Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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CORROSION RESISTANT IMAGER
BACKGROUND OF THE INVENTION
1. FIELD OF THE INVENTION
The field of the invention is imaging or display arrays
having photosensor arrays having components embodying
hydrogenated amorphous silicon (a-Si) technology, and more
particularly, to a contact pad, as well a guard ring, having enhanced
corrosion resistance while at the same time providing reliable
electrical connections and also being particularly suited for use with
an encapsulated data line having reduced electrical resistance. Such
arrays may be used for X-ray or light imaging.
2. DISCUSSION OF THE PRIOR ART
Imagers and display arrays have contact pads to which
electrical contact can be made to external circuitry. Contact fingers
connect the contact pads to the edge of the active array area where
they electrically connect to scan or data lines or to the common
electrode of the array.
The imager is formed on a substantially flat substrate,
typically glass. The imager comprises an array of pixels with
photosensitive elements, typically photodiodes, each of which has an
associated switching element, preferably a thin film transistor (TFT).
Both devices (photodiodes and TFTs) preferably comprise a-Si. In
operation, the voltage on the scan lines, and hence that of the gates of
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TFTs of the pixels associated with each scan line, are switched on in
turn, allowing the charge on each scanned line's photodiodes to be
read out via the data address lines. The scan and data address lines
are typically perpendicular to each other. The address line consists of
a region in the array. The region outside the array comprises the
contact finger, its associated contact pad and then, electrically
insulated from the contact pad, a guard ring. The electrical contact to
the guard ring is made via its own contact pads which do not
electrically connect to the array. Thre guard ring is usually maintained
at ground potential during operation. The guard ring . serves the
purpose of protecting the array from electrostatic discharge during
formation of the imager, and during connection of the imager to
external circuitry.
The contact pad is defined by an area of conducting
material exposed on the substrate surface on a pad surface. The
contact pad region, as used herein, includes the surface contact
region and any additional regions with structures that electrically
connect the surface pad to the main body of the contact finger.
Usually the contact pad is at the end of the contact finger and the
guard ring resides outside the contact pad. In some array
embodiments, address lines may have two contact fingers and
associated contact pads, at opposite sides of the array.
Contact pads consist of a single region TFT gate metal,
gate dielectric with vias formed in them, source-drain (S-D) metal
regions serving as electrodes, TFT passivation dielectric material
typically comprised of silicon oxide (SiOx), a first layer of diode
passivation material with a via formed through the two layers (TFT
passivation dielectric and diode passivation materials), and a topmost
conducting material typically comprising indium tin oxide (ITO) (which
also usually forms a substantially transparent common electrode in the
photodiode array). The imager includes other materials, such as TFT
amorphous silicon (a-Si), photodiode a-Si, an overlaying thin ITO layer
on the photodiode, and polymer dielectric, typically a preimidized
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polyimide (PI) all of which materials are generally removed from the
contact pad region. U.S. Patent 5,233,181, assigned to the assignee
herein, provides a description for a two layer diode passivation
dielectric in which diode passivation layer formed of silicon nitride
(SiNx) is removed from the contact pad during formation of the diode
top contact via. It has been found that ITO is a good conducting
material for use in imagers and display panels because it provides
good electrical contact resistance and is particularly suited for use in a
contact pad, but it is not a good barrier to moisture allowing possible
corrosion of underlying metals.
It is thus desirable in a contact pad for an imager or
display panel to use ITO as a conductor, but provide means to retard
or even eliminate any corrosion of the contact pad from exposure to
ambient moisture. It is further desirable that good electrical contact
be maintained by conductive lines extending through vias disposed in
passivation layers, such as thick inorganic dielectric materials
disposed on the array.
Ground rings, in a manner similar to contact pads, suffer
from corrosion when exposed to moisture which degrades the
electrostatic protection and electrical function that the ground rings
provide, and it is desirable to provide ground rings having means to
retard or even eliminate corrosion of the ground rings when exposed
to moisture.
The contact fingers, commonly employed in imagers and
display arrays, electrically connect to the data lines of the active array.
High performance imagers require low noise. Data lines suffer from
having unwanted electrical resistance which increase Johnson-related
noise during data readout, thereby degrading imager performance; it is
thus desirable in an imager array to provide data lines with reduced
resistance.
Solid state imaging devices are of particular importance
to the present invention and typically include a photosensor coupled to
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a scintillator. Radiation absorbed in the scintillator (such as x-rays)
generates optical photons which in turn pass into a photosensor, such
as a photodiode, in which the optical photons are absorbed and an
electrical signal corresponding to the incident optical photon flux is
generated. The accumulated charge on the respective photosensors
provides a measure of the intensity of the incident radiation. Such
imaging devices commonly comprise an array of pixels arranged in
rows and columns. Each pixel includes a photosensor that is coupled
via a switching transistor (typically a~ TFT or the like) necessitating two
separate address lines, a scan line and a data line, and a. connection
to a common electrode which electrically connects to one surface of all
the photodiodes in parallel. In each row of pixels, the readout
electrode of the transistor (e.g., the source electrode of the TFT) is
coupled to a data line. The photosensor charge from each pixel is
read by sequentially enabling rows of pixels (by applying an electrical
signal to the contact pad and therefore to the TFT's respective gate
electrode which causes the scan line to become conductive), and
reading the photosensitive charge from the respective pixels thus
enabled via respective data lines coupled to the TFTs.
Amorphous silicon is commonly used in the fabrication of
photosensors due to the advantageous photoelectric characteristics of
a-Si and the relative ease of fabricating such devices. In particular,
photosensitive elements, such as photodiodes, can be formed in
connection with necessary control or switching elements, such as
TFTs in relatively large area arrays. Environmental conditions can
affect the performance of the a-Si components; for example,
performance is degraded by exposure to moisture in a manner similar
to that discussed with reference to the contact pad and guard ring of
the imager, which can be absorbed from humid air in the ambient
environment. Moisture absorption in photodiodes undesirably
increases the charge leakage from the diode.
Charge leakage is a critical factor in photodiode
performance as the loss of charge during a sampling cycle lessens a
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photodiode's'sensitivity and increases the noise. The two significant
components of charge leakage are area leakage and sidewall
leakage. Particularly in smaller diodes in which the length of the
sidewalls is relatively large with respect to the overall area of the
photodiode, sidewall leakage constitutes the primary source of
leakage, although degradation of sidewall surfaces due to exposure to
moisture can make sidewall leakage a significant leakage source in
almost any size photodiode.
Multitier passivation layers are commonly made up of
inorganic and organic dielectric materials as described in previously
cited U.S. Patent 5,233,181. The inorganic part of the diode
passivation layer is typically comprised of silicon nitride while the
organic passivation layer is commonly made up of polyimide. Most
polyimides providing otherwise satisfactory passivation layer
characteristics are hygroscopic, that is they tend to absorb some
moisture from the environment. A dielectric material such as SiNx
should have a high level of structural integrity to provide the desired
moisture resistance and electrical insulation. This characteristic is
particularly important as defects in the barrier layer disposed on the
ITO common electrode can allow moisture penetration which in turn
results in electrical leakage from the photodiodes: electrical leakage is
an undesirable behavior that can seriously degrade imager
performance by introducing electrical noise. The inorganic part of the
diode passivation layer is disposed over steep sidewalls of the
photosensor diode. Often, the points at which the inorganic part of the
diode passivation layer is disposed are high stress areas in which
structural degradation can result in moisture penetration and
undesired electrical leakage through the diode passivation layer.
Thus, structural degradation of the diode passivation layer creates
higher electrical noise and a greater number of defective pixels in the
imager array.
Although SiNx as the inorganic part of the diode
passivation layer in sufficient thickness can provide an effective
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barrier to moisture penetration, use of SiNx can present processing
problems. For example, a thick layer of SiNx is susceptible to cracking
(both horizontally and vertically), thereby causing structural
degradation and decreased resistance to moisture penetration. Poor
adhesion may occur between SiNx and other layers, such as ITO
which may be overlaying the photodiode surface or acting as a
common electrode, or photoresist. The poor adhesion to photoresist
can result in poor dimensional control in processing steps after
deposition of the SiNx barrier layer, such as in the formation of vias to
provide contact to the photodiodes.
It is thus desirable that an imager array demonstrate
both a high degree of moisture resistance and structural robustness to
enable effective fabrication and operation of the array in a variety of
environments.
SUMMARY OF THE INVENTION
The present invention is directed to a high performance
solid state radiation imager having low noise components for
addressing pixels in the array.
In one embodiment of the present invention, an imager
comprises a contact pad that is particularly suited to connect to a
contact finger which, in turn, connects to scan and data lines for
addressing pixels of the imager. The contact pad comprises first,
second and third regions, each having a continuous gate contact
region which is overlayed by a continuous source-drain contact region.
The first and second regions further comprise a continuous conductor
comprising indium tin oxide (ITO) which overlays the source-drain
contact region.
In another embodiment, the imager comprises a low
noise data address line comprising an aluminum line deposited on a
field effect transistor structure. The data line is preferably completely
encapsulated by source-drain electrode material comprised of a
molybdenum layer. The encapsulation confines the grain boundary
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motion and minimizes exposure in subsequent processing steps of the
aluminum layer, thereby reducing the detrimental effects of array
fabrication steps on aluminum in the data line while retaining the
benefit of use of aluminum material to reduce the electrical resistance
of the data line.
In a further embodiment, the imager comprises a guard
ring that is typically maintained at a ground potential. The guard ring
typically forms a boundary region serving as a perimeter in the region
more distant from the array than the contact pads with at least one
corner and with one or more guard ring contact pads abutting the
perimeter. The guard ring has first and second regions each having a
continuous gate contact region overlayed by a continuous source-
drain contact region which, in turn, is overlayed by a continuous
conductor comprising ITO having upper and lower surfaces and
wherein the ITO conductor in the first region has its lower surface
disposed from the continuous gate contact by at least one dielectric
layer. The ITO conductor in the second region makes contact with the
continuous source-drain contact region, and a majority of the ITO
conductor in the first and second regions is overlayed by a barrier
layer. One of the first and second regions has a portion of the ITO
conductor free of the barrier layer and extending so as to electrically
connect to one or more guard ring contact pads.
In a still further embodiment, a solid state imaging device
comprises a photosensor array disposed on a substrate, the array
including a plurality of individually-addressable pixels. Each pixel
includes a photosensor and a TFT coupled thereto so as to selectively
electrically couple the photosensor to an~ address line when a voltage
is applied to a gate electrode in the TFT. In accordance with an
exemplary embodiment of this invention, the photosensor includes a
bottom contact pad disposed on a substrate, a photosensor island
disposed on the substrate in electrical contact with the bottom contact
pad, a multitier passivation layer, and a top contact layer. The
photosensor island has sidewalls extending from a base of the
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photosensor island upwardly to an upper surface extending between
the sidewalls. The top contact layer is in electrical contact with a
contact area typically comprising an inner portion of the upper surface
of the photosensor island; elsewhere the multitier passivation layer is
disposed between the top contact layer and the underlying
photosensor island and substrate. The multitier passivation layer
includes at least a first tier inorganic barrier layer and a second tier
inorganic barrier layer, the multitier passivation layer extending over at
least the photosensor island sidewalls.
The first tier inorganic passivation layer is typically
comprised of silicon oxide. This passivation layer is disposed at least
over the sidewalls of the photosensor island to provide enhanced
adhesion to the underlying diode surface. The second tier inorganic
passivation layer is a moisture barrier that typically comprises silicon
nitride and is disposed on the first tier inorganic passivation layer. In
other embodiments, a third tier inorganic passivation layer of silicon
oxide is incorporated so as to improve adhesion to the photoresist
used to pattern the inorganic part of the passivation layer. In a further
embodiment, a passivation layer comprises the second and third tiers
comprising silicon nitride and silicon oxide.
BRIEF DESCRIPTION OF THE DRAWINGS
The features of the invention believed to be novel are set
forth with particularity in the appended claims. The invention itself,
however, both as to organization and method of operation, together
with further objects and advantages thereof, may best be understood
by reference to the following description taken in conjunction with the
accompanying drawings in which like characters represent like parts
throughout the drawings, and in which:
Fig. 1 is a top view schematic representation of the
contact pad of the present invention having first, second and third
distinct electrical regions.
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Fig. 2 is composed of Figs. 2(a), 2(b), 2(c), 2(d), 2(e),
2(f) and 2(g) that illustrate a preferred method of forming the contact
pad of Fig. 1.
Figs. 3-6 illustrate the sequence of steps of the preferred
method for forming the data line also related to the present invention
having reduced electrical resistance.
Fig. 7 is a schematic of an imager related to the present
invention.
Figs. 8a and 8b are plan views of ground ring regions
related to the present invention.
Figs. 9 and 10 are cross-section views related to the
process associated with the imager of Fig. 7.
Figs. 11 and 12 are cross-sectional views of a
photodiode in accordance with one of the exemplary embodiments of
this invention.
Fig. 13 is an illustration of a representative multitier
passivation layer in a photosensor array completed in accordance with
this invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring to the drawings, Fig. 1 is a top view schematic
illustration of a contact pad 10 having a first region 12, a second
region 14, and a third region 16. The first, second and third regions
12, _ 14 and 16, respectively each have . a continuous gate contact
region 18 (shown in phantom) which is overlayed by a continuous
source-drain contact region 20 (also shown in phantom). As used
herein, "overlayed" and the like refer to relative positions of materials
and components in the imager array (e.g., one material deposited over
another, with or without intervening material layers) and does not
connote any limitation on orientation or use of the imager array. The
first and second regions 12 and 14 further comprise a continuous
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conductor 22 that typically comprises indium tin oxide (ITO) and which
overlays the source-drain contact region 20. A portion of the gate
contact region 18 in the second region 14 includes a first via 24
(shown in phantom) in the inorganic part of a diode passivation layer,
to be further described with reference to Fig. 2, which is surrounded by
a rectangular polyimide annular arrangement 26. The third region 16
preferably includes a second via 28 (also shown in phantom) in the
TFT gate dielectric over the gate contact region 18, to be further
described with reference to Fig. 2. The contact pad 10 further
includes a barrier layer (not shown in Fig. 1 but to be described with
reference to Fig. 2) having an edge 29. The barrier layer covers the
regions of the contact pads to the right of edge 29 as viewed in Fig. 1.
The first region 12, in operation, is connected to an
external device 11, more particularly, to a flexible connector 11 A from
the external device 11. The third region 16 serves as a means for
connecting to an array device 13. More particularly, one, or
alternatively, both the gate contact region 18 and source-drain 'contact
region 20 are continued (indicated by broken lines) so as to run to and
electrically connect to the array device 13, which may be an imaging
array, display array, or the like.
