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Transcript
1
Front-end performance and charge collection
properties of heavily irradiated DNW MAPS
Lodovico Ratti, Member, IEEE, Massimo Manghisoni, Member, IEEE, Valerio Re,
Gianluca Traversi, Member, IEEE, Stefano Zucca, Stefano Bettarini, Fabio Morsani, Giuliana Rizzo
Abstract—Deep N-well (DNW) CMOS monolithic active pixel
sensors (MAPS) fabricated in a 130 nm technology have been
exposed to γ-rays up to an integrated dose of about 10 Mrad and
subjected to a 100 ◦ C/168 h annealing cycle. Device tolerance to
total ionizing dose has been evaluated by monitoring the change
in charge sensitivity, noise and charge collection properties after
each step of the irradiation and annealing campaign. Damage
mechanisms and their relation to front-end architecture and
sensor features are thoroughly discussed by comparing the
response to ionizing radiation of different test structures and
based on radiation induced degradation models in single MOS
transistors.
Index Terms—MAPS, deep N-well, ionizing radiation, CMOS,
analog front-end.
I. I NTRODUCTION
D
EEP N-well (DNW) CMOS monolithic active pixel
sensors (MAPS) were proposed a few years ago to
enable the design of large, highly granular matrices of thin
charged particle detectors with fast readout architecture based
on sparsification techniques [1]. The DNW MAPS approach
takes advantage of the properties of triple well structures to lay
out a sensor with relatively large area (as compared to standard
three transistor MAPS [2]) read out by a classical processing
chain for capacitive detectors. The sensor, featuring a buried
N-type layer with N-wells (NW) on its contour according to a
typical deep N-well scheme, collects the charge released by the
impinging particle and diffusing through the substrate, whose
active volume is restricted to the uppermost 20-30 µm thick
layer below the collecting electrode. Therefore, within this
extent, substrate thinning is not expected to significantly affect
charge collection efficiency, while improving momentum resolution performance in charged particle tracking applications.
As mentioned above, DNW MAPS are being developed chiefly
to comply with the intense data rates foreseen for tracking
applications at the future high energy physics (HEP) facilities.
Based on the proposed solution, the MAPS detectors of the
Manuscript received December 11, 2009. This work was supported by the
Italian Ministry of University and Research through a National Firb Project,
contract #RBAP06L4S5.
Lodovico Ratti and Stefano Zucca are with INFN Pavia and
Dipartimento di Elettronica, Università degli Studi di Pavia, I-27100
Pavia,
Italy
(Phone: +39 0382 985222;
fax: +39 0382 422583;
email: lodovico.ratti@unipv.it).
Massimo Manghisoni, Valerio Re and Gianluca Traversi are with INFN
Pavia, I-27100 Pavia, and Dipartimento di Ingegneria Industriale, Università
di Bergamo, I-24044 Dalmine (BG), Italy.
Stefano Bettarini and Giuliana Rizzo are with INFN Pisa and Università
degli Studi di Pisa, I-56127 Pisa, Italy.
Fabio Morsani is with INFN Pisa, I-56127 Pisa, Italy.
Apsel series, which are among the first monolithic sensors with
pixel-level data sparsification [3], [4], [5], have been developed
and successfully tested at the Proton Synchrotron facility at
CERN [6]. Depending on the experimental environment and on
the position inside the detector, MAPS sensors will be required
to withstand a total ionizing dose (TID) which can range from
a few hundreds of krad(SiO2 ) [7] to about ten Mrad(SiO2 ) [8].
The effects of ionizing radiation on DNW MAPS were discussed for the first time in a previous work [11] which was
mainly focused on studying the damage mechanisms in the
readout electronics. In that work, the devices under test (DUT)
were exposed to a maximum dose of 1.1 Mrad(SiO2 ). The
present paper is concerned with the effects of higher γ-ray
doses, well beyond 1 Mrad(SiO2 ) and compatible with vertex
detector applications at the SuperB Factory experiment [8].
Furthermore, besides studying the performance of the frontend processor, this work also investigates the charge collection
properties of the sensing electrode under heavy irradiation
conditions. This has been done by means of measurement
techniques involving a laboratory 55 Fe radiation source and
an infrared laser.
II. DUT S
AND IRRADIATION AND TEST PROCEDURES
The DUT, called Apsel3T1, was designed and fabricated
in a 130 nm CMOS technology and includes a number of
structures with different features, described in detail in Table I.
In all of the tested devices, the signal coming from the sensor
(or from an external pulser through a 30 fF MIM injection
capacitor) is processed by means of the readout chain shown
in Fig. 1, including a charge preamplifier, an RC-CR shaper,
a threshold discriminator and a set-reset bistable circuit acting
as a memory cell. The analog front-end performs continuous
time charge amplification and shaping, which is a classical
choice for capacitive detectors [9]. This has to be contrasted
with the typical, imaging-like approach, where correlated
double sampling (CDS) techniques are used to perform timevariant filtering. The adopted solution lends itself in a more
straightforward way to implementing a data driven readout
architecture [10]. In Fig. 1, CF is the preamplifier feedback
capacitor, continuously reset by means of the MF NMOS
transistor operated in the deep subthreshold region. Moreover,
A(s) is the transfer function of the shaper gain stage, C1 is
the differentiating capacitance at the shaper input, while Gm
and C2 are the transconductance and the capacitance in the
shaper feedback network. By acting on the capacitance in the
high impedance node of the shaper gain stage and on the
2
VF
Gm
MF
C inj
C2
CF
A(s)
C1
p
n+
p
+ +
+ +
+
+ +
+
Vt
−
RST
DNW sensor
Preamplifier
Shaper
Discriminator
Latch
Fig. 1. Schematic diagram of the analog readout chain integrated in the deep N-well monolithic active pixel sensors. A conceptual cross sectional view of
the deep N-well sensor is also shown.
transconductor current, the shaping time can be set to 200
or 400 ns. The signal at the shaper output is compared to a
preset threshold voltage Vt . The 1-bit memory cell following
the discriminator, which is externally resettable, is used for hit
storage.
The MAPS devices integrated in the Apsel3T1 chip are
very similar, at least from an architectural standpoint, to those
included in the Apsel2T and Apsel2M test structures, whose
features and radiation tolerance were discussed in an already
published paper [11]. The Apsel3T1 can actually be considered
as an evolution of the Apsel2T and Apsel2M chips, aiming
at improving the MAPS performance in terms of noise/power
dissipation trade off, charge collection efficiency and immunity
to digital signals. In particular, in the Apsel3T1 chip, the
preamplifier NMOS input device (W/L=14 µm/0.25 µm, 4
fingers) is operated at a drain current ID of 20 µA (compare
it to the 30 µA drain current and W/L=16 µm/0.25 µm, of the
preamplifier input device in the Apsel2T and 2M chips, featuring 3 fingers). Again in the Apsel3T1 chip, the DNW sensor
was laid out in such a way to reduce the detector capacitance
to about 300 fF (from about 450 fF in the Apsel2 chips). In one
of the Apsel3T1 matrices, M1, the collecting electrode features
a main DNW body and three N-well satellites with different
shapes, aiming at maximizing the charge collection efficiency
without exceeding the 300 fF target detector capacitance.
Finally, the analog section and the substrate are shielded from
the digital signals, routed through metal 5 and metal 6, by
means of large metal 4 strips, also used for power distribution.
However, it is worth noticing here that the Apsel3T1 chip
was designed and produced before performing the radiation
hardness characterization on the Apsel2T and Apsel2M test
structures; therefore, no rad-tolerant measures, such as the
ones that might have been suggested by the results from
the first irradiation campaign (e.g., enclosed layout transistors
or thin oxides over the sensor junctions) were applied in
the design of the collecting electrode or of the front-end
processor. Besides the Apsel3T1 MAPS, also NMOS devices
and octagonal DNW diodes, with the same structure as the
MAPS collecting electrode shown at the beginning of the chain
in Fig. 1, have been irradiated. The γ-ray cobalt source used
for the tests presented in this work features a dose rate of
about 9.5 rad(SiO2 )/s. The irradiated MAPS parts were also
subjected to high temperature annealing (100 ◦ C for 168 h),
according to the ESCC radiation test guidelines [12]. The
DUTs were biased at the design operating point during both
the irradiation and the annealing procedures.
