The present application is based on and claims priority of Japanese patent application No. 2005-144043 filed on May 17, 2005, the entire contents of which are hereby incorporated by reference.
1. Field of the Invention
The present invention relates to plasma processing apparatuses, and more particularly, relates to a plasma processing apparatus having a self-diagnostic function.
2. Description of the Related Art
For example, according to Japanese Unexamined Patent Application Publication No. 2004-152999, a plasma processing apparatus has been disclosed which can detect incorrect operation at an early stage and specify the causes thereof by the following procedure. That is, in the plasma processing apparatus described above, impedances and process speeds are measured when the apparatus is operated under normal conditions and when chamber conditions, such as high-frequency electrical power and gas conditions, are changed so that a relational curve therebetween is formed beforehand, and the electrical power conditions are measured after maintenance so as to determine whether the measured data are within a predetermined range or not.
In addition, according to Japanese Unexamined Patent Application Publication No. 2002-73158, a monitor and self-diagnostic system has been disclosed which has a field monitoring server and a remote monitoring terminal, the field monitoring server collecting real-time operation data of industrial apparatuses and storing them in accordance with a predetermined editing style, the remote monitoring terminal connected to the field monitoring server with a communication cable, reading the stored operation data of the industrial apparatuses in accordance with a predetermined editing style, and monitoring and diagnosing operation conditions of the respective apparatuses.
In semiconductor device manufacturing, periodical diagnosis of apparatus conditions is necessarily performed in order to maintain an uptime ratio thereof, and it has been believed that so-called preventive maintenance is particularly important in which the change in condition of an apparatus is detected before incorrect operation occurs. However, according to the related techniques described above, for preventive maintenance, it has been very difficult to detect incorrect operation while the apparatus is being operated, and as a result, inspection is necessarily performed after the apparatus is temporarily stopped; hence, the uptime ratio of the apparatus is inevitably decreased.
The reason the preventive maintenance is difficult to perform while an apparatus is being operated is that the apparatus condition is changed in accordance with change in condition of wafers which are being processed. For example, the pressure of an etching chamber, which forms a semiconductor device manufacturing apparatus, is changed in accordance with the change in condition of reaction between an etching gas and a film, which is provided on a surface of a substrate such as a wafer and is to be etched by the etching gas, and when the film is entirely etched away, since the reaction caused by the etching gas is stopped, a phenomenon occurs in which the pressure in the process chamber is increased (or decreased).
The same thing can be said for conditions of other apparatuses, and for example, an electrical source voltage (Vpp voltage) for plasma generation, plasma emission, or the like reflecting the plasma impedance is changed as etching reaction proceeds. In addition, a film to be etched is generally provided on the front surface of a substrate; however, when being formed by deposition, the film is likely to be also deposited on the back side of the substrate in many cases, and depending on the amount of the film deposited on the back side, a force electrostatically adsorbing the substrate is changed.
Hence, in preventive maintenance heretofore performed, after the operation of an apparatus is temporarily stopped, a specific sequence is carried out while workpieces are not being processed, so that the change in apparatus condition is detected. While the preventive maintenance as described above is performed, the operation of the apparatus must be stopped, and as a result, the uptime ratio thereof is unavoidably decreased.
Accordingly, in consideration of the problems described above, the present invention was made, and an object of the present invention is to provide a preventive maintenance technique capable of diagnosing apparatus conditions without serious decrease in uptime ratio.
To this end, the present invention has the following structure.
A plasma processing apparatus of the present invention comprises: a plasma processing main frame and an apparatus controller controlling the plasma processing main frame in accordance with a predetermined procedure, the plasma processing main frame comprising: a vacuum process chamