage at the respective temperature has been chosen. This is a value close to the operating
range of the APDs. The step-stress has been performed at
temperatures increasing first from 40°C to 80°C and then in steps of 20°C
up to
a temperature
of
200°C.
After
150
hours
at
each
temperature the devices have been first cooled down to 20°C.
A
current-voltage characteristic has been taken at that temperature and successively the temperature has been increased temperature. intended
The
elevated
only to accelerate
temperatures
to the next higher
during
the degradation
step-stress
processes,
which
are are
already present at operating temperatures, and have therefore been limited to 200°C in order to avoid the creation of new degradation mechanisms, like the above mentioned contact degradation. In Fig.13 the current values at 20°C (named 190), determined after each stress temperature for a voltage, corresponding to 90% of the breakdown voltage of the respective APD, have been plotted as function o! the stressing time for two APDs each from the four different families. The two devices from family D failed at 140°C and 180°C respectively,
while the other three APD types showed only minor
Multiplication avalanche pholodiodes
temperature
991
(°C)
40 80 100 l zo 140 160 180 zoo
10 -4
,o
10 "s
=
10 6
•
A1
t.
A2
•
C1 C2
B1
0
DI
B2
•
D2
7^
10"z o
--=
I 0 "B 1 0 "9
10-1o 0
300
600
900
1200
time (h) Fig.13 Monitoring of the dark current, measured at 90% of the breakdown voltage (190) of the four different families of APDs
at 20°C
after different steps of a temperature
step-stress test at increasing temperatures
(40°C-200°C)
variations in the dark current. The curves for the two APD's from family B showed slight variations in the - rather low - dark current, which were very similar for both devices. In Fig.14 the dark current-voltage curves for one
device from each
10-4
10-4
#A1
#B1
A 10-6
.- 10-6
w II n-
=3, (,3
10-8
10-8
~ 10-1C
10"10
10-12 =
10-12
/
-50
-50
- 100
VOLTAGE (V)
10-4
A 10-6
w 10°8
o r¢
10-4
10-12
.
•
#C1 I-Z uJ cE
.--
#D1
10-6
10-8 (3 Y n.-
J
~ 10-10
- 100
V O L T A G E (V)
~ 10-10 .
0
.
.
, -50
.
.
VOLTAG E (V)
.
.
10-12 - 100
-50
-100
V O L T A G E (V)
Fig.14 Reverse dark IV characteristic, measured at 20°C for the four different APD types before and after temperature step-stress test
992
P. Montangero et al.
APD family, measured before and after step-stress test, are shown. The APD A1 shows a slight increase in the dark current in the whole measured voltage range, but no shift of the breakdown voltage. The kink, seen at 30V in the IV curve before aging test, is less pronounced after the step-stress test. The IV-characteristics of device B1 did not show measureable
changes.
For device C1 a slight increase of the dark
current at low bias voltages and a slight decrease near the avalanche breakdown breakdown
are
observed
voltage.
characteristics
in
After
addition the
to
step
a slight
stress
just below the breakdown
increase
test
the
regime (between
of the
dark
IV-
50V and
62V) shows a plateau like behaviour. The most dramatic changes - as already seen in Fig.13 - are found for the APDs of family D. Here an overall increase in the dark current of almost two orders of magnitude and additionally a significant decrease in Vb is found, as displayed for APD
D1 in Fig.14.
The step in the dark current
observed
before
degradation at 12V applied bias voltage cannot be seen anymore after degradation. The parameter changes of the APDs from family D - which failed during temperature step-stress at 140°C (D2), resp. at 180°C (D1) will be discussed more in detail. For this purpose the dark current has been measured as a function of the measurement temperature. By plotting the logarithm of the dark current, at the voltage where M=I and at 90% of the breakdown voltage,
1 2
'
'
I
'
'
'
I
'
'
'
r
'
'
'
I
'
after 10
- -~- ~ ,,
u
'
I
'
'
'
I
'
'
'
degradation I E =0.26eV a
m
"-"
'
-.
4
before
degradation
-o
C
2 0
E,=O.47eV ,
, , ,
30
I,
32
,,
I
34
t
i
i
I i I
36
I I =
I I I
38
'
40
,
,
J'
42
' '
44
1/kT (ev "1) Fig.15 Arrhenius-plot and resulting values of the activation energies of the reverse dark current at 90% of Vb for device D1 measured at 20°C before (open circles) and after (closed circles) step-stress
test
Multiplication avalanche photodiodes
993
Versus 1/kT, a single activation energy (Ea) has been found in the investigated temperature
range before and after step-stress. This is
shown in Fig.15 for the current vs. temperature dependence of device D1 for an applied voltage of 90% of Vb. In order to distinguish between the bulk clark current (Ibulk) and the surface dark current (Isurface), the dark current has been plotted as a function of the multiplication factor M. The result is shown in Fig.16 for the Diode D1 before and after stepstress. Now it has been assumed, following [4,43] that the surface dark current is not multiplied, so that for the total dark current (Id(tot))
results: (3)
Id(tot)=lsurface + M'lbulk
6 10"3 A
3 10 -3 O
2 10 .3 m "O
1 10.3
/
o o
O
D1
0 100
after
degradation
I
I
I
I
10
20
30
40
I
1
50
M
2 10"4
I
I
1 10 .4 O 0 0= "O
D1 before
0 10o 0
degradation
I
I
I
I
10
20
30
40
50
M
Fig.16 Reverse dark current as a function of M for device D1, measured at 20°C before (closed circles circles) and after step-stress test (open circles). The results of a linear fit to the data for high M values are displayed as well.
994
P. Montangero Table 1
et al.