III. E FFECTS OF 60 C O γ- RAYS ON DNW MAPS
TABLE I
A PSEL 3T1 CHIP DESCRIPTION
M1
3×3 matrix, all analog outputs accessible, injection capacitance
(Cinj = 30 fF) for the central pixel, collecting electrode
featuring a main body and satellite N-well diffusions,
an area of 670 µm2 and a perimeter of 315 µm
M2
3×3 matrix, all analog outputs accessible, injection capacitance
(Cinj = 30 fF) for the central pixel, T-shaped collecting
electrode featuring an area of 880 µm2 and a perimeter
of 190 µm
M3
8×8 matrix, with row by row, 8 parallel digital readout,
one cell with injection capacitance (Cinj = 30 fF) and analog
output accessible (T-shaped collecting electrode area), half
the matrix featuring M1-like cells, the other half M2-like cells
PERFORMANCE
The ionizing effects of 60 Co γ-rays on DNW MAPS have
been studied by analyzing radiation-induced variations in the
most significant parameters of the front-end electronics and
of the collecting electrode. In the following, a selection of the
test results is shown, providing some paradigmatic examples
of the DUT behavior.
A. Effects on charge sensitivity
Exposure of the DNW MAPS to ionizing radiation is
responsible for a significant decrease in charge sensitivity. This
can be observed in Fig. 2, showing the charge sensitivity as
a function of the integrated dose for the accessible pixel of
an M3 matrix. The data, which also include post-annealing
3
Fig. 2. Charge sensitivity as a function of the total ionizing dose and after
the annealing procedure for the accessible pixel of an M3 matrix. Data are
plotted for the two available peaking times.
Fig. 3. Variation of the threshold voltage in a couple of irradiated narrow
channel NMOSFETs.
TABLE II
G EOMETRICAL FEATURES OF THE TESTED OCTAGONAL DNW DIODES
measurement results, are plotted for the two available peaking
times, 200 and 400 ns. Before irradiation, at each irradiation
step (900 krad, 2660 krad and 8200 krad for chips 24 and
25, 900 krad, 3300 krad and 9700 krad for chips 27 and
29) and after annealing, the gain value has been extracted
by linearly fitting the peak response of the front-end channel
to a voltage step with varying amplitude at the input MIM
capacitor Cinj (see Fig. 1). The corresponding amount of
injected charge has been calculated by taking into account the
nominal Cinj capacitance, 30 fF. Before irradiation, the charge
sensitivity is about 1.5 V/fC at a peaking time tp =200 ns,
about 1.3 V/fC at tp =400 ns. The decrease after exposure to
a 900 krad(SiO2) γ-ray dose is about 7% at both peaking
times. This result is in fair agreement with the outcomes of the
rad-hard characterization of the Apsel2T MAPS sensors [11],
where the maximum observed change in charge sensitivity, actually after a slightly larger integrated dose (1.1 Mrad(SiO2 )),
was just over 10%. After irradiation with an integrated dose of
9700 krad(SiO2 ), the charge sensitivity is found to be slightly
more than 80% of its original value at tp =200 ns and slightly
less than 75% of the pre-irradiation value at tp =400 ns. The
annealing cycle brings the charge sensitivity back to a state
not far from its pre-irradiation condition. The mechanisms
underlying such a behavior, thoroughly analyzed in the case of
the Apsel2T chip [11], are briefly summarized in the following
together with new supporting evidence. In particular, charge
sensitivity was found to decrease as a result of 1) the threshold
voltage shift in the feedback NMOSFET MF of the charge
preamplifier, only partially compensated by 2) the leakage
current increase in the detector, and as a consequence of 3)
the change in the feedback transconductance and in the gainbandwidth product of the shaping stage.
