Semiconductor device manufacturing: process – Coating with electrically or thermally conductive material – To form ohmic contact to semiconductive material
Reexamination Certificate
2000-05-26
2002-02-26
Nelms, David (Department: 2818)
Semiconductor device manufacturing: process
Coating with electrically or thermally conductive material
To form ohmic contact to semiconductive material
C438S401000
Reexamination Certificate
active
06350680
ABSTRACT:
BACKGROUND OF THE INVENTION
(1) Field of the Invention
The invention relates to the fabrication of integrated circuit devices, and more particularly, to a method for the alignment of AlCu pads as part of the copper metalization process.
(2) Description of the Prior Art
In the design and manufacturing of semiconductor devices, techniques of Very Large Scale Integration (VLSI) and Ultra Large Scale Integration (ULSI) are used to create complex semiconductor devices on the surface of a silicon substrate. Improved device performance is typically made possible by reducing device dimensions, present day technology is reaching device dimensions in the deep sub-micron range down to 0.1 &mgr;m. To create device features that are part of semiconductor devices, the technique of photolithography is frequently applied. Using this technology device features or device patterns are transferred from a (relatively large dimensional) reticle or photomask to a target surface that is typically the surface of a semiconductor substrate. Step-and-repeat processes allow for the step-wise or gradual transfer of a relatively large dimensional image to ever smaller reproductions of this image to the point where the desired, if needed sub-micron, dimensions of the semiconductor device are reached.
In the process of device feature or pattern exposure, the alignment between successive layers that are being created is of critical importance. Smaller device dimensions place even more stringent requirements on the accuracy of the alignment of the successive layers that are superimposed on each other. Alignment marks that are provided in the lower layers of exposure or typically in the surface of the substrate are in this used to assure alignment between the various layers or patterns that are created. It is clear that device manufacturing yield is directly dependent on how accurate the patterns of the successive layers that make up the device are aligned. Any misalignment can result in for instance interconnect line opens or shorts or shorts or high leakage currents between adjacent regions within a device. Several alignment marks can be provided per wafer, each alignment mark having a specific function such as wafer positioning, contact etching or photoresist patterning. Alignment marks are mostly incorporated into the chip and are placed close to the edge of the wafer. The process of using alignment marks makes use of the step height of the alignment marks. By etching a depth into the surface of a substrate, a step height of the alignment mark is created. Wafer positioning is performed, typically by a wafer stepper tool, to assure proper alignment of a pattern that is to be created in a deposited layer with the pattern of the preceding layer. When performing this wafer alignment, the surface of the (underlying) layer that has been provided with alignment marks is coated with a transparent layer of photoresist. A laser light beam is aimed at the alignment mark, light will be reflected by the alignment mark and provides in this manner an exact indication of the position of the wafer in the stepper tool. This allows the stepper tool to adjust the wafer position to the desired position, making accurate alignment between overlying layers possible. Each photomask that is used for the exposure of the various layers that make up the semiconductor device is provided with alignment marks, which allow for accurate alignment of all photomasks that are used for the creation of the device. During this process, the alignment mark is replicated in the overlying layer and in this manner migrates upward with the successive layers that are being formed. This leads to problems where layers of for instance interconnect metal need to be planarized, thereby potentially erasing the alignment mark. Before the layer of interconnect metal is deposited, the dielectric (Intra-Level Dielectric or ILD) is planarized for reasons of satisfactory metal deposition. This planarization removes the underlying alignment mark, making alignment for the interconnect metal difficult to achieve. In another typical processing sequence, metal interconnects or vias are created in a layer of dielectric or insulation. The metal that is used to fill the interconnects or vias is then deposited over the surface of the dielectric or insulation thereby filling the openings that have been created for the vias. The excess metal is removed from the surface of the dielectric, typically using CMP technology, a process that results in a smooth surface of the layer of dielectric and which eliminates the (required) sharply defined edges of the alignment marks and makes the alignment of overlying layers very difficult. Additional processing steps may in these cases be required in order to restore the visibility of the alignment marks, these additional processing steps add to the cost of the overall device and are therefore to be avoided whenever possible. One of the techniques that is used for this purpose is the creation of the “open frame” whereby the step height of the original mark is recreated.
FIGS. 1
a
and
1
b
show a Prior Art process of using alignment marks for the creation of an AlCu pad in an overlying layer. The contact points
12
are points of electrical interconnect that have been created in an underlying layer
10
. It is the objective of the process that is highlighted in
FIGS. 1
a
and
1
b
to create an AlCu pad that overlays and makes contact with at least one of the electrical contact points
12
. Alignment marks
20
are present in an underlying layer and are used for both the alignment of the contact points
12
and for the alignment of the to be created and overlying AlCu pad.
The processing flow that is shown in
FIGS. 1
a
and
1
b
can be summarized as follows in the sequence listed, assuming that the pattern
12
of electrical points of contact has been created in layer
10
:
deposit a layer
14
of passivation
pattern the layer
14
of passivation for opening
16
sputter deposit a layer
18
of AlCu
perform photo exposure and etch for the alignment marks
20
thereby making the alignment marks
20
visible, and
perform photo exposure and etch for the AlCu pad.
It must be emphasized that, in the above indicated processing sequence, the photo and etch sequence for the alignment marks are first performed as one processing sequence followed by another processing sequence of photo and resist for the AlCu pad. The first of these two steps, that is the photo and etch steps for the alignment marks
20
, is necessary because the alignment marks
20
are not visible through the layer
14
of passivation and layer
18
of AlCu and can therefore not be used as alignment marks for the photo and etch of the AlCu pad that is to be created.
The AlCu pad is to be created over at least one of the points of electrical contact of copper
12
that have been created in the surface of, for instance, a substrate
10
. A layer
14
of passivation has been deposited over a surface of layer
10
, layer
10
can be the surface of a semiconductor substrate or it can be a layer of dielectric. The layer
14
of passivation has been patterned thereby creating opening
16
(for the AlCu pad) in this layer
14
of passivation whereby opening
16
aligns with at least one of the electrical contact points of copper pattern
12
. A layer
18
(
FIG. 1
b
) of AlCu is sputter deposited over the layer
14
of passivation thereby including the opening
16
that has been created in the layer
14
of passivation. Alignment marks
20
have been shown as being present but as being located at a level below the surface of layer
10
. The creation of opening
16
required an alignment of the photolithographic mask whereby the mask is aligned using the alignment marks
20
, the creation of the AlCu that overlays at least one of the electrical points of contact
12
requires an alignment of a photolithographic mask using the same alignment marks
20
. This alignment assumes that the light that is used to perform the process of alignment can penetrate the layer
14
of passivation in ad
Hsieh Hung-Chang
Kuo Chen-Cheng
Shih Tsu
Ackerman Stephen B.
Nelms David
Saile George O.
Taiwan Semiconductor Manufacturing Company
Vu David
LandOfFree
Pad alignment for AlCu pad for copper process does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with Pad alignment for AlCu pad for copper process, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Pad alignment for AlCu pad for copper process will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-2972289