Bulk and surface dark current values and dark current activation energies (Ea) at the voltage, where M=I and at 90% of the breakdown voltage for the two APDs from family D before and after temperature step-stress test
Isurface (A) Ibu~ (A) Ea (M=I) (eV) Ea (0.9*Vb) (eV)
I D2 (Ere stress)) 9.75 e-8 1.60e- 10 0.49 0.46
The linear extrapolation multiplication
D2 (post stress) 6.27e-6 4.96e-8 0.29 0.28
D1 (pre stress) 8.15e-8 2.20e-9 0.51 0.47
D1 (post stress) 4.33e-6 3.59e-8 0.26 0.26
of the dark current in the regime of high
values to M=0 (Fig.16) gives in this way the Isurface
value and the slope of the linear extrapolation the Ibulk contribution in the voltage regime where M is rapidly increasing. Table 1 summarizes the activation energies and bulk and surface dark current values for the two devices from family D before and after the step-stress test. The bulk dark current as well as the surface dark current contributions of D1 and D2 increase during the bias step-stress by 1-2 orders of magnitude. The activation energies of the dark current at both investigated bias voltages decrease roughly by a factor of two from 0.46-0.52eV before aging to 0.26-0.28eV after aging. Commonly
for
the
generation-recombination
current
a
dark
current activation energy of about half the bandgap is found [37]. This would give a value of about 0.37eV in the InGaAs layer and of about 0.67eV in the InP. The values of Ea before bias step-stress are in between
this two values
expected for the generation-recombination
currents originating from the InGaAs and InP layers. After degradation, however, the activation energy is close to the values of 0.20eV and 0.25eV, which have been reported in literature for the activation energy of surface
dark
currents
dominating
Id
after degradation
of APDs
[32,44]. From the dependence of Id on M we can state that surface as well as bulk contributions increase
during
significant
to the dark current of the investigated
degradation
decrease
in the
of
the
activation
devices energy
from
family
of the
dark
D.
APDs The
current,
however, indicates that the surface current contribution dominates the dark current after degradation. In the literature the most cited reason for the
dark
current
increase
under similar stress conditions
is a
Multiplication avalanche photodiodes
995
degradation of the passivating layer [24,44,45,46]. As possible reasons hot hole injection and trapping [24,45] and mobile charge buildup in the insulator [46] have been proposed. In another work the contribution of avalanche breakdown at the surface of the guard-ring junction formed in the InP cap layer has been found responsible for a surface current increase [41]. It is interesting to note that in this latter case this local enhancement
of the
surface
current
increases
other than
our
assumption made above - with increasing dark current multiplication values. In another study about the degradation of
InGaAs/InP APDs, the
degradation due to premature edge breakdown was reversible and could be baked out at 200°C, while the increase of the surface current due to charge trapping in the passivating layer was permanent [42]. This, however, is known to be partially recovered by a removal of the passivating layer by chemical etching [45].
Conclusions
Four different families of InGaAs/InP Separate Absorption Grading Multiplication avalanche photodiodes have been characterized by high resolution photoresponse imaging with a scanning optical microscope and by dark and photocurrent measurements. Different highly local features in the photoresponse like edge breakdown and microplasma formation have been observed on some devices. Another typical problem for one of the device families was a mask misalignment during processing, resulting also in an anomalous photoresponse at the diode perimeter. During a step-stress test at increasing temperatures up to 200°C the devices from only one APD family failed. The photoresponse of these latter devices, which failed at temperatures between 140°C and 180°C, exhibited already before degradation a highly non-uniform behaviour with microplasma formation
along parallel stripes. After the step-
stress a dramatic increase of the surface dark current of this failed devices has been observed.
996
P. Montangero et al.
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Microelectron. Reliab., Vol. 36, No. 7/8, pp. 973-1000, 1996 Copyright © 1996 Elsevier Science Ltd Printed in Great Britain. All rights reserved 0026-2714/96 $15.00+.00
Pergamon
PII :S0026-2714(96)00026-1
REVIEW PAPER RELIABILITY OF InGaAs/InP BASED SEPARATE ABSORPTION GRADING MULTIPLICATION AVALANCHE PHOTODIODES P. MONTANGERO, G.A. AZZINI, H.C. NEITZERT, G. RICCI AND L. SERRA Centro Studi e Laboratori Telecomunicazioni (CSELT), via (3. Reiss Romoli, 274, 10148 ~ Torino, Italy
Abstract An overview over typical defects and reliability aspects regarding the operation of InGaAs/InP avalanche photodiodes for the use in fiberoptic communication systems is given. Measurements
regarding the performance
types of top
illuminated
and stability of different
InGaAs/InP Separate
Absorption
Grading
Multiplication avalanche photodiodes have been compared with special emphasis on the homogeneity of the photoresponse. High resolution scanning optical microscopy measurements allowed
to
misalignment
identify
specific
resulting
in
at different wavelengths
technological
increased
problems.
responsivity
of
Guard the
ring
junction
perimeter have been found on devices from one manufacturer. The responsivity images of the active area of some of the investigated photodiodes showed sharp peaks due to microplasma formation. The impact of these microplasmas on dark current and photocurrent of the devicea has been investigated in detail. A step-stress test performed at successively increasing temperatures resulted in the catastrophic failure of the tested devices from one family. An analysis of the dark current-voltage characteristics before and after degradation leads to the conclusion that a modification of the semiconductor-insulator
interface
properties
caused
a
dramatic
increase in the surface leakage currents. Copyright © 1996 Elsevier Science Ltd
Introduction
Avalanche photodiodes (APDs) are widely used as receivers in long distance fiber-optic communication systems. APDs have, compared to 973
974
P. Montangero et al.
the
conventional
pin
photodiodes,
the
advantage
of
inherent
photocurrent gain in the multiplication regime of the current-voltage characteristics
and
better
noise
performance
bandwidths. The wavelengths around wavelengths
of
communication.