1) Threshold voltage shift in MF . Although deep submicron CMOS technologies are acknowledged to possess quite
a high degree of radiation tolerance [13], nevertheless, N- and
PMOS devices, belonging to the 130 nm CMOS node and
featuring a channel width W smaller than about 1 µm, were
proven to undergo the so called radiation induced narrow chan-
name
A
B
C
area [µm2 ]
55 · 103
16.1 · 103
4 · 103
perimeter [µm]
1194
638
318
nel (RINC) effect, involving charge trapping in the shallow
trench isolation (STI) oxides. This has been proposed as the
main cause for a substantial change in the drain leakage current
and in the threshold voltage [14]. This phenomenon is likely
to affect MF in the preamplifier feedback network, featuring
W = 0.18 µm and channel length L = 10 µm. A couple of
devices, N M 1 and N M 2, belonging to the same technology
as the Apsel3T1 and with the same aspect ratio as MF , have
been exposed to different integrated doses of γ-rays to search
for possible evidence of the RINC effect also in the technology
used for the Apsel3T1 MAPS devices. During irradiation they
were kept with their source and drain grounded and the gate
biased to 1.2 V. This was done for the sake of comparison
with the results from rad-hard tests on wider channel devices
from the same node and manufacturer and on narrow channel
transistors belonging to the same node but coming from a
different foundry. Fig. 3 shows the variation in the threshold
voltages of NM1 and NM2. The change is of the order of a few
tens of mV, significantly larger than found in transistors with
larger W from the same process [13]. Interestingly enough, a
partial recovery can be detected for N M 2 just after the last
irradiation step, as a possible consequence of the interface state
negative charge starting to compete with the oxide-trapped
positive charge (as it was observed in the technology where
the RINC effect was recognized for the first time [14]). On
the other hand, no hint of such a rebound-effect (not to be
confused with annealing-induced recovery) can be found in
Fig. 2 (nor in the data presented in the next sections). This may
be due to the operating conditions of N M 2 in Fig. 3 being
different from those of MF . Also, the starting TID value for
the rebound-effect may vary by several Mrad [14]. It is worth
mentioning in conclusion of this section that no thorough
study was carried out on possible TID induced formation
4
Fig. 4. Leakage current as a function of the reverse voltage in a deep Nwell diode. The preirradiation curve is compared to the ones obtained after
exposure to a 900 krad(SiO2 ) and to a 3300 krad(SiO2 ) TID.
Fig. 5.
Leakage current at a reverse voltage of 5 V as a function of
the junction perimeter length after irradiation with a 900 krad(SiO2 ) and a
3300 krad(SiO2 ) TID for the three test diodes described in Table II.
of conductive channels under the STI between adjacent N+
diffusions (e.g., terminals of neighbor NMOS transistors) at
different potentials. However, power supply currents, which
were monitored throughout the entire irradiation campaign, did
not show any detectable change indicating possible creation of
parasitic field oxide transistors (so called FOXFETs).
2) Leakage current increase in the detector. Response to
ionizing radiation of the DNW detector was studied by testing
a set of three octagonal DNW diodes whose geometrical
features are listed in Table II (see Table I for a comparison
with the area and perimeter of the Apsel3T1 sensors). Fig. 4
shows the leakage current in an A diode for a reverse voltage
spanning from 0 to 10 V at varying TID. A substantial increase
can be detected over the entire reverse voltage range. The
buildup of holes in the field oxide and the creation of trapping
states at the Si/SiO2 interface over the PN junction may
account for an increase of the surface generation current [15],
[16]. Based on the involved damage mechanism, the leakage
current is supposed to be proportional to the length of the
Fig. 6. Radiation effects on the amplitude and shape of the MAPS response
to a 750 electron input charge. The pixel belongs to an M3 matrix.
junction at the silicon surface. This is supported by the results
shown in Fig. 5, where the leakage current at a reverse voltage
of 5 V is plotted as a function of the junction perimeter length
after irradiation with a 900 krad(SiO2 ) and a 3300 krad(SiO2)
TID for the three test diodes described in Table II. Data points
can be fitted fairly well to a linear function, demonstrating that
no significant bulk damage effect, which would be roughly
linearly dependent on the junction area, contributes to the
leakage current increase. This result agrees with the literature
data reporting on the relatively small values of the 60 Co
γ-ray bulk damage factor in silicon diodes [17], which, as
calculations confirm, yields a completely negligible leakage
current term from the depleted volume.
3) Change in the feedback transconductance and in
the gain-bandwidth product of the shaper. Also in the
shaping filter, the RINC effect provides a further contribution
to charge sensitivity decrease. Radiation induced change in
the threshold voltage of the PMOS current source (featuring
W = 0.18 µm) in the shaper input stage is responsible for a
decrease in the gain-bandwidth product. On the other hand, a
threshold voltage shift in the transconductor current sources
(all featuring W = 0.25 µm), may result in an increase of
the feedback transconductance. Both effects combine to bring
about a reduction in the peak response of the analog channel [11]. Moreover, transconductance increase is expected to
speed up the return to the baseline of the shaper response. This
is actually confirmed by the waveforms in Fig. 6, illustrating
the effects of radiation on the response of a DNW MAPS
to an input charge of 750 electrons. Return to baseline grows
faster with increasing TID. Note that, after annealing, the pixel
response is restored virtually to its original state.
