Adhesive bonding and miscellaneous chemical manufacture – Differential fluid etching apparatus – For liquid etchant
Reexamination Certificate
2002-06-28
2004-10-26
Mills, Gregory (Department: 1763)
Adhesive bonding and miscellaneous chemical manufacture
Differential fluid etching apparatus
For liquid etchant
C324S071500
Reexamination Certificate
active
06808590
ABSTRACT:
BACKGROUND OF THE INVENTION
The invention relates generally to semiconductor fabrication and more specifically to in-line metrology for process control during wafer processing.
During semiconductor fabrication a there are multiple steps where an underlying substrate is subjected to the formation and removal of various layers. The small feature sizes, tight surface planarity requirements, combined with the constant quest to increase throughput, makes it highly desirable to stop the process when the correct thickness has been achieved, i.e., when an endpoint has been obtained for the process step.
Eddy current sensors are used for displacement, proximity and film thickness measurements. The sensors rely on the induction of current in a sample by the fluctuating electromagnetic field of a test coil proximate to the object being measured. Fluctuating electromagnetic fields are created as a result of passing an alternating current through the coil. The fluctuating electromagnetic fields induce eddy currents which perturb the applied field and change the coils inductance.
FIG. 1
is a simplified schematic diagram of the principle upon which an eddy current sensor operates. An alternating current flows through coil
100
in close proximity to conducting object
102
. The electromagnetic field of the coil induces eddy currents
104
in conducting object
102
. The magnitude and the phase of the eddy currents in turn effect the loading on the coil. Thus, the impedance of the coil is impacted by the eddy currents. This impact is measured to sense the proximity of conducting object
102
as well as a thickness of the object. Distance
106
impacts the effect of eddy currents
104
on coil
100
, therefore, if object
1002
moves, the signal from the sensor monitoring the impact of eddy currents on coil
100
will also change.
Attempts to use eddy current sensors to measure thickness of a film has resulted in limited success. Since the signal from the eddy current sensor is sensitive to both the thickness of the film and distance of the substrate to the sensor, there are two unknowns that must be resolved.
FIG. 2
is a schematic diagram of a wafer carrier having an eddy current sensor for measuring the thickness of a wafer during a chemical mechanical planarization process (CMP). Wafer carrier
108
includes eddy current sensor
110
. During a CMP operation, wafer
114
supported by carrier film
112
of carrier
108
is pressed against pad
116
to planarize a surface of the wafer. Pad
116
is supported by stainless steel backing
118
.
One shortcoming of the configuration of
FIG. 2
comes from the variability of the carrier film, which can vary by +/−3 mils. Thus, the carrier film causes a substantial variability in the distance between the wafer and the sensor. Additionally, different down forces applied to the carrier film will cause further variation as the carrier film compresses. Accordingly, it becomes extremely difficult to calibrate for all the variables that effect the distance, which in turn impacts the thickness measurement of the sensor. Another shortcoming of this configuration is caused by the presence of another conducting material separate from the conducting material being measured and is commonly referred to as a third body effect. If the thickness of the conductive layer is less than the so-called skin depth, the electromagnetic field from the coil will not be completely absorbed and will partially pass through to stainless steel backing
118
of pad
116
of FIG.
2
. It will induce additional eddy currents within the stainless steel belt, thereby contributing to the total signal from the eddy current sensor. Furthermore, it should be appreciated that the pad wears or erodes over time, causing variation in the distance between the stainless steel backing and the eddy current sensor, which influences the appropriated contribution to the total eddy current sensor signal. Thus, a wear factor has to be considered as the wafers are continuously being processed. Consequently, due to the variability injected into the thickness measurement, the amount of error is unacceptably high and unpredictable.
In view of the foregoing, there is a need to eliminate or offset the variability inherent under working conditions so that an accurate endpoint can be determined to more precisely achieve a desired thickness.
SUMMARY OF THE INVENTION
Broadly speaking, the present invention fills these needs by determining a thickness of the wafer under ideal conditions, i.e., non-working conditions, and providing that thickness so that the variability due to unknowns introduced during the processing operation can be accounted for or offset.
In accordance with one embodiment of the present invention, a method for determining an endpoint thickness for a chemical mechanical planarization (CMP) operation, is provided. The method initiates with providing a first sensor external to the CMP module. Then, a thickness of a wafer is detected with the first sensor. Next, the thickness of the wafer is supplied to a second sensor in the CMP module. Then, the second sensor is calibrated with the thickness of the wafer. Next, CMP operating parameters are adjusted based on a signal from the second sensor in order to optimize a CMP operation for the wafer.
In another embodiment, an apparatus for supporting a wafer during a chemical mechanical planarization (CMP) operation is provided. The apparatus includes a wafer carrier defined within a housing. The wafer carrier has a bottom surface. A carrier film is affixed to the bottom surface. The carrier film is configured to support a wafer during CMP operations. A sensor is embedded in the wafer carrier such that a bottom surface of the wafer carrier is aligned with a bottom surface of the sensor, or a window, made of non-conductive material, aligned with the bottom surface of the carrier is introduced in front of the sensor. The sensor is configured to induce an eddy current in the wafer to determine a signal which is defined by proximity and a thickness of the wafer as the wafer is forced against a polishing pad. For a given proximity, the sensor is configured to receive an incoming thickness of the wafer to offset an inaccuracy of the sensor due to both a non-uniformity of the carrier film and polishing pad erosion.
In accordance with yet another embodiment of the present invention, a system for processing a wafer is provided. The system includes a chemical mechanical planarization (CMP) tool. The CMP tool includes a wafer carrier defined within a housing, where the wafer carrier has a bottom surface. A carrier film is affixed to the bottom surface. The carrier film is configured to support a wafer during CMP operations. A sensor is embedded in the wafer carrier such that a bottom surface of the wafer carrier is aligned with the bottom surface or a separating non-conductive spacer, aligned with the bottom surface is introduced. The sensor is configured to induce an eddy current in the wafer to determine a proximity and a thickness of the wafer. A sensor array external to the carrier is included, performing film thickness measurements in non-disturbing conditions. The sensor array is in communication with the sensor embedded in the wafer carrier. The sensor array is configured to substantially eliminate a distance sensitivity. The sensor array is configured to provide an initial thickness of the wafer. The initial thickness of the wafer allows for a calibration to be performed on the sensor embedded in the wafer carrier. The calibration offsets variables causing inaccuracies in the determination of the thickness of the wafer during CMP operation.
It is to be understood that the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.
REFERENCES:
patent: 3815016 (1974-06-01), Nix et al.
patent: 4556845 (1985-12-01), Strope et al.
patent: 5473247 (1995-12-01), You et al.
patent: 5485082 (1996-01-01), Wisspeintner et al.
patent: 5559428 (1996-09-01), Li
Bright Nicolas J.
Gotkis Yehiel
Hemker David
Kistler Rodney
Owczarz Aleksander
Lam Research Corporation
MacArthur Sylvia R.
Martine & Penilla LLP
Mills Gregory
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