highest
interest
A wavelength
at
high
modulation
1300rim and 1550nm are the for
around
long
distance
1300nm
fiber-optic
corresponds
to
the
absolute dispersion minimum and a relative absorption minimum of a standard
silica fiber,
while the wavelength
region
around
1550nm
corresponds to the absolute absorption minimum of a standard fiber and in the case of a dispersion-shiftet fiber - also to the dispersion minimum. For this wavelength range photodiodes are most commonly made from Ge or from
InP based ternary (InGaAs) and quaternary
(InGaAsP) compounds. It should be mentioned that also HgCdTe has been investigated for this wavelength range [1]. The
InGaAs/InP
material
system
has
for
photodetector
applications several advantages in the long wavelength range compared to Ge, like a better noise figure [2], lower dark current [3] and a high quantum efficiency in a broad wavelength range (1.0-1.6~m) [4]. It has also a better performance than Ge regarding the temperature stability of the dark current and the noise figure [5], making it very attractive for
operation
in
uncontrolled
environments
where
the
ambient
temperature is varying in a wide range. While it was initially thought to be difficult to obtain
high multiplication factors
in the
InGaAs/InP
system [6], state-of-the-art devices achieve rather high photocurrent multiplication values [7]. For the
prediction
of the
reliability of optical
communication
systems, the investigation of the degradation mechanisms of avalanche photodetectors as one of the key components is crucial. The main device parameter change observed during accelerated stress tests at elevated operating
temperatures
performed
on
InGaAs
pin
diodes
without
multiplication was a substantial increase in the dark current [8,9]. The dark current increase has been reported to be induced either by the degradation of the surface passivation layer [6] or by the formation of premature breakdown regions at the perimeter of the active area of the photodiode
[10].
For a comprehensive
study
of the
dark
current
mechanisms in pin-diodes the reader is referred to Ref. [11]. In addition to the former mentioned degradation mechanism, which
Multiplication avalanche photodiodes
975
is common for pin-diodes with and without photocarrier multiplication, the performance of avalanche photodiodes is additionally limited by the existence of small spots within the active region of the device, where the breakdown voltage is significantly lowered in comparison to the surrounding area [12,13]. This type of defect, which has been referred to as "microplasma," is already described in the very early literature about silicon pn-diodes [14,15,16]. Besides degrading the homogeneity of
the
photoresponse
of
the
avalanche
photodiode,
microplasma
formation is as well one of the reasons for an increase in the electrical noise of the APDs [15,17]. It corresponds to a local increase in the electric field
in the
multiplication
layer of the avalanche diode. In
particular the correlation between the microplasma density and the density
of
dislocations
in
the
semiconductor
layers
has
been
investigated. For InGaAs APDs some authors find approximately the same microplasma and dislocation density [18,19]. Others report for GaAs on Si [20], Si [21] and InGaAs [22] APDs that the microplasma density is orders of magnitude lower than the dislocation density. In t h e latter case it has been argued that only the decorated dislocations create
electrically
active
defect
sites
or
that
other
crystal
imperfections may be responsible for the microplasma formation [23]. It has been proposed that the dislocations cause a local enhancement of the
dopant
concentration
which
increases
the
electric
field
and
therefore leads to a local decrease of the avalanche breakdown voltage [18]. Local changes in the electric field strength in the multiplication layer can also be due to variations in the layer thicknesses or doping instabilities
[23],
The degradation of the metallic contacts [24] is another problem, which limits the long term stability of InGaAs avalanche photodiodes. Similar problems are already known for Ge APDs, where for example fast AI diffusion has been observed [25]. Here we will focus more on problems that are relevant in the normal temperature operating range of the avalanche photodetectors. Recently in some laboratories other types of InGaAs/InP APDs, which are - to our knowledge - not yet commercially available, have been realized. For example a charge layer has been inserted into the
976
P. Montangero
et al.
SAGM structure and the resulting SAGCM InGaAs high modulation 100GHz
based APDs exhibited
speed with a gain-bandwidth product higher than
[26] and low noise operation [5]. The substitution of the
homogeneous
multiplication
region by superlattice
[27] and multi-
quantum-well [28] structures enables the operation of these detectors in
the
single-carrier-initiated,
single-carrier-multiplication
mode.
This results in very low excess noise and allows for the operation of the device in the regime with high photocarrier multiplication [29], resulting
in elevated gain-bandwidth products.
Staircase APDs, as
proposed for operation at rather low applied voltages [30] have recently been realized using the GaAs/AIGaAs [31] and the InAIGaAs material systems [32]. To our knowledge reliability data on this kind of advanced structures is not yet available. In the present study we will give a short introduction to the electro-optical
characteristics
of
InGaAs/InP
Separate
Absorption
Grading Multiplication (SAGM)APDs, showing the results obtained on devices of four different manufacturers. Then we will demonstrate the existence of some of the above mentioned defects and more in detail study the microplasma formation and other inhomogeneities in the photoresponse. Additionally the degradation of these devices during a bias step-stress test at increasing temperatures has been monitored and the performances before and after degradation will be discussed. The physical mechanisms leading to the failure of some devices during this step-stress test will be discussed.
Experimental A)
Device Structures
In this work we report measurements families
of
commercially
available
performed avalanche
on four different photodiodes
from
different manufacturers. All the four APD families (labelled A,B,C,D), whose
schematical
cross
sections
are
given
in
Fig.l,
are
top
illuminated Separate Absorption Grading Multiplication (SAGM) APDs. They are specified to conform with the requirements of fiber-optic communication systems. I-or a description of the different types of InP based APDs the reader is referred to [33].