B. Effects on noise performance
Equivalent noise charge (ENC) is a figure of merit for
analog processors, defined as the charge to be injected at the
input of a charge measuring system to have a peak response as
high as the output root mean square noise. In the monolithic
sensors under test, the main noise contribution comes from
the fluctuations in the drain current of the preamplifier input
5
Fig. 7. Noise voltage spectrum before and after a 1.1 Mrad(SiO2 ) γ-ray
dose for an NMOS device with W/L=20/0.20 belonging to the 130 nm CMOS
process used for DNW MAPS fabrication.
Fig. 8. Noise voltage spectrum in the preamplifier input device calculated
based on the design operating point, the transistor dimensions and the noise
characterization of 130 nm CMOS devices from the same technology as the
Apsel3T1 chip. The modulus of the shaper frequency response normalized to
its peak value for a peaking time tp of 400 ns is also shown.
device. At the available peaking times, other contributions
from the preamplifier feedback network and from the detector
leakage current can be safely dropped. This is also supported
by the results of the rad hard tests on the Apsel2T chip, where
noise contributions other than the one from the input device
were found to be negligible at tp =500 ns [11]. The noise in
the preamplifier input transistor can be represented by means
of a voltage source in series with the device gate. Its power
spectral density Se2 (f ) is given by
Af
Kf
4kB T
2
Se2 = Sw
+ αf = nγ
+
.
f
gm
W LCox f αf
K
(1)
with Af = W LCf ox . The previous equation includes a fre2
quency independent component, Sw
, mainly accounting for
the channel thermal noise in the input device drain current,
A
and a 1/f term, f αff . In the equation, n is the subthreshold
slope coefficient, γ is the channel thermal noise coefficient,
depending on the device operating point and polarity, kB is
Fig. 9. Equivalent noise charge as a function of the absorbed dose and after
the annealing cycle for the central pixel of an M1 matrix. ENC is plotted for
the two available peaking times.
the Boltzmann’s constant, T is the absolute temperature, gm
is the device transconductance, Kf is an intrinsic 1/f noise
process parameter, Cox is the gate oxide specific capacitance
and αf is the 1/f noise slope coefficient (about 0.85 in the
NMOS devices from the 130 nm process used for the tested
MAPS [18]). Eq. (1) does not include any Lorentzian term
pointing to possible random telegraph signal (RTS) phenomena, which are typically found in small area MOSFETs [19],
[20]. Such phenomena were actually detected only in some
of the smallest among the irradiated single device samples,
featuring W/L=10/0.13. In transistors with gate area of the
same order of the preamplifier input device or larger, the
low frequency spectrum, both before and after irradiation,
was found to be dominated by flicker noise. This is shown
as an example in Fig. 7 for an NMOS with W/L=20/0.20
irradiated with a 1.1 Mrad(SiO2 ) γ-ray dose. The expected
pre-irradiation behavior of the preamplifier input device from
the standpoint of the noise voltage spectrum Se , shown in
Fig. 8, was calculated based on the design operating point,
the transistor dimensions and the noise characterization of
130 nm CMOS devices from the same technology as the
Apsel3T1 chip. In the same figure, the modulus of the shaper
frequency response normalized to its peak value has been
superimposed onto the noise spectrum to emphasize that 1/f
noise contribution to the overall noise performance of the
system is supposed to dominate over channel thermal noise.
Based on (1), the ENC can be calculated to be
EN C 2 = CT2
α −1
2 1
A1 Sw
+ A2 · (2π)αf Af tPf
,
tp
(2)
where CT is the total capacitance shunting the charge preamplifier and A1 and A2 are shaping coefficients. The effects
of radiation on the ENC are shown in Fig. 9, where the
equivalent noise charge is plotted as a function of the absorbed
dose and after the annealing cycle for the central pixel of an
M1 matrix at the two available peaking times. A significant
increase in equivalent noise charge can be detected, from about
40 electrons to between 110 and 150 electrons, depending on
6
Fig. 10. Relative variation of the drain current with respect to the postirradiation value upon absorption of a 10 Mrad γ-ray dose. Data are plotted
as a function of the total post-irradiation current.
the peaking time, after exposure to radiation. The annealing
procedure brings the noise performance back to somewhere
between the starting DUT state and the post-900 krad step
condition. It is worth recalling that the charge sensitivity
features a qualitatively similar response, with a remarkable
performance recovery after annealing, possibly due to partial
annihilation of the positive charge trapped in the STI. ENC
degradation after irradiation is likely to originate from low
frequency noise increase in the preamplifier input device.