In the practice of the present invention it has been found
that of the conducting materials used in imager or display array
fabrication, use of indium tin oxide (ITO) is desirably in many respects
in that it is robust with regard to maintaining low electrical contact
resistance and experiencing minimum corrosion over long term
exposure to moisture. As used herein, long term exposure is meant to
represent weeks to years and the long term exposure is mimicked by
testing the imagers and display panels, related to the present
invention, under conditions of high temperature and relative humidity,
e.g., 85°C and 85% relative humidity for the periods of days to weeks.
Further, in the practice of the present invention it has
been found that a thin layer of ITO (e.g., having a thickness on the
order of 0.1 Nm) that does not have of the benefits of the present
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invention and that is used in imager or display array fabrication, is
insufficient to protect underlaying conducting material from corrosion
by exposure to moisture. The present invention is adapted to the use
ITO as its transparent electrically conducting material; additionally,
other related compounds are contemplated by the practice of the
present invention. The contact pad of Fig. 1 that utilizes ITO as an
electrically conducting material, but does not suffer prior art
disadvantages, may be further described with reference to Fig. 2
which is composed of views taken along lines 2-2 shown in Fig. 1
located in the first, second and third regions 12, 14 and 16
respectively.
Figure 2 is composed of Figs. 2(a) - 2(g) illustrating
steps involved in the formation of the contact pad of Fig. 1, particularly
suited for an imager. As used herein, the usage of the term
"formation" includes depositing of a material and, where applicable,
patterning array components by the removal of all or selected portions
of the deposited material. The method of Fig. 2 is concerned with the
fabrication of first, second and third regions 12, 14 and 16,
respectively, shown in Fig. 1 and also in Fig. 2. More particularly, Fig.
2 is segmented into the first, second and third regions 12, 14 and 16
so as to more clearly illustrate the formation of each of the illustrated
regions.
Fig. 2(a) illustrates the formation of the continuous gate
contact region 18, respectively, for an imager. The forming of gate
contact region 18, as well as the forming of other metal contact
regions or non-metal regions of Fig. 2, may be accomplished in a
manner known in the art, such as evaporation and sputtering of metals
such as Mo, Cr, Ta, Ti, AI, or combinations thereof.
Fig. 2(b) illustrates the formation of a first dielectric layer
30 over the gate contact region 18, but in addition thereto Fig. 2(b),
with reference to region 16, depicts that the dielectric layer 30 has
been removed from a region of the gate contact region 18 but leaving
the dielectric layer at the edge portions 32 and 34 of the gate contact
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region 18. The first dielectric layer 30 is often called the gate or TFT
dielectric layer. The removal of the first dielectric layer 30 provides
the via 28, previously mentioned with reference to Fig. 1 and
commonly referred to as a FET digdown via, that allows for the
source-drain contact region 20 to make good electrical contact with
the gate contact region 18. Further details in which vias, such as via
28, are formed are to be more fully described hereinafter with
reference to Fig. 6(c). The first dielectric layer 30 is removed from the
gate contact region 18 by appropriate means, such as by conventional
wet-etching in a solution comprising hydrofluoric acid. The first
dielectric layer 30 of Fig. 2(b) and edge portions 32 and 34 have a
typical thickness from about 0.1 Nm to about 0.5Nm comprising silicon
nitride SiNx or silicon oxide SiOx and are typically deposited by
plasma enhanced chemical vapor deposition (PECVD).
Fig. 2(b) further illustrates the formation of the
continuous source-drain contact region 20 onto the dielectric layer 30
of the first and second regions 12 and 14, onto the central part of the
gate contact region 18 in the third region 16 and overlapping onto the
edge portions defined by the edge portions 32 and 34 of the first
dielectric layer 30. The source-drain contact region 20 preferably is
comprised of molybdenum which is patterned by appropriate means,
such as wet-etching in a solution available from Cyantek, Inc., carrying
the tradename "Cyantek 12S." The molybdenum has a thickness in
the range from about 0.1 Nm to about 1.ONm.
Fig. 2(c) illustrates the formation of a TFT passivation
layer 36 over the source-drain contact region 20. The TFT passivation
layer 36 may be of a material selected from the group comprising SiNx
and SiOx and have a thickness in the range from about 0.1 Nm to
about I.ONm.
It has been found that these FET digdown vias 28 of
Figs. 2(b) and 2(c), having steps, can be the cause of excessive wet
etching under the patterning photoresist of the first or diode digdown
vias 24, to be described with reference to Fig. 2(d), along the steps of
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the second or FET digdown via 28. Additionally, it has been found
that the steps of the FET digdown vias 28 can lead to other problems
such as degrading the adhesion of layers overlaying the TFT dielectric
layer 36 due to the additional topography. In the practice of the
invention, in order to provide for a reliable electrical contact, the FET
digdown vias 28 were only formed in the third region 16. Additional
embodiments of the present invention addressed to reduce the
adhesion difficulties of dielectric layers are to be further described with
reference to Figs. 11-13.
Fig. 2(d) illustrates the formation of a diode passivation
layer 38 over the TFT passivation layers 36, except in region 14 which
shows that the TFT and diode passivation layers 36 and 38
respectively have been removed from a predetermined central area
corresponding to the second (or diode) digdown via 24 also shown in
Fig. 1 in such a manner so as to expose the central region of the
source-drain contact region 20 and to leave portions 40 and 42 in the
remaining diode passivation layer 38. Layers 36 and 38 are etched in
the same patterning step.
The diode passivation layer 38 in one embodiment
comprises silicon nitride having a thickness in the range between
about 0.5 microns to about 1.5 microns. The diode passivation layer
38, in a preferred embodiment, comprises a three layer structure
consisting of an underlying material of SiOx having a thickness of
about 20nm to about 50nm, an intermediate layer of SiNx having a
thickness of about 0.5Nm to about 1.SNm, and a topmost layer of SiOx
having a thickness of about 20nm to about 50nm. The intermediate
layer SiNx acts as a moisture barrier whip the underlying and topmost
SiOx layers have been found to enhance adhesion of the three layer
diode passivation layer to its contacting elements, such as shown in
Fig. 2. Further advantages of a multilevel, multitier passivation layer
are to be further described hereinafter with reference to the
embodiment of Figs. 11, 12 and 13.
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' The three layer structure of the diode passivation layer
38 and the underlying TFT passivation layer 36 in region 14 may be
dry etched, wet etched or etched by a combination of timed wet etch
followed by timed dry etch. The dry etching may be selected from the
processes comprising the group of plasma, barrel or reactive ion
etching incorporating Flourine, Chlorine, or a combination thereof.
Fig. 2(e), in particular region 14, illustrates the formation
of a polymer coating comprised of oppositely located first coating
portion 48 and second coating portion 50 positioned to overlap via
edge portions 40, 42, 44, and 46. The polymer coating typically
comprises a preimidized polyimide (PI) having a trade name of "OCG
Probromide 286" made available by Olin Ciba-Geigy and having a
thickness from about I.ONm to about 2.ONm deposited by a spin or a
meniscus coating process. It is preferred that the preimidized
polyimide (PI) be formed into a rectangular arrangement 26,
previously mentioned with reference to Fig. 1, (yielding opposite first
and second portions 48 and 50 in cross-section respectively having
sloped sidewalls 48A and 48B; and 50A and 50B as shown in Fig.
2(e)), the inside of which helps define the electrical contact between
the ITO layer and source-drain contact region 20 to be further
described with reference to Fig. 2(f), in particular, in region 14 thereof.