#C
n - kiGa,~P
n - kiP
n" - InP
#A
Fig.1
_~/tl
SHALLOW - O R
SI Nx (PASSIVATION)
/ IJi
#D
GRADED LAYER /
p - ELECTRODE (TI/Pt/Au)
SiN
k
.
n - Inp
n" InGmAi
I CONTACT
Separate Absorption Grading Multiplication InGaAs/InP APDs
PASSIVATICN
n " - kip
Si IMPLANT
n+ kiP (SUBSTRATE)
CONTACT
n - ELECTRODE (Au/Ge)
1
InP Substrale
n - InGa~
n - InGaAsp
% _ J ~ L _ ~ n'-,,
G U A R D RING
Schematic cross section of the four different families of
I
n - ELECTRODE
n + - ~ P SUB.
n - I n P BUFFER
#B
1__ ,.~..ACE
p - ELECTRODE
GUARD RING
p+ - REGION
n" - InGaAs
DEEP - OR
n - ELECTRODE
I
n + l n P - Sub
n - InP
n" InGaAs
n" ktGaAsP
n - InP
p - ELECTRODE
0 0
g
E
_~. O
F,"
m-
978
P. Montangero et aL
More than 12 APDs from each manufacturer have been characterized and most results reported here give an idea of the typical behaviour of the devices from each family. The insertion of an InGaAsP grading layer between the InGaAs absorption layer and the InP multiplication layer reduces the hole pileup at the valence band discontinuity and enables therefore the operation at higher modulation frequencies [34]. The active area of the device B is about 801.tin wide while for devices A,C and D it is 50gm wide and they are all illuminated from the top. The main differences between the investigated APD families is the definition of the lateral confinement and the guard ring structure. The photodetectors from the family A exhibit a very simple structure with only one guard-ring and with a multiplication layer defined by the p+ diffusion in the n--InP. The guard ring is created by ion implantation. In the family B the multiplication region is defined by a n-lnP mesa buried into the n--InP layers and a guard ring at the junction edges [35]. Devices C have two guard rings with a PLEG structure (Preferential Lateral Extended Guard-ring) [4]. For the
APDs from family D the multiplication area is obtained by
silicon implantation and not by the growth of a suitably doped layer as in the
other
implanted
structures
[36];
the
p+
region is larger than the Si
area in order to prevent edge breakdown at the curved
junction. This solution is alternative to the guard-ring implementation.
B)
Measurements techniaues
Dark current voltage (IV) characteristics of the avalanche photodiodes have
been
measured
different temperatures. illumination intensities
with (about
a
with
a semiconductor
parameter
analyzer at
The photocurrent has been measured laser
diode
at
100nW),
using
a
1550nm lock-in
at
low
technique
under
illumination with
a low
frequency modulation (f=4kHz) of the light source. To avoid casual results due to inhomogeneities of the photoresponse, the laser spot has been defocused to cover about 80% of the active photodiodes area. In the case of the characterization of a microplasma site, the incident light beam has been focused to the relevant part of the APD with a spot diameter of about l~m. In this latter case much lower light intensities (between 0.3nW and 8nW) have been used for characterization.
Multiplication avalanche photodiodes
979
High resolution imaging of the photoresponse of the APDs has been clone at different wavelengths and at different applied bias voltages using a scanning wavelengths
optical microscope
(SOM).
846nm, 880nm and 1320nm
Laser diodes at the
have been used as light
sources. Light with a wavelength of 1320nm is mainly absorbed in the InGaAs layer and probes therefore the photoelectric properties of the APDs under normal operation. Light at wavelengths of 846nm or 880nm is mainly absorbed in the upper InP layer and is used in this study for diagnostic
purposes.
responsivity
The
mapping,
light power
will
be
given
densities in the
(Io), used for the
figure
captions.
The
measurement setup has been described in detail elsewhere [37,38].
Results
A)
and
Discussion
Dark and photocurrent voltage characteristics before dearadation
A comparison
of the
current-voltage
(IV)
characteristics
at room
temperature of the four families of APDs is shown in Fig.2.
All diodes
exhibit at low applied bias voltages rather low dark current (Id) values,
10-4
10"4
,tot
10-6
,'l
#A
p-
I---
z
z
rr"
cC
LU 10-8 rr :::) O
Itot
10-8
10-10
10"1(]
10-12
t
10-6
II
,
,
,
,
1
l
l
1
,
-50 VOLTAGE (V)
10"12
,
- 100
10-4
S rl
0
i
i
i
i
#B
• 1
i
i
i
i
- 100
10-4
Itot
10-6
,,(
#C
I-Z
10-6
i
-50 VOLTAGE (V) f Itot
,* It
D #
F-
Z 10-8 rl"
10-8 rr
O 10-10
,~J/\,a
10-12
Fig.2
J
,
,
,
O
=
,
-50 VOLTAGE (V)
,
,
10-10
10-12
,
-100
-50 VOLTAG E (V)
- 1O0
Reverse IV characteristic, measured at 20°C without and with illumination at 1550nm for the four different APD types
P. Montangero et at.
980
which rapidly increase when the voltage reaches a threshold value. This threshold
corresponds
to the
punch-through
depletion
zone extends down to the
voltage,
InGaAs/InP
at which
interface.