According to the model validated in previous works [21],
[22], flicker noise gets worse as a consequence of parasitic
lateral transistors being turned on by positive charge buildup
in the shallow trench isolation oxides and contributing to the
overall noise. Radiation induced increase in border trap density
provides a further, although minor, contribution to the overall
noise degradation. The role of STI and parasitic lateral transistors in 1/f noise degradation has been emphasized in deep
submicron technologies, in particular in 130 nm and 90 nm
ones. It was probably less significant, if not negligible, in older
CMOS generations, where the contributions from border trap
density increase and charge buildup in the transistor gate oxide
were predominant [23], [24]. In irradiated devices, flicker
noise increase can be expressed through the ratio between the
post-irradiation coefficient Af,post and its pre-irradiation value
Af,pre
Kf,m,post 1 +
Af,post
=
Af,pre
Kf,m,pre
2
gm,lat
Kf,lat
W Cox
2
Kf,m,post Wlat Cox,ef f gm,m,post
2
gm,lat
1 + gm,m,post
.
(3)
In (3), Kf,m,pre , is the preirradiation intrinsic process parameter for 1/f noise in the main device, Kf,m,post and Kf,lat are
post-irradiation intrinsic process parameters in the main and
in the parasitic transistor respectively, Cox,lat is the effective
oxide capacitance of the parasitic STI sidewall transistor,
gm,m,post is the channel transconductance in the main device
and gm,lat = 2nf gm,lat,s , with nf the number of fingers com-
Fig. 11.
Equivalent noise charge normalized with respect to the preirradiation value and averaged over several pixels in different Apsel2T and
Apsel3T1 chips.
posing the main transistors and gm,lat,s the transconductance
of the single parasitic device. Note that for each finger, two
single parasitic devices get switched on by charge trapped
in the STI, each with channel length L and channel width
lat
Wlat,s = W
2nf . Under the simplifying hypothesis, generally
valid in the low power operation adopted for DNW MAPS,
that the main and the single parasitic devices are made to work
in weak and strong inversion respectively [21], then
gm,lat,s
≃
r
2µn Cox,ef f
Wlat,s
ID,lat,s ,
L
(4)
ID,m,post
,
(5)
nφt
with µn the electron mobility in silicon, ID,lat,s the drain
current in the single parasitic transistor, ID,m,post the postirradiation drain current in the main device and φt the thermal
gm,lat
voltage. If gm,m,post
<< 1 is also assumed, (3) can be
rewritten as
gm,m,post
Af,post
Af,pre
≃
Kf,m,post
(1 +
Kf,m,pre
W
ID,lat,s
Kf,lat nIz∗
), (6)
2nf
Kf,m,post L ID,m,post ID,m,post
≃
where Iz∗ = 2µn Cox nφ2t is the normalized drain current
marking the boundary between weak and strong inversion.
Equation (6) points out that, for a given CMOS process, flicker
noise degradation is larger in devices with larger number
I
. As a
of fingers nf and smaller current density D,m,post
W
matter of fact, radiation induced flicker noise increase was
experimentally proven to affect in a more pronounced fashion
NMOSFETs with many fingers and operated at small current
densities, where the parasitic devices have a greater impact
on the behavior of the main transistor [22]. On the other
ID,lat,s
ratio is a
hand, experimental data indicate that the ID,m,post
decreasing function of the total post-irradiation drain current
ID,tot = ID,m,post + 2nf ID,lat,s , corresponding to the current
forced into the device drain terminal. This is shown as an
7
I
D,lat,s
example in Fig. 10, where the ID,m,post
ratio is plotted as
a function of ID,tot upon absorption of a 10 Mrad γ-ray
dose for a set of NMOSFETs with W = 1000 µm and
varying L. Equation (6) provides some hints for rad-hard
front-end design, which are substantiated by the results of
Fig. 11, showing the ENC normalized with respect to the
pre-irradiation value averaged over several pixels in different
Apsel3T1 and Apsel2T chips (the latter operated at a peaking
time of 500 ns, comparable with the 400 ns peaking time of
the Apsel3T1 chip). The Apsel2T MAPS are found to perform
better even at larger integrated doses. This result can be
explained by considering the layout features and the operating
point of the preamplifier input device in the two different
MAPS versions. In particular, the smaller drain current density
and the larger number of fingers (see Section II) make the
Apsel3T1 preamplifier input device more sensitive to ionizing
radiation as far as flicker noise is concerned. These results
corroborates once more the notion that, at least in the 130 nm
technology node, enclosed layout transistors, with their very
high degree of radiation hardness [22], are mandatory if low
noise performance under irradiation is required.