The PI is dry-etched in a plasma comprising 02 to pattern the coating
to form sloped sidewalls 48A, 48B, 50A and 508, having slopes in the
range of about 30° to about 60° with respect to the upper
surface of
source-drain contact region 20.
Fig. 2(f) illustrates the formation of a layer 52 of ITO in
region 12 over the diode passivation layer 38 therein and also over
the remaining exposed central region 24 (diode digdown via) of the
source-drain contact region 20 in the second region 14 and also over
the preimidized polyimide portions 48 and 50, as well as some of the
diode passivation layer 38 of the second region 14. The layer 52 is
preferably formed by evaporation or sputtering and has a thickness of
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about 50 to about 200 nanometers. The ITO typically is wet-etched in
a solution comprising hydrochloric acid.
The ITO layer 52 is the top most layer in the first region
12 in order to be allowed, by appropriate means, to make contact with
the flexible connector 11 A of equipment 11 shown in Fig. 1. To
minimize the chance of corrosion, the layer of ITO 52 is vertically
isolated from underlying conductive materials, such as gate contact
region 18 and source-drain contact region 20 by dielectric layers, that
is, preferably by the TFT passivation layer 36 and the diode
passivation layer 38.
The preimidized polyimide portions 48 and 50 having
sloped sidewalls 48A and 48B; and 50A and 50B respectively,
described with reference to Fig. 2(e) of region 14, help define the
contact between the ITO layer 52 and source-drain contact region 20.
The inside and outside edges, corresponding to the sloped sidewalls
48A and 48B; and 50A and 50B, of the preimidized polyimide .portions
48 and 58, formed into a rectangular arrangement 26 discussed with
reference to Fig. 2(e) and shown in Fig. 1, enclose the sidewalls (40
and 42) formed in the diode passivation layer 38 and the sidewalls (44
and 46) of the TFT passivation dielectric layer 36, thereby, smoothing
the profile at that sidewall for the ITO layer 52 so that the ITO layer 52
is highly reliably electrically continuously across the step formed in the
via 24. Because the sidewalls 44 and 46 are sealed by the polyimide
(preimidized polyimide portions 48 and 50), their exact sidewall slopes
are not critical, which eases greatly a difficult task of forming smoothly
and uniformly sloped sidewalls over a relatively large area. More
particularly, a typical imager with an active area greater than l0cm by
l0cm may have over a thousand contact pads, each requiring sealing
which would otherwise present a difficult formation problem except for
the benefits of the present invention.
Fig. 2(g) illustrates the formation of a barrier layer 58
covering the second and third regions 14 and 16 respectively. As
previously mentioned, the barrier layer 58 covers all of the contact pad
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to the right of the barrier edge 29 as viewed in Fig. 1. The barrier
layer 58 may have a thickness of about 0.5 to about 2.0 microns and is
comprised of a material selected from the group comprising SiNx and
SiOx and combinations thereof. The barrier layer 58 may be
5 deposited by a plasma etched chemical vapor deposition process.
The barrier 58 in region 14 seals the edges of the steps of the
structure, e.g., the gate contact region 18 therein and the source-drain
contact region 20 therein that are distant from the array, that is, the
radiation array related to the present invention, because the edge
10 portions of the elements 18 and 20 are the most susceptible to
moisture permeation and to being attacked during etching that is
performed after the steps {related to elements 18 and 20) are formed.
Similarly, the layer 52 of ITO in the second region 14 extends laterally
past the edges of the gate contact region 18 therein and source-drain
contact region 20 therein and therefore is desired to be and is sealed
by the barrier layer 58.
Further, the barrier layer 58 placed in region 14 provides
sealing which is beneficial because of the susceptibility of the
preimidized polyimide absorbing some moisture, and because region
14 may lay outside a protective ring of material (not shown) that
encloses the active area of an imager or display array related to the
present invention.
In the practice of the present invention it has been found
that it is desirable for the bottom layer of the diode passivation layer
38 to preferably have a thickness of about 1 micron, with thicknesses
in the range of 0.5 to about 2.0 microns thick acceptable, in order to
best protect the photodiodes of an associated array, known in the art,
from moisture. Without such protection, the photodiodes may leak
under reverse bias with exposure to high humidity, possibly
compromising the usefulness of an imager related to the present
invention.
To overcome such detrimental reverse bias leakage, it
has been found that a layer of approximately 0.1 micrometers of ITO
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does not make reliable contact to the underlying conductive material,
usually source-drain contact region 20. This unreliable contact occurs
at the edge of the diode digdown via, such as the via 24 of Fig. 1.
This unreliable contact pad diode digdown via also includes about 0.5
microns of the TFT passivation material 36. Accordingly, and in a
manner more fully discussed hereinbefore with reference to Figs. 2(e)
and 2(f), in the practice of the present invention the preimidized
polyimide portions 48 and 50 advantageously help define the contact
between the indium tin oxide layer 52 and the source-drain contact
region 20 so as to provide a highly reliable contact therebetween.
It should now be appreciated that the practice of the
present invention provides for a contact pad having three distinctive
electrically connected regions. In one application related to an
imager, an external device 11 of Fig. 1 is connected to the outermost
contact pad region 12 having the ITO layer exposed but with a thick
layer of dielectric between it and the underlying conductive layers,
such as 18 and 20 of Fig. 2(g). As used herein, "exposed" and the like
refers to a portion of the material being exposed to the ambient
environment surrounding the pixel array, the array itself, however, may
be disposed in an enclosure such that the ambient environment
immediately surrounding the array is within such enclosure. In the
region 14, the ITO layer 52 of Fig. 2(g) makes contact to underlying
source-drain contact region 20 by transversing the outer and inner
portions of preimidized polyimide portions 48 and 50. In the region
closest to the array, that is, the region 16, the source-drain contact
region 20 is in contact with the gate contact region 18 of the thin film
transistors. The regions 14 and 16 are covered by a barrier dielectric
layer 58 as illustrated in Fig. 1 with regard to edge 29. The resulting
structure of the contact pad 10 of Fig. 1 forms reliable contact, while
allowing the formation of an imager that is highly resistant to
degradation due to moisture by either contact pad corrosion or
photodiode leakage.
RD-26046 CA 02247717 1998-o9-Zi
-18-
'Another embodiment of a high performance imager
comprises an address line, more particularly, a data line the
resistance of which is reduced by patterning an aluminum line on top
of a FET structure, with the formed data line preferably being
encapsulated and which data line may be further described with
reference to Figs. 3-6 that illustrate a preferred method of forming the
data line.
The practice of the. present invention incorporates
aluminum into data lines that are commonly interconnected throughout
imagers and display arrays in a manner known in the art. The
aluminum data lines of the present invention are advantageous
because of their low resistance which reduces the imager electronic
noise related to data line resistance and also because of the minimum
additional depositions and photolithographic pattern steps of the
present invention, the advantages of the use of an aluminum material
for a data line are more fully realized.
Aluminum is known to have excessive . grain boundary
movements upon being exposed to temperatures typically used in
imager fabrication processes, i.e., 200°C to 250°C. This grain
boundary movement may disadvantageously lead to the growth of
aluminum hillocks on the order of 1 micron which, in turn, may readily
cause shorts between the aluminum material and other layers in the
imagers and/or display arrays.
It is further known that in the formation of source-drain
metals, some of which have been previously discussed with reference
to Figs. 1 and 2, it is a complication to wet etch molybdenum,
comprising the source-drain metal, at an elevated temperature
because the molybdenum wet etch rate increases with temperature,
and the effective process control of the length of source-drain metal is
more difficult to maintain, especially if the molybdenum is relatively
thin, that is, 200nm or less in thickness due to the short etch time.