the
Type
B
exhibits additionally a second rise of the dark current at about 23V. Also type D shows a small second increase of the dark current (in this case at about 28V ). The reverse dark current (Id) in this kind of APDs is mainly dominated (g-r)
current,
by two contributions:
which
interface defects,
increases
with
and additionally
the generation-recombination
increasing
by surface
density
of bulk and
leakage currents. The
leakage current at the surface can often be distinguished from bulk current contributions, because it is in general not multiplied at higher bias voltages. For APD families D and B only, the growth of the InP multiplication and
the
layer has been interrupted for the silicon
definition
of the
mesa
structure
respectively.
implantation The
rapid
increase of Id for a threshold value of the bias voltage above the punchthrough voltage, which is only present for this two families of APDs, may therefore be explained by an increased number of defect states at this internal interface and hence a rapid increase of the g-r current, when the depletion zone extends down to this region. An alternative interpretation of this rapid current increase for devices of family B and D could be the existence of two different punch-through voltages in the center of the device and in the outside region due to lateral dopant variation in these APD families [5]. Some diodes from the APDs of family A show at a reverse bias voltage of around 30V a significative
increase in the slope of the
current-voltage
clearly
characteristics.
More
than
for
the
diode
presented in Fig.2, this is observed in the characteristics of another APD presented
in Fig.14. The effect might be due to an onset of
tunnelling breakdown before the onset of avalanche breakdown at 63V, which degrades the photodetector performance of this device. For the device of the family C a plateau-like feature in the dark current just before the beginning of the avalanche multiplication has been observed. In the following
the avalanche
breakdown
voltage
(Vb)will
be
defined as the voltage where the reverse dark current equals 100~A. This breakdown occurs at room temperature in a range between 60V and 75V for families A,B and C, whereas the type D APDs exhibit higher breakdown voltages between 82V and 88V. The onset of breakdown is
Multiplication
avalanche
981
photodiodes
sharp for family C and more gradual in the case of family A, B and D. A reason for a more gradual increase may be either the early onset of tunneling breakdown or microplasma formation. The latter effect will be
looked
at
in more
detail
by high
resolution
mapping
of the
responsivity of the APDs in the next chapter. The comparison of the IV characteristics of the four families under illumination is also shown in Fig.2. The light intensities have in this case been chosen to give the same diode current of 100nA for all APDs at
the
punch-through
voltage.
In
the
photocurrent-voltage
characteristics of all four APD types one can clearly see the onset of charge
carrier
multiplication.
In Fig.3 the photocurrent (Iph), determined by lock-in technique has been plotted as a function of the applied bias voltage. Iph is almost negligible at low bias voltages and increases sharply at the punch through
voltage.
photocurrent
Increasing
starts
to
the
rise
bias
again.
voltage
This
is
still the
further, onset
the
of
the
multiplication regime, which is the voltage range where the APD is actually operated. All four APD types exhibit appreciable photocurrent gain. Under the assumption that the photocurrent value at the beginning
10-4
1
10-4
#A
t
v 10-6 IZ I.u n-"
,
#B
10-6 uJ
10-8
.5
10-10
10-10
0-
1` 1` t,
10-12 0
10-12
-100
-5O
VOLTAGE (V)
10-4
~" z ILl E
n"
G.
10-8
J~
•••
,
,
i
i
,
,
,
_~#D
#C
I - 10-6 Z LU
i
-50 VOLTAGE (V)
10-4 i i
¢~
,
0
10-6
-100
~ 5 lO-8
10-10 n
1
.5
10-10
1`1` 10-12 0
Fig.3
,
i
i
i i , ~ , -50 VOLTAGE (V)
i
i
10-12 -100
i
i
i
i
i
i
-50 VOLTAGE(V)
=
i
~ i
-I00
Inverse of the multiplication factor and photocurrent as a function of the reverse bias voltage measured at 20°C under illumination at 1550nm for the four different APD types
982
P. Montangeroet
al.
of the plateau equals a photocurrent multiplication factor (M) of 1, in Fig.3 the inverse of the multiplication factor has been plotted as well in function of the applied bias voltage. An alternative definition for the breakdown voltage is given as the voltage where M approaches infinity. This can be obtained by the extrapolation of the dependence of 1/M vs. bias voltage to l/M=0. For device A this gives a breakdown voltage of 65V, for device B of 68.5V and for device C of 66V. An analytical expression, which is in good agreement with the presented results for all four devices, has been given in literature for the voltage dependence of M [39]. M-
I_(V-R,It/p (1)
where p is a constant with typical values between 1 and 2, Vb is the breakdown voltage, Rs the series resistance of the APD and It the total multiplied current
current.
For even higher applied
of all four APD types
is again
bias voltages
dominated
the total
by the sharply
increasing dark current. In Fig.4 the temperature dependence of the dark current-voltage curve of a SAGM APD in the temperature range between 20°C and 100°C is shown for a device
of the family
B. Basically two temperature
lO-4
,o-71 I 10-11~ 10-121" 0 Fig.4
~
~
,
~
I , -50 VOLTAGE(V)
~
f
J -100
Reverse dark IV characteristic, measured at different temperatures between 20°C and 100°C (in steps of 10°C) for an APD from family B
Multiplication avalanche photodiodes
983
dependent changes have been observed. The avalanche breakdown voltage and the dark current are both increasing while increasing the operating temperature. The first effect is indeed a check that the breakdown mechanism is due to avalanche multiplication, because the alternative breakdown mechanism - i.e. tunnelling breakdown - shows the inverse temperature dependence [40]. In all four cases, Vb increases linearly with increasing temperature, following Eq.(2):
(2)
Vb(T)=Vb(To)(I+~(T-To))
with
positive temperature
coefficients
(p)
between
1.42.10"3°C "1
(family B) and 2.32.10"3°C "1 (family D). We took 273K as the reference temperature [7].