C. Charge collection properties
The effects of ionizing radiation on the charge collection
properties of the Apsel3T1 chips under examination have
been also tested by means of an 55 Fe source and a low
power, infrared laser source. 55 Fe sources can be used to
provide charge sensitivity and noise calibration for pixels
without injection capacitance and to validate measurements
obtained with other methods. Fig. 12 shows the event count
rate distribution for a pixel in an M2 matrix and compares preirradiation, post-irradiation and post-annealing spectra. A very
similar behavior was found in the characterization of the other
DUTs. 55 Fe X-rays release their entire energy in the detector
substrate through photoelectric interaction. Photons from the
55
Fe 5.9 keV line generate about 1640 electron/hole pairs
each. When photons convert in the junction depleted region,
the released charge is virtually entirely collected, yielding
the peak in the 55 Fe spectrum. Charge released far from the
junction and only partially collected is responsible for the
pedestal at lower amplitudes. Data shown in Fig. 12 are in
fair qualitative agreement with the charge sensitivity and noise
results discussed in the previous sections. As the absorbed dose
increases, the 5.9 keV peak gets broader as a consequence
of the noise increase. At the same time, the peak is shifted
towards lower amplitude values, as a result of the charge
sensitivity decrease. Immediately after the first irradiation
step, a non negligible loss in the count rate can be detected in
the peak region. Since the count rate in the peak is proportional
to the depleted substrate volume, this result might hint at a
reduction in the thickness of the space charge region at the
DNW-to-substrate junction. This in turn may be possibly due
to a decrease in the DNW potential as a consequence of a
change in the gate voltage of the preamplifier input transistor.
After the annealing procedure, the 55 Fe spectrum is restored
almost to the original condition, only with a persisting event
rate loss with respect to the pre-irradiation measurement results. Note that the charge sensitivity values provided by 55 Fe
Fig. 12. Event count rate histogram for a pixel of an M2 matrix tested
with an 55 Fe source before irradiation, after exposure to γ-rays and after the
annealing cycle.
Fig. 13. Charge sensitivity normalized to the pre-irradiation value for the
central pixel of an M2 matrix. Data obtained by means of charge injection
through the input MIM capacitor is compared to charge sensitivity values
extracted from 55 Fe calibration.
measurements, between 800 and 900 mV/fC, are significantly
different from the ones shown in Fig. 2. This discrepancy
might be due to the actual value of the injection capacitance
being sizeably underestimated and considerably larger than the
nominal 30 fF value. Nevertheless, once the charge sensitivity
is normalized to the pre-irradiation value, 55 Fe tests and
charge injection through Cinj provide fairly similar results.
This is shown in Fig. 13, comparing the normalized charge
sensitivities obtained, at a peaking time of 400 ns, by applying
the two mentioned measurement techniques to the central pixel
of the M2 matrix in chip 24.
A measurement setup for precision scanning with an infrared laser (featuring a wavelength λ=1064 nm and a beam
spot of about 20 µm in diameter) was also used to investigate
the charge collection properties of the deep N-well MAPS.
The samples were illuminated from the back side in order
to avoid reflections from the intricate net of interconnections
laid out on the front side. Note that, in this configuration,
8
Fig. 15. Peak value of the collected charge in the central pixel of M1 and
M2 matrices illuminated with an infrared laser beam. Data are plotted as a
function of the integrated dose and after the annealing cycle.