Further, if aluminum is present in the process, in order to avoid a
differential etch rate between the aluminum and the molybdenum,
RD-26046 CA 02247717 1998-o9-Zi
-19-
which wouldLlead to undercut of one of these layers relative to the
other, both materials need to be etched at about 55°C where the
molybdenum rate is about 7000 angstroms per minute. The etching
may be accomplished by using a solution carrying the tradename
"Cyantek-12S" made available from Cyantek, Inc., and acceptable
performance thereof can be achieved from about 40°C to about
60°C.
The temperature of 55°C is preferred and taken into account in the
practice of the present invention. The present invention forms the
data lines comprising an aluminum rayer and may be further described
with reference to Figs. 3-6, wherein Figs. 3, 4, 5 and 6 are respectively
comprised of Figs. 3(a), 3(b); 4(a) and 4(b); 5(a) and 5(b); and 6(a),
6(b) and 6(c).
Fig. 3(a) illustrates a gate electrode 60 (extending as a
finger from a scan line in the pixel array); Fig. 3(b) is a cross-sectional
view taken along line 3(b)-3(b) of Fig. 3(a) that illustrates that the gate
electrode 60 is formed on a substrate 62. The formation of the gate
electrode 60,, as well as other materials shown in Figs. 4-6, is
accomplished in a manner known in the art and described
hereinbefore.
Fig. 4(a) illustrates the gate electrode 60 as being laid
over by a field effect transistor (FET) island 64; Fig. 4(b) is a cross-
sectional view taken the line 4(b)-4(b) of Fig. 4(a).
Fig. 4(b) illustrates the formation of the dielectric layer 66
so as to cover at least the gate electrode 60. The dielectric layer 66 is
selected from the group of materials comprising SiOx and SiNx that
has a typical thickness such as that previously described for the
dielectric layer 30 of Fig. 2(b). Fig. 4(b) further illustrates the
formation of a substantially intrinsic amorphous silicon (i-Si)layer 68
over the dielectric layer 66. The (i-Si)-layer 68 is overlayed by a n+
type doped (n+-Si) layer 70 having a bottom boundary 72 indicated in
phantom. As seen in Fig. 4(b), the FET island 64 includes elements
68, 70 and bottom boundary 72. The FET island 64 has first and
second ends 64A and 64B respectively. The i-Si layer 68 is about 0.1
RD-26046 CA 02247717 1998-o9-Zi
-20-
to 0.5Nm in thickness and the n+-Si layer 70 is about 20 to 100 nm in
thickness.
Fig. 4(b) further illustrates the deposition of a first
conductive layer 74 of molybdenum over the FET island 64. The
molybdenum layer 74 serves as the base of the data line and has a
thickness in the range of about 0.02 to about 0.1 microns. The
molybdenum layer 74 also serves as a protective layer to minimize
interaction of the aluminum with the underlying silicon. It is desirable
that the molybdenum layer 74 be completely inside the ends 64A and
64B of the FET island 64 so as to minimize the chances of shorts in
this region where the data line may cross, for example, over a scan
(gate electrode 60) line, which can result if the moly (Mo) is wet etched
a sufficiently long time before the silicon is etched. The silicon
typically is etched by reactive ion etching (RIE) in a plasma containing
CI , F, or a halogen combination.
Fig. 5(a) illustrates a data line 76 formed of aluminum
and having a thickness of about 0.5 to about 1.0 microns ~ that is
deposited on the FET island 64. It should be noted that the layer of
aluminum is placed over the layer of molybdenum without the need for
forming contact holes for the aluminum. This eliminates a prior art
step that required holes to be formed into insulating material. The
forming of the aluminum layer is most clearly shown in Fig. 5(b) which
is a cross-sectional view taken along line 5(b) - 5(b) of Fig. 5(a).
Fig. 5(b) shows the molybdenum layer 74 as only
remaining under the layer of aluminum 76. The molybdenum layer 74
is removed from the amorphous silicon layer 68 except for the region
under aluminum layer 76. The removal is preferably accomplished by
an etch accomplished by wet etching using a phosphoric acid and
nitric acid mixture, such as that made available from Cyantek, Inc.,
and carrying their tradename "Cyantek-12S." The wet etching is
accomplished at an elevated temperature in the range from about
40°C to about 60°C so that the aluminum and the underlying
molybdenum etch at substantially the same rate. In this manner, the
RD-26046 CA 02247717 1998-o9-Zi
-21 -
molybdenum' layer 74 does not undercut the aluminum layer 76
thereby preventing a sidewall profile that would be difficult to seal with
subsequent layers, such as the passivation layer 36 of Fig. 2(c). At
this point the FET digdown via 28 of Fig. 1 is commonly formed in the
contact region and the source-drain electrode is deposited and
patterned and is further described with reference to Fig. 6.
Fig. 6(a) illustrates a structure in the array comprised of
the gate electrode 60, the FET island 64, and a source-drain metal
electrode with first and second portions 78 and 80. The aluminum
layer 76 is shown in phantom because it is under the first portion 78 of
the source-drain metal electrode. The first and second portions of the
source-drain metal electrodes 78 and 80, respectively, may be further
described with reference to Fig. 6(b) which is a cross-sectional view
taken along line 6(b)-6(b) of Fig. 6(a).
The source-drain metal electrode portion 78 of Fig. 6(b)
(same as layer 20 of Fig. 2) is preferably comprised of a second layer
of molybdenum that is deposited so as to completely cover the layer of
aluminum 76 and some of the FET island 64 at the first opposite end
64A adjacent the layer 76 of the aluminum. The first portion 78, as
well as the second portion 80, has a thickness of about 0.2Nm to about
0.5Nm. This first and second portions 78 and 80 may be etched in a
manner as discussed for layer 20 of Fig. 2.
Fig. 6(b) further illustrates that the second portion 80 of
source-drain metal electrode covers at least the second end portion
64B of the FET island 64 where it extends to form the bottom contact
of the photodiode. Because of the aluminum layer 76, a center layer
of source-drain metal electrode having portions 78 and 80 with a
thickness toward about 0.2Nm, can be used, which improves the
patterning of the back channel region 82 to be described with
reference to Fig. 6(c).
The FET island 64 is further subjected to a process of
etching n+-Si usually by RIE in a plasma containing CI, F, or a
RD-26046 CA 02247717 1998-o9-Zi
-22-
combination ,of halogens, from the top layer 70 to form the back
channel 82 of the thin field transistor. The first and second portions
78 and 80 of the source-drain metal electrode are formed with a gap
between them which helps define the back channel 82 of the TFT.
The source-drain metal electrode layer 80 and may be further
described with reference to Fig. 6(c). The etching is accomplished in
the region separating the first (78) and second (80) portions of source-
drain metal electrode so as to provide an electrically isolated path
therebetween which n+-Si, being conductive, would otherwise short.
As seen in Fig. 6(c), the top layer 70 is removed frorr~ the region
between the first (78) and second (80) portions of source-drain
electrodes and, furthermore, the removal extends to below the
boundary line 72 of the layer 70. The etching is then covered with a
dielectric (not shown) typically selected from the group comprising
SiOx and SiNx.