Also
(To). Similar values of I~ have been reported in literature the
generation-recombination
current
increases
with
increasing temperature. This effect causes the monotonic dark current increase with an increase in measurement temperature
below the
breakdown voltage regime. In general an activation energy (Ea)for the current in this regime can be defined and the change of dark current activation energy during an accelerated life test will be discussed in the last chapter.
B) Imaging of the resDonsivitv
For more than 12 samples each of all four types of APDs, high resolution
responsivity
images
have
been
taken
at
different
wavelengths and with different intensities of the probing light, varying in a wide range the applied bias voltages. Here we show in the beginning first
some
responsivity
images
of
APDs
with
a
homogeneous
photoresponse, followed with images of APDs, which display different kinds
of local
defects that have already been mentioned
in the
introduction. Most of the responsivity images presented here have been taken with applied bias voltages in the operating range of the APD, close to the avalanche breakdown regime. Typical photocurrent multiplication values in this regime range between 20 and 30. Local maxima in the photocurrent gain due to microplasma breakdown have been observed in all
investigated
APD
families,
but
with
very
different
rates
of
984
P. Montangero et al.
occurence. Microplasma breakdown has been observed for only one device out of 14 APDs from family B while almost every device from family D exhibited these type of defect. Also for APDs from family A microplasma breakdown has been frequently observed. APDs
of family
C showed
in general
a very homogeneous
photoresponse at all measured wavelengths. This is for example shown in Fig.5, where the responsivity image of an APD of the family C measured
at
62V
with
an
excitation
wavelength
of
1320nm
is
presented. At this wavelength, which is as well one of the wavelengths of interest for the application of the APD, the light is absorbed in the InGaAs layer and one gets information about the bulk properties of the photodiodes.
In order to get more detailed information
about the
homogeneity of the junction edge and guard ring region we mapped the same device at a wavelength of 880nm. It has been suggested in literature to use this probing wavelength for the investigated type of APDs in order to check for irregularities situated in the InP layer near the surface [41]. The result is shown in Fig.6. At this wavelength the photoresponse from the guard ring region is observed as well, which manifests itself in the ring with increased photoresponse surrounding the active diode region. In this case the photoresponse in the active region and also in the region of the guard ring is homogeneous.
Fig.5
Image of the responsivity of an APD of the family C, measured at 1320nm, Vbias=62V, Io=5W/cm2
Multiplication avalanche photodiodes
Fig.6
985
Image of the responsivity of an APD of the family C, measured at 880nm, Vbias=62V, Io=15W/cm 2
The
characterization
of an APD with a local
photoresponse
irregularity in the guard ring region is shown in Fig.7. In this case an APD of family A has been mapped at 880nm with an applied reverse bias voltage of 40V, well below the avalanche breakdown regime. A sharp
Fig.7
Image of the responsivity of an APD of the family A, measured at 880nm, Vbias=40V, Io=15W/cm2
P. Montangero et al.
986
peak in the photoresponse situated on the guard ring can be observed. Devices with such irregularities have a high failure probability, when operated in the multiplication regime [41]. Another common problem in this
APD
family
was
mask
misalignment
during
processing.
To
illustrate this problem, in Fig.8 photoresponse images of another APD from family A, which have been taken at different wavelengths and bias voltages are shown. In this case the photoresponse maps are displayed in a manner, that bright areas on the plot correspond to areas of high photocurrent. The black areas within the bright lines correspond to the metallization. The photoresponse map taken at 880nm with 0V applied bias (Fig.8 A) reveals the misalignment of the active area of the photodiode
with
respect
to
the
surrounding
metallization.
The
responsivity map of this APD, measured at an applied bias voltage of 62V (Fig.8 B) exhibits clearly an enhanced response at two points near the metallization outside of the active area. To enable an easier identification of this areas of punctual higher photoresponse with respect to the geometry of the device, in Fig.8C both maps at 880nm and 1320nm (Fig.8A and Fig.8B) are superimposed. A sharp local irregularity in the photoresponse due to microplasma breakdown is evidenced in Fig.9 for a device from family A biased at 65V. In this case the probing wavelength was 846nm, which is strongly absorbed in the top InP layers, including the multiplication layer. Also the overall homogeneity of the photoresponse of this device in the other parts of the active region is rather poor. Increasing only slightly the applied bias voltage, the responsivity map changes completely. This is seen in Fig.10, where the same APD as in Fig.9 has been mapped, but applying a bias voltage of 66V. Now the photoresponse is still quite inhomogeneous, microplasma,
but the
evidenced
sharp in
enhancement
Fig.9 cannot
at the
be seen
site
of the
anymore.
This
illustrates an often mentioned property of microplasma breakdown, which is limitation of the photocurrent due to the creation of a space charge induced by the high local current itself [16]. Increasing the bias voltage further to a value slightly below breakdown, even a reduced photoresponse may be observed on the microplasma site.
It may
therefore be possible that the APD presented in Fig.9 and Fig.10 contains other microplasmas, which
become visible at other bias
voltages. Consequently in the presence of microplasmas it is not
Multiplication avalanche photodiodes
997
P. Montangero et al.
988
i Fig.9
Image of the responsivity of an APD of the family A, measured at 846nm, Vbias=65V, Io=20W/cm 2
Fig.10 Responsivity image of an APD of the family A, measured at 846nm, Vbias=66V, Io=20W/cm 2
Fig.8
Image of the responsivity of an APD of the family A, measured at different wavelengths A) 880nm, Vbias=0V, Io=15W/cm2 B)
1320nm, Vbias=62V, Io=5W/cm 2
C) Superimposed image of A) and B) Bright areas correspond to high photocurrents values.
