Semiconductor device manufacturing: process – With measuring or testing
Reexamination Certificate
2002-03-08
2004-08-31
Niebling, John F. (Department: 2812)
Semiconductor device manufacturing: process
With measuring or testing
C438S015000, C438S016000, C257S355000, C257S372000
Reexamination Certificate
active
06784001
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates generally to semiconductor fabrication technology, and, more particularly, to an automated method of varying stepper exposure dose across the surface of a wafer based upon across wafer variations in device characteristics, and a system for accomplishing same.
2. Description of the Related Art
There is a constant drive within the semiconductor industry to increase the operating speed of integrated circuit devices, e.g., microprocessors, memory devices, and the like. This drive is fueled by consumer demands for computers and electronic devices that operate at increasingly greater speeds. This demand for increased speed has resulted in a continual reduction in the size of semiconductor devices, e.g., transistors. That is, many components of a typical field effect transistor (FET), e.g., channel length, junction depths, gate insulation thickness, and the like, are reduced. For example, all other things being equal, the smaller the channel length of the transistor, the faster the transistor will operate. Thus, there is a constant drive to reduce the size, or scale, of the components of a typical transistor to increase the overall speed of the transistor, as well as integrated circuit devices incorporating such transistors.
By way of background, an illustrative field effect transistor
10
, as shown in
FIG. 1
, may be formed above a surface
15
of a semiconducting substrate or wafer
11
, such as doped-silicon. The substrate
11
may be doped with either N-type or P-type dopant materials. The transistor
10
may have a doped-polycrystalline silicon (polysilicon) gate electrode
14
formed above a gate insulation layer
16
. The gate electrode
14
and the gate insulation layer
16
may be separated from doped source/drain regions
22
of the transistor
10
by a dielectric sidewall spacer
20
. The source/drain regions
22
for the transistor
10
may be formed by performing one or more ion implantation processes to introduce dopant atoms, e.g., arsenic or phosphorous for NMOS devices, boron for PMOS devices, into the substrate
11
. Shallow trench isolation regions
18
may be provided to isolate the transistor
10
electrically from neighboring semiconductor devices, such as other transistors (not shown).
When the transistor
10
is operational, i.e., when it is turned “ON” by applying an appropriate voltage to the gate electrode
14
, a channel region
17
, indicated by dashed lines, will be established in the substrate
11
between the source/drain regions
22
. During operation, electrons will flow between the source/drain regions
22
in the channel region
17
. The distance between the source/drain regions
22
is generally referred to as the “channel length” of the transistor
10
, and it approximately corresponds to the length
27
of the gate electrode
14
. Channel length, at least in part, determines several performance characteristics of the transistor
10
, such as drive current (I
d
), leakage currents, switching speed, etc.
As further background, as shown in
FIGS. 2 and 3
, a plurality of die
13
are fabricated above a surface
15
of a substrate or wafer
11
. The die
13
are separated by scribe lines
21
. Each of the die
13
contains many thousands of the transistors
10
. As shown in
FIG. 3
, one or more illustrative test structures
23
, such as a test transistor
29
, are formed in the scribe lines
21
at various locations across the surface
15
of the wafer
11
. For purposes of clarity, various process layers that are normally formed above the test structure
23
, e.g., conductive lines and conductive contacts formed in layers of insulating material, have been omitted.
A plurality of such illustrative test transistors
29
are subjected to one or more electrical performance tests at various points during the process of forming a completed integrated circuit device on each die
13
. For example, after an initial metal contact layer is formed, thereby allowing electrical coupling to the test transistor
29
by probing, the drive current of one or more of the test transistors
29
may be measured. The test transistors
29
are assumed to be representative of the transistors fabricated in the production die
13
. Based upon such measurements, predictions may be made as to the performance characteristics of the completed integrated circuit devices formed on the die
13
. For example, the measured drive current of one or more of the test transistors
29
may be used to predict the overall operating speed of completed integrated circuit devices.
Based upon the results of various electrical performance tests on the test structures
23
and/or completed integrated circuit devices, the wafer
11
may be considered to be comprised of multiple arbitrarily-defined regions, e.g., a center region
31
, a middle region
33
, and an edge region
35
, in which integrated circuit devices formed therein share similar performance characteristics. The precise boundaries and shapes of these various regions are difficult to define. For example, the center region
31
may be defined by an outer radius
41
that is approximately one-third of a radius
43
of an active area
19
. The middle region
33
may be defined by an outer radius
45
that is approximately two-thirds of the radius
43
of the active area
19
and an inner radius that corresponds to the outer radius
41
of the center region
31
. The edge region
35
may be defined by the outer radius
43
and the inner radius
45
. Although the depicted regions
31
,
33
and
35
are depicted as having a generally circular or annular ring shape, in practice, they may be of any shape, e.g., oval, toroidal, etc., depending upon the results of the electrical testing.
Based upon experience, the electrical characteristics, e.g., drive current (I
d
), of the transistors
10
tend to vary across the surface
15
of the wafer
11
. For example, the transistors
10
fabricated in the edge region
35
of the wafer
11
tend to have smaller drive currents (“edge-cold”) as compared to the transistors
10
fabricated in other regions of the wafer, e.g., the center region
31
. Stated another way, the wafer
11
tends to exhibit certain across wafer performance characteristic “signatures,” like producing the transistors
10
with reduced drive currents in the edge region
35
of the wafer
11
.
These across wafer performance variations may be a result of a variety of processing events. For example, such variations may be due to variations in manufactured gate lengths
27
across the surface of the wafer
11
. Alternatively, these performance variations may be due to variations in the results of anneal processes performed on the transistors
10
fabricated in the edge region
35
of the wafer
11
as compared to, for example, the impact of such anneal processes on the transistors
10
fabricated in the center region
31
. These variations may also be due to the inherent nature of fabricating the transistors
10
on the edge region
35
of the wafer
11
, or they may be due to the particular processing tools used to fabricate the transistors
10
on the wafer
11
.
Irrespective of the cause of such across wafer variations, such variations tend to be problematic in that the manufacturing operations are not as efficient as would otherwise be desired. For example, if it is desired to fabricate a certain number of high speed devices, additional wafers may have to be processed due to the fact that a certain number of devices manufactured in the center region
31
of the wafer
11
may have less than desirable performance characteristics, i.e., the operating speed of such transistors may be too slow. Thus, there is a need for an automated method and system of fabricating integrated circuit devices wherein variations in across wafer performance characteristics are reduced or eliminated.
The present invention is directed to solving, or at least reducing the effects of, some or all of the aforementioned problems.
SUMMARY OF THE INVENTION
The present invention is dire
Hewett Joyce S. Oey
Toprac Anthony J.
Advanced Micro Devices , Inc.
Luk Olivia T.
Niebling John F.
Williams Morgan & Amerson P.C.
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