The process illustrated in Figs. 3-6 differs from the prior
art in that the molybdenum layer 74 is removed from the channel
region 82 of the thin film transistor (TFT). However, this removal of
Mo does not degrade the operation of the thin film transistor because,
by using wet strips of photoresist during patterning of the FET island
64, such as that shown in Fig. 5(a), and also during patterning of the
digdown vias 28 of Fig. 2(c), the contact resistance of the n+ Si is not
degraded by being disadvantageously exposed to OZ plasma (an
alternate method to remove photoresist). The use of wet strips allows
the contact resistance to the TFT to be unaffected by the practice of
the present invention. The wet stripping can be done using, for
example, PRS series resist strippers, available from J.T. Baker
Company, at a temperature in the range between about 80° to about
90°C.
The advantage of the present invention is to incorporate
an aluminum data line into the process for forming imagers with the
addition of only one deposition step of aluminum and only one
photomask step of patterning aluminum. Generally, two depositions
RD-26046 CA 02247717 1998-o9-Zi
-23-
and two photomasks steps are required, one for an insulating
dielectric layer in which contact holes for the aluminum are formed,
and a second set of steps for the aluminum. Further, by overlaying the
aluminum layer 76 completely with the molybdenum layer 78, the
aluminum is encapsulated so that its shape is fixed and so that the
grain boundary mobility will not lead to shorts or other defects
previously discussed. Additionally, the process of Figs. 3-6
substantially reduces the risk of corrosion to the overlaying layers or
changes in the etch rate of the quality of subsequent steps, e.g., etch
rate changes may undesirably be altered due to the presence of
aluminum. The risk of AI affecting the n+ Si removal by RIE is reduced
because the AI is not exposed during the n+ Si removal of Fig. 6(c).
More particularly, the aluminum is encapsulated during the n+-Si
removal.
Another aspect of the process of Figs. 3-6 is that the
aluminum data line 76 is narrower than prior art data lines such as that
could be established by the FET island 64 because of the extension of
FET island 64 past the edges of aluminum layer 76; but the higher
conductivity of A1 compared to other useful metals like, molybdenum,
more than compensates for this narrowing in lowering the data line
resistance.
If desired, the aluminum data line illustrated in Fig. 5(b)
could be a two layer structure of aluminum with a thin layer (e.g.,
about 20nm to about 50nm) of molybdenum on top of layer 76. In
such an arrangement, the molybdenum would tend to suppress
aluminum hillock formations especially if it is deposited in the same
vacuum pumpdown as that typically occurring during aluminum
deposition.
It should now be appreciated that the practice of the
present invention provides for data lines comprising a layer of
aluminum which reduces the electrical resistance of the data line, and
because of the practice of the present invention, the aluminum is
encapsulated by a molybdenum metal, such as layer 78, and the layer
RD-26046 CA 02247717 1998-o9-Zi
-24-
76 of aluminum does not manifest hillock growth once the layer 78 has
been formed'thereto.
All of the inventive features hereinbefore described with
reference to Figs. 1-6 are well adapted for use in a further
embodiment of an imager 84 as illustrated in Fig. 7. The imager 84 is
typically formed on a substantially flat substrate 86, typically glass.
The imager 84 comprises an array 88 of pixels with photosensitive
elements, preferably photodiodes, each of which has an associated
switching element, preferably a TFT. Both devices (photodiodes and
TFT) preferably comprise a-Si. This light sensitive region of the array
is typically referred to as the active region of the array. The array 88
is addressed around its perimeter by a plurality of row and column
address lines having contact pads 90 and 92 which extend along the
array 88 as indicated by the dot representations of Fig. 7.
In operation, the voltage on the row lines, and hence the
TFTs, are switched on in turn, allowing the charge on that scanned
line's photodiodes to be read out via the column address lines. The
row address lines are commonly called the scan lines and the column
address lines the data lines. The data lines may be those yielded by
the practice of the invention related to Figs. 3-6. The address line
thus are disposed in an active region of the pixel array 88, with contact
finger 94 extending from the active region towards the edge of the
substrate. The contact finger 94, previously discussed with reference
to Fig. 1, electrically connects to contact pads, such as row contact
pads 90 and column contact pads 92, which, in turn, can be
electrically connected to an external device 13 of Fig. 1. As more fully
discussed in U.S. Patent 5,389,775 issued February 14, 1995 of
Kwasnick et al, the contact pads, such as 90 and 92, include contact
pads connected to the common electrode of the array.
Outside the contact pads, such as contact pad 90, a
guard ring 98 is typically disposed around the perimeter of the pixel
array. Ground ring 98 is typically maintained at ground potential
during operation and serves the purpose of protecting the array from
RD-26046 CA 02247717 1998-o9-Zi
-25-
electrostatic discharge during the formation of the imager, and during
connection of the imager to external circuitry, and acts as a ground
potential for the imager 88. The guard ring 98 has one or more guard
contact pads 99 spaced apart from each other around the inner side of
the perimeter of the guard ring 98 as shown in Fig. 7. The guard ring
98 preferably forms a boundary region serving as a perimeter in the
region more distant from the array 88 than the contact pads 99 and
with at least one corner in the perimeter.
The imager guard ring 98, without the benefits of the
present invention, suffers from similar corrosion protection
considerations as the contact pad previously described with reference
to Figs. 1 and 2. That is, for best electrostatic discharge protection
conducting material from the guard ring 98 is exposed to ambient after
ITO formation, but the structure should be made resistant to corrosion
to avoid imager degradation. A primary feature of the present
invention is that electrical contact is not directly made to the guard ring
98 but instead to contact pads 99 connected to the guard ring 98. The
guard ring 98 may be further described with reference to Fig. 8
composed of Figs. 8(a) and 8(b) which are plan views of the guard
ring 98 regions 100 and 102, respectively, shown in Fig. 7, and
wherein region 100 is shown as having a guard ring contact pad 99
within its boundaries, and region 102 is shown as preferably having an
L shape.
Fig. 8(a) shows in cross hatch the barrier layer 58,
exposing some of the ITO layer 52, all previously discussed with
reference to Fig. 2, on both sides of the ground ring 98. Fig. 8(a)
further illustrates the ITO layer 52 as having an extension portion 103
free of the barrier layer 58 and that extends to the right (as viewed in
Fig. 8(a)) and that is interconnected to a guard contact pad 99 (also
shown in Fig. 7). To minimize the change of bias-enhanced corrosion,
guard contact pads 99 are kept removed from regions 102 where ITO
layer 52 makes contact to underlying conductive materials and is thus
more susceptible to electrochemically-induced corrosion. Further, the
RD-26046 CA 02247717 1998-o9-Zi
-26-
extension portion 103 is not placed in the second region 102 but
rather is preferably located away from the second region 102 by a
distance of at least 1 cm.
Fig. 8(b) shows in cross hatch the barrier layer 58, and
preimidized polyimide portions 48 and 50 cross hatched in the
opposite direction to barrier layer 58. Region 102 of Fig. 8(b) differs
from region 100 of Fig. 8(a) in having the polyimide annulus 26 and
diode digdown via 24; preimidized .polyimide portions 48 and 50 are
part of the polyimide annulus 26. The portion 26 of Fig. 8(b) is shown
for the upper portion thereof, but in actuality portion 26 preferably
extends down to the corner of the guard ring 98 as generally by the L-
shape illustrated in Fig. 7 for region 102. Although it is preferred,
region 102 need not extend into the corner of the guard ring 98. More
particularly, in order to minimize corrosion of region 102 associated
with the potential difference between ground ring 98 and contact pads
90 and 92 running along a substantial portion of each side of the array
88, region 102 is preferably confined within about 1 mm to about 1 cm
of a comer of the guard ring 98.