Fig. 14. Charge collected by the central pixel of an M1 matrix illuminated
by an infrared laser as a function of the laser spot position before irradiation
(upper figure) and after exposure to a 9700 krad γ-ray dose (lower figure).
The figures also show the layout of the sensor, with a main body and three
N-well satellite diffusions.
the light, after going through the device bulk, is reflected
back into the substrate by the metals at the chip top. Since
the aim of the laser test is to evaluate the relative variation
of the collected charge with the laser spot position inside
the pixel, reflection is not expected to significantly affect the
measurement results, as long as it is uniform over the cell.
The latter is a reasonable assumption, as the chip top side is
virtually fully covered with metal layers. Fig. 14, which is
exemplary of the general behavior of the tested pixels, shows
the charge collected by the central pixel of an M1 matrix as
a function of the laser beam position before irradiation and
after exposure to a 9700 krad(SiO2 ) total ionizing dose. The
figures also show the layout of the sensor, with a main body
and three N-well satellite diffusions. The collected charge was
calculated as the ratio between the amplitude of the readout
channel response to the laser pulse and the charge sensitivity
measured by means of charge injection through an external
pulser. The matrix, which features a pitch of 50 µm in both the
X and Y directions, has been scanned using a 5 µm step. The
point corresponding to the maximum collected charge value
was taken as the (0,0) coordinate. Before irradiation, the peak
value of the collected charge is about 1000 electrons, which is
close to the signal from a minimum ionizing particle (MIP).
This is supported by laboratory tests performed with a 90 Sr
source. After irradiation a small decrease (about 5%) in the
peak value of the charge collected by the DNW sensor can be
noticed. This very limited effect might be ascribed to the small
amount of non-ionizing energy released by 60 Co γ-rays in the
sensor substrate, which might be responsible for the creation
of traps in the bulk (although with a very small density)
through Compton scattering and, as a consequence, for an
increase in the carrier recombination probability. Actually,
such a small variation might also be explained with errors in
the measurement setup, due for instance to slight differences
in the distance between the DUT and the laser focuser from
measurement to measurement. This latter hypothesis seems to
find support in Fig. 15, where the peak value of the collected
charge in the central pixel of M1 and M2 matrices is plotted
as a function of the integrated dose and after the 100◦C/168 h
cycle. Although the data values at 9700 krad dose are 510% lower than the pre-irradiation values for all of the tested
devices, nevertheless no clear trend with the dose can be easily
determined. Also, the leakage current test results discussed in
Section III seems to validate the hypothesis of a very limited,
if not completely absent, bulk damage.
IV. C ONCLUSION
In this paper, results from total ionizing dose characterization of deep N-well monolithic sensors fabricated in a 130 nm
CMOS technology have been presented and discussed. A large
set of devices have been irradiated with γ-ray doses up to
about 10 Mrad(SiO2 ) (a relatively high integrated dose as far
as MAPS are concerned) in view of applications to the vertex
detector for the SuperB Factory experiment. DUTs were also
subjected to a 100◦C/168 h cycle. At the highest integrated
dose, a decrease of 20-30% in the charge sensitivity and an
9
increase well in excess of 100% in the equivalent noise charge
have been detected. Increase in the sensor leakage current was
proved to result mainly from hole buildup in the field oxide
over the junction and/or trap creation at the SiO2 /Si interface.
The analysis of charge collection properties of irradiated DNW
MAPS, carried out by means of an 55 Fe and an infrared laser
source, did not indicate any major performance degradation.
The results presented in this work gather new evidence to support the damage mechanisms proposed in a previous radiation
tolerance study on a very similar structure irradiated at much
lower doses. They also provide a set of useful rules for radhard design of DNW MAPS and, more generally, of analog
front-end in deep submicron CMOS processes. Irradiation
with a monochromatic neutron source is being planned to
study MAPS sensitivity to bulk damage. Moreover, new Apsel
samples will be irradiated with a low dose rate γ-ray source
and subjected to room (or under 100◦ C) temperature annealing
cycles to investigate their behavior under conditions closer to
the real application.
ACKNOWLEDGMENT
The authors wish to thank A. Faucitano (Università di
Pavia), who made the 60 Co source available for device irradiation, and M. Dellagiovanna, who carried out a large part of the
measurements presented in this work. They are also indebted
to V. Speziali (Università di Pavia) for her useful suggestions.
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