Multiplication avalanche photodiodes
989
Fig.11 Image of the responsivity of an APD of the family D, measured at 1320nm, Vbias=77V, Io--5W/cm2 sufficient to characterize the homogeneity of an APD only at one value of the bias voltage. The responsivity of almost all the APDs from family D suffered from a unique type of inhomogeneity, which is reported in Fig.11. The photoresponse appears as a series of parallel stripes separated by lower responsivity zones. It should be noted that the same stripes have been observed in the surface morphology of the device, taken with the scanning optical microscope in the differential phase contrast mode. For more details the reader is referred to [42]. Most probably growth i n h o m o g e n e i t i e s or problems related to the substrate surface induce this anomalous behaviour. The local behaviour of the photocurrent-voltage characteristics of the above characterized APD from family D is shown in Fig.12 measured in
two
different
points,
at
the
site
of
a
microplasma
comparison, in the center of the active area. The
local
and,
for
breakdown
voltage - estimated by the linear extrapolation of the I/M curve - is about 10V lower at the microplasma site than in the center of the active area. C)
Temperature
ste~)-stress
Two APDs of each family have been stressed at a constant voltage and at successively increasing temperatures. For the applied bias voltage
990
P. Montangero et al. 10-4 10-5
g
lo-6
,,,z
1o-,
rr :D 0
10"8
£O
10-
13.
10.10
!
-J
~"
%...
"
;,
#B
~'~
~1
1
,p,/oeo'erl - - ~ , ~ - ~ - - ~ ' ~
Iph (max)
10-11
-50
-100
VOLTAGE (V) Fig.12 Photocurrent (Iph) and I/M as a function of the reverse bias voltage measured at 20°C under illumination within (max) and outside (center) of the microplasma region for an APD of the family D. The incident light intensities were about 8nW for the measurement in the center and 0.3nW for the measurements on the microplasma site.
during this step-stress test a value of 90% of the breakdown voltage at the respective temperature has been chosen. This is a value close to the operating
range of the APDs. The step-stress has been performed at
temperatures increasing first from 40°C to 80°C and then in steps of 20°C
up to
a temperature
of
200°C.
After
150
hours
at
each
temperature the devices have been first cooled down to 20°C.
A
current-voltage characteristic has been taken at that temperature and successively the temperature has been increased temperature. intended
The
elevated
only to accelerate
temperatures
to the next higher
during
the degradation
step-stress
processes,
which
are are
already present at operating temperatures, and have therefore been limited to 200°C in order to avoid the creation of new degradation mechanisms, like the above mentioned contact degradation. In Fig.13 the current values at 20°C (named 190), determined after each stress temperature for a voltage, corresponding to 90% of the breakdown voltage of the respective APD, have been plotted as function o! the stressing time for two APDs each from the four different families. The two devices from family D failed at 140°C and 180°C respectively,
while the other three APD types showed only minor
Multiplication avalanche pholodiodes
temperature
991
(°C)
40 80 100 l zo 140 160 180 zoo
10 -4
,o
10 "s
=
10 6
•
A1
t.
A2
•
C1 C2
B1
0
DI
B2
•
D2
7^
10"z o
--=
I 0 "B 1 0 "9
10-1o 0
300
600
900
1200
time (h) Fig.13 Monitoring of the dark current, measured at 90% of the breakdown voltage (190) of the four different families of APDs
at 20°C
after different steps of a temperature
step-stress test at increasing temperatures
(40°C-200°C)
variations in the dark current. The curves for the two APD's from family B showed slight variations in the - rather low - dark current, which were very similar for both devices. In Fig.14 the dark current-voltage curves for one
device from each
10-4
10-4
#A1
#B1
A 10-6
.- 10-6
w II n-
=3, (,3
10-8
10-8
~ 10-1C
10"10
10-12 =
10-12
/
-50
-50
- 100
VOLTAGE (V)
10-4
A 10-6
w 10°8
o r¢
10-4
10-12
.
•
#C1 I-Z uJ cE
.--
#D1
10-6
10-8 (3 Y n.-
J
~ 10-10
- 100
V O L T A G E (V)
~ 10-10 .
0
.
.
, -50
.
.
VOLTAG E (V)
.
.
10-12 - 100
-50
-100
V O L T A G E (V)
Fig.14 Reverse dark IV characteristic, measured at 20°C for the four different APD types before and after temperature step-stress test
992
P. Montangero et al.
APD family, measured before and after step-stress test, are shown. The APD A1 shows a slight increase in the dark current in the whole measured voltage range, but no shift of the breakdown voltage. The kink, seen at 30V in the IV curve before aging test, is less pronounced after the step-stress test. The IV-characteristics of device B1 did not show measureable
changes.
For device C1 a slight increase of the dark
current at low bias voltages and a slight decrease near the avalanche breakdown breakdown
are
observed
voltage.
characteristics
in
After
addition the
to
step
a slight
stress
just below the breakdown
increase
test
the
regime (between
of the
dark
IV-
50V and
62V) shows a plateau like behaviour. The most dramatic changes - as already seen in Fig.13 - are found for the APDs of family D. Here an overall increase in the dark current of almost two orders of magnitude and additionally a significant decrease in Vb is found, as displayed for APD
D1 in Fig.14.
The step in the dark current
observed
before
degradation at 12V applied bias voltage cannot be seen anymore after degradation. The parameter changes of the APDs from family D - which failed during temperature step-stress at 140°C (D2), resp. at 180°C (D1) will be discussed more in detail. For this purpose the dark current has been measured as a function of the measurement temperature. By plotting the logarithm of the dark current, at the voltage where M=I and at 90% of the breakdown voltage,
1 2
'
'
I
'
'
'
I
'
'
'
r
'
'
'
I
'
after 10
- -~- ~ ,,
u
'
I
'
'
'
I
'
'
'
degradation I E =0.26eV a
m
"-"
'
-.
4
before
degradation
-o
C
2 0
E,=O.47eV ,
, , ,
30
I,
32
,,
I
34
t
i
i
I i I
36
I I =
I I I
38
'
40
,
,
J'
42
' '
44
1/kT (ev "1) Fig.15 Arrhenius-plot and resulting values of the activation energies of the reverse dark current at 90% of Vb for device D1 measured at 20°C before (open circles) and after (closed circles) step-stress
test
Multiplication avalanche photodiodes
993
Versus 1/kT, a single activation energy (Ea) has been found in the investigated temperature
range before and after step-stress. This is
shown in Fig.15 for the current vs. temperature dependence of device D1 for an applied voltage of 90% of Vb. In order to distinguish between the bulk clark current (Ibulk) and the surface dark current (Isurface), the dark current has been plotted as a function of the multiplication factor M. The result is shown in Fig.16 for the Diode D1 before and after stepstress. Now it has been assumed, following [4,43] that the surface dark current is not multiplied, so that for the total dark current (Id(tot))
results: (3)
Id(tot)=lsurface + M'lbulk
6 10"3 A
3 10 -3 O
2 10 .3 m "O
1 10.3
/
o o
O
D1
0 100
after
degradation
I
I
I
I
10
20
30
40
I
1
50
M
2 10"4
I
I
1 10 .4 O 0 0= "O
D1 before
0 10o 0
degradation
I
I
I
I
10
20
30
40
50
M
Fig.16 Reverse dark current as a function of M for device D1, measured at 20°C before (closed circles circles) and after step-stress test (open circles). The results of a linear fit to the data for high M values are displayed as well.
994
P. Montangero Table 1
et al.
Bulk and surface dark current values and dark current activation energies (Ea) at the voltage, where M=I and at 90% of the breakdown voltage for the two APDs from family D before and after temperature step-stress test
Isurface (A) Ibu~ (A) Ea (M=I) (eV) Ea (0.9*Vb) (eV)
I D2 (Ere stress)) 9.75 e-8 1.60e- 10 0.49 0.46
The linear extrapolation multiplication
D2 (post stress) 6.27e-6 4.96e-8 0.29 0.28
D1 (pre stress) 8.15e-8 2.20e-9 0.51 0.47
D1 (post stress) 4.33e-6 3.59e-8 0.26 0.26
of the dark current in the regime of high
values to M=0 (Fig.16) gives in this way the Isurface
value and the slope of the linear extrapolation the Ibulk contribution in the voltage regime where M is rapidly increasing. Table 1 summarizes the activation energies and bulk and surface dark current values for the two devices from family D before and after the step-stress test. The bulk dark current as well as the surface dark current contributions of D1 and D2 increase during the bias step-stress by 1-2 orders of magnitude. The activation energies of the dark current at both investigated bias voltages decrease roughly by a factor of two from 0.46-0.52eV before aging to 0.26-0.28eV after aging. Commonly
for
the
generation-recombination
current
a
dark
current activation energy of about half the bandgap is found [37]. This would give a value of about 0.37eV in the InGaAs layer and of about 0.67eV in the InP. The values of Ea before bias step-stress are in between
this two values
expected for the generation-recombination
currents originating from the InGaAs and InP layers. After degradation, however, the activation energy is close to the values of 0.20eV and 0.25eV, which have been reported in literature for the activation energy of surface
dark
currents
dominating
Id
after degradation
of APDs
[32,44]. From the dependence of Id on M we can state that surface as well as bulk contributions increase
during
significant
to the dark current of the investigated
degradation
decrease
in the
of
the
activation
devices energy
from
family
of the
dark
D.
APDs The
current,
however, indicates that the surface current contribution dominates the dark current after degradation. In the literature the most cited reason for the
dark
current
increase
under similar stress conditions
is a
Multiplication avalanche photodiodes
995
degradation of the passivating layer [24,44,45,46]. As possible reasons hot hole injection and trapping [24,45] and mobile charge buildup in the insulator [46] have been proposed. In another work the contribution of avalanche breakdown at the surface of the guard-ring junction formed in the InP cap layer has been found responsible for a surface current increase [41]. It is interesting to note that in this latter case this local enhancement
of the
surface
current
increases
other than
our
assumption made above - with increasing dark current multiplication values. In another study about the degradation of
InGaAs/InP APDs, the
degradation due to premature edge breakdown was reversible and could be baked out at 200°C, while the increase of the surface current due to charge trapping in the passivating layer was permanent [42]. This, however, is known to be partially recovered by a removal of the passivating layer by chemical etching [45].
Conclusions
Four different families of InGaAs/InP Separate Absorption Grading Multiplication avalanche photodiodes have been characterized by high resolution photoresponse imaging with a scanning optical microscope and by dark and photocurrent measurements. Different highly local features in the photoresponse like edge breakdown and microplasma formation have been observed on some devices. Another typical problem for one of the device families was a mask misalignment during processing, resulting also in an anomalous photoresponse at the diode perimeter. During a step-stress test at increasing temperatures up to 200°C the devices from only one APD family failed. The photoresponse of these latter devices, which failed at temperatures between 140°C and 180°C, exhibited already before degradation a highly non-uniform behaviour with microplasma formation
along parallel stripes. After the step-
stress a dramatic increase of the surface dark current of this failed devices has been observed.
996
P. Montangero et al.
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