The process steps related to regions 100 (Fig. 8(a)) and
102 (Fig. 8(b)) may be further described with reference to Figs. 9 and
10, respectively, which illustrate the process after the related step is
performed. Fig. 9 is composed of Figs. 9(a), 9(b), 9(c), 9(d), 9(e), 9(f)
and 9(g) respectively similar to Figs. 2(a), 2(b), 2(c), 2(d), 2(e), 2(f)
and 2(g) and illustrating the same reference numbers thereof.
Similarly, Fig. 10 is composed of Figs. 10(a), 10(b), 10(c), 10(d),
10(e), 10(f) and 10(g) respectively similar to Figs. 2(a), 2(b), 2(c), 2(d),
2(e~, 2(f) and 2(g) and illustrating the same reference numbers
thereof.
In general, Figs. 9(a) and 10(a) illustrate the formation of
the gate contact region 18 for regions 100 and 102 respectively. Figs.
9(b) and 10(b) illustrate the formation of the source-drain contact
region 20 for regions 100 and 102 respectively and also illustrate the
formation of edge portions 32 and 34 of the dielectric layer 30. Figs.
RD-26046 CA 02247717 1998-o9-Zi
_27_
9(c) and 10(c) illustrate the deposition of the TFT passivation
dielectric layer 36 for regions 100 and 102 respectively associated
with the formation of the photodetector diode of the array 88 of Fig. 7.
Figs. 9(d) and 10(d) illustrate the formation of the diode passivation
bottom layer 38 for regions 100 and 102. Fig. 10(e) illustrates the
formation of the preimidized polyimide portions 48 and 50 of region
102 having sloped sidewalls 48A and 48B; and 50A and 50B
respectively. Figs. 9(f) and 10(f) illustrate the formation of the ITO
layer 52 for regions 100 and 102 serving as a common electrode for
the array 88 of Fig. 7. It should be noted that the ITO layer 52 has an
extension 103 previously described with reference to Fig. 8(a). Figs.
9(g) and 10(g) illustrate the formation of the barrier layer 58 for
regions 100 and 102. Figs. 9 (g) and 10(g) differ from Fig. 2(g) in that
the barrier layer 58 shown in Figs. 9(g) and 10(g) is placed onto the
ITO layer 52 so as to leave exposed regions 54 and 56 thereof. The
performance of the guard ring 98 is enhanced by having these regions
54 and 56 exposed to ambient.
It should now be appreciated that the present invention
provides a guard ring 98 having guard ring contact pads 99 all
generally illustrated in Fig. 7 and has the regions 100 and 102
particularly illustrated in Fig. 8(a) and 9 and 8(b) and 10, respectively,
in which electrical contact for the guard ring 98 is not made directly
thereto, but instead to the guard ring contact pads 99 connected to the
guard ring 98, thereby, safeguarding the guard ring 98 from the
detrimental effects caused by humidity.
A still further embodiment of the present invention is
illustrated in Fig. 11. A photosensor element such as a photodiode
104 in accordance with this invention comprises a substrate 106, a
bottom contact pad 108, a photosensor island 110, a multitier
passivation layer 112, a top contact layer 114 and a FET passivation
layer 115 having end portions 115A and 1158 that overlap the bottom
contact pad 108 in a manner similar to portions 32 and 34 of Layer 30
overlapping the gate contact region 18 of Fig. 2. In operation,
RD-26046 CA 02247717 1998-o9-Zi
_ 28 .
photodiode 104 is exposed to actinic incident radiation 104A which
generates mobile charge in the body of the photodiode 104. In a
common arrangement, photodiode 104 is one of a number of
photodiodes in a photosensitive array 116 in rows and columns on
substrate 106 (see Fig. 13). For ease of describing the invention,
other elements that may be formed on substrate 106 along with the
photodiode 104, such as address lines (commonly in a matrix of scan
and data lines) and TFTs to control switching on these lines between
photodiodes are not shown in Figs. 11-13, but may be the type
previously described with reference to Fig. 7. Alternatively, many
photodiodes may be formed on substrate 106 and electrically
connected to switches and other processing circuits located off the
substrate 106, or to diode switches in each pixel.
Photosensor island 110 comprises light absorptive
semiconductive material such as a-Si, and may comprise layers (not
shown) of silicon doped of a selected conductivity (i.e., n-type or p-
type) to provide the desired diode electrical properties and respective
electrical contact to bottom contact pad 108 and top contact layer 114.
Amorphous silicon and related materials are typically deposited by
plasma enhanced chemical vapor deposition (PECVD) or similar
methods and then patterned, for example by etching, to form the
desired island structure on substrate 106. Photosensor island 110 is
disposed between top contact layer 114 and bottom contact pad 108
such that a selected bias voltage is applied across the photosensor
body; photosensor island 110 is typically mesa-shaped, having
sidewalls extending upwardly and inwardly from a base 118 of
photosensor island 110 towards an upper surface 120 disposed
between sidewalls 122. Top contact layer 114 comprises a
substantially transparent conductive material such as indium tin oxide
(ITO) (previously described with reference to Figs. 1 and 2) or the like.
Bottom contact pad 108 and top contact layer 114 serve as the
electrodes in the photodiode to establish the electric field across the
device (to allow the aforementioned charge to be collected). Charge
generated in the photodiode as a result of the absorption of optical
RD-26046 CA 02247717 1998-o9-Zi
-29-
photons in the semiconductive material is collected at a selected
electrode that is periodically "read" or measured, or equivalently,
decreases the applied bias between bottom contact pad 108 and top
contact layer 114 at which time the bias voltage across the photodiode
is reset to its selected value.
Bottom contact pad 108 is typically disposed on
substrate 106 and typically comprises an electrically conductive
material that has good electrical contact with the material of
photosensor island 110. Alternatively, bottom contact pad 108 may be
disposed on a dielectric layer or on other materials (not shown)
disposed on the substrate 106. Typical materials from which bottom
contact pad 108 is formed include molybdenum or chromium with
thickness of about 0.1 to about 1.0 microns. Bottom contact pad 108
is connected to switching and processing circuits, which are not
illustrated in Figs. 11-13, that allow the charge generated by the
photodiode in response to incident radiation to be measured.
Photodiode 104 with thickness of 0.5 to 2.0 microns or
more typically comprises the multitier passivation layer 112 disposed
under top contact layer 114 except at regions as shown in Fig. 11
where the top contact layer 114 is disposed in electrical contact with
an underlying and preferred (but not required) ITO strap 130 of
photosensor island 110. In accordance with an embodiment of this
invention, multitier passivation layer 112 comprises a first tier
inorganic dielectric layer 132 which makes a good quality bond with
ITO strap 130, a second tier inorganic moisture barrier layer 134, and
a third tier organic dielectric layer 136. Inorganic dielectric layer 132
extends at least over sidewalls 122 of photosensor island 110,
typically extends beyond sidewalls 122 at the base 118 of photosensor
island 110, and typically additionally extends over at least a portion of
upper surface 120, as illustrated in Fig. 11. For the embodiment of the
invention devoid of the ITO strap 130, the first tier inorganic dielectric
layer 132 may be removed so that the multitier passivation layer 112
comprises the second and third tier layers 134 and 136 respectively.
RD-26046 CA 02247717 1998-o9-Zi
-30-
The multitier layer 112 of Figs. 11-13 has many of the
characteristics of the passivation layer 38 of Figs. 1 and 2. First tier
inorganic barrier layer 132 of the multitier layer 112 comprises silicon
oxide and has a typical thickness in a range between about 0.005
microns and 0.05 microns. The silicon oxide comprising first tier
inorganic barrier layer 132 is typically deposited in a plasma enhanced
chemical vapor deposition (PECVD) process. Silicon oxide deposited
in this process provides improved adhesion relative to SiNx and
conforms well to the underlying sidewalls 122. Enhanced adhesion
between inorganic barrier layer 132 and the underlying and preferred
ITO strap 130 on upper surface 120 provides improved dimensional
control of the via necessarily formed in this dielectric so that the
photodiode top may be contacted. Additionally, the silicon oxide
provides a robust moisture barrier and is resistant to solvents, such as
gamma butyrolactone, which may be present in the array from the
deposition of polyimide.
The second tier inorganic moisture barrier layer 134
comprises silicon nitride having a thickness in a range between about
0.5 microns and 1.5 microns. The silicon nitride comprising the
second tier inorganic dielectric barrier layer 134 is typically deposited
on first tier inorganic dielectric layer 132 in the same PECVD process.
The second tier inorganic dielectric layer 134 forms a barrier layer
having a low pinhole density and is relatively thick so that it is highly
resistant to penetration by moisture; the SiNx is further readily
disposed by PECVD so as to conform to the topography of the diode
sidewall 122 and thus acts as a good moisture barrier. This protection
is of particular importance on sidewalls 122, which otherwise present
relatively large surfaces that are subject to degradation from exposure
to moisture over time and can become the source of considerable
charge leakage from the device.
In an alternative embodiment of this invention illustrated
in Fig. 12, a photodiode 138 comprises a multitier passivation layer
112 having a fourth tier inorganic dielectric layer 140 sandwiched
RD-26046 CA 02247717 1998-o9-Zi
-31 -
between the second (134) and third (136) tiers. Fourth tier inorganic
dielectric layer 140 comprises silicon oxide. Such a layer typically has
a thickness in a range between about 0.005 microns and about 0.05
microns; except as noted herein, the device of the alternative
embodiment is otherwise the same as that described elsewhere in the
specification with respect to the multitier passivation layer comprising
at least two inorganic dielectric layers. It has been noted that SiOx
provides improved adhesion to ITO relative to SiNx, and photoresist
has improved adhesion to SiOx relative to SiNx. Thus, during etching
of the photodiode top contact via, dimensional control is very good.
Third tier organic dielectric layer 136 is disposed over
substrate 106 and inorganic barrier layers 132, 134 and 140. More
particularly, with reference to Fig. 12, third tier dielectric layer 136 is
disposed over fourth dielectric layer 140, and with reference to Fig. 11,
third tier dielectric layer 136 is disposed over second tier dielectric
layer 134. Dielectric layer 136 is disposed in a way so that it overlaps
and seals the edges of the multitier passivation layer 112 in such a
manner that top contact layer 114 makes good electrical contact with
the ITO strap 130. The dielectric layer 136 has a shape similar to the
preimidized polyimide portions 48 and 50 having sloped sidewalls 48a
and 48b; and 50a and 50b (shown in Fig. 2(e)) so as to define good
electrical contact between the top contact layer 114 and ITO strap 130
in a manner similar to that previously described with reference to Fig.
2(f)). Organic dielectric layer 136 typically comprises a polyimide and
has a typical thickness in a range between about 1.0 microns and
about 2.0 microns deposited by a spin or a meniscus coating process.
It is desirable that the top surface of organic dielectric layer 136 be
reasonably smooth so that top contact layer 114 deposited thereover
will be of high integrity. Dielectric layer 136 is thermally stable, that is,
the polyimide structure does not undergo chemical decomposition or
excessive swelling or shrinking that would cause cracks or lifting of the
layer 136 resulting in the layer 136 losing its dielectric properties or
breaking the structural integrity of the layer 136.
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Top contact layer 114 is disposed over organic dielectric
layer 136 and is in electrical contact with photosensor island 110 at
contact area 130 for both of the embodiments of Figs. 11 and 12. Top
contact layer 114 comprises a substantially transparent electrically
conductive material such as indium tin oxide (ITO), and forms the
electrical contact between the photodiode and other elements used in
reading and processing the charge generated by the photodiode in
response to incident radiation. Thus, in the finished device, multitier
passivation layer 112 is disposed between top contact layer 114 and
photosensitive island 110 or substrate 106, except in contact area 130
on top surface 120 of photosensor island 110.
In operation, for both embodiments of Figs. 11 and 12,
actinic incident radiation 104 enters photosensor island 110 after
passing through one or all of the following: substantially optically
transparent top contact layer 114, organic dielectric layer 136,
inorganic moisture barrier layer 134, and inorganic dielectric layer
132. Radiation absorbed by the a-Si in the photosensor island 110
results in the generation of charge, which is collected at the contacts
108 and 130. The multitier passivation layer 112, in accordance with
this invention, minimizes sidewall leakage from the photodiode 104.
The inorganic dielectric layer 132 adjoins the sidewalls 122 and
provides improved adhesion relative to SiNx to the underlying ITO
strap 130 on the diode surface. The second tier inorganic moisture
barrier layer 134 is disposed on the first tier inorganic dielectric layer
132 to limit moisture penetration to sidewalls 122. The second tier
SiNx layer 134 serves as the most significant moisture resistant layer
because it has excellent step coverage, is inorganic, is relatively thick,
and has reasonably low pinhole and crack formation characteristics.
The multitier passivation layer 112 further protects the a-Si
photosensor island 110 from leakage resulting from the combination of
moisture introduced from the ambient into the polyimide and ionic
impurities present in most polyimides, while still enabling the use of
polyimide to take advantage of its numerous attributes, such as the
ability to deposit it in a relatively thick amount without resulting cracks
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and stresses in the . Furthermore, the multitier passivation layer 112
forms steps for highly reliable continuity for top contact layer 114 over
edges of the organic dielectric layer 136.
The advantages of this invention are especially
applicable to all photosensitive elements in which sidewall leakage is
of concern to device performance. Sidewall leakage is of particular
importance as photodiode sizes decrease to less than 1 mm, since
sidewall leakage then becomes a significant contributor to the total
reverse bias leakage of the photodiode. Particularly for photodiodes
having a size of less than about 200 microns on a side, sidewall
leakage dominates the area leakage component and is thus of primary
importance to this aspect of device performance. The multitier
passivation layer 112 provided by this invention similarly benefits
larger photodiodes in which humidity related degradation of sidewalls
can cause sidewall leakage to become a significant leakage
contributor.
Subsequent to deposition of the multitier passivation
layer 112, fabrication of photosensitive array 116 of Fig. 13 is
continued with deposition of a photosensitive array barrier layer 142.
The barrier layer 142 typically includes two strata; the first stratum,
silicon oxide 144 having a thickness of about 0.01 to about 0.1
microns, is disposed over top contact layer 114 of the photosensor
array, and the second stratum 146, silicon nitride having a thickness of
about 0.5 to about 2.0 microns, is disposed over the first stratum 144.
Further details relating to passivation layer may be found in U.S.
Patent 5,187,369 issued to J.D. Kingsley et al., assigned to the
assignee herein.
While only certain features of the invention have been
illustrated and described herein, many modifications and changes will
occur to those skilled in the art. It is, therefore, to be understood that
the appended claims are intended to cover all such modifications and
changes as fall within the true spirit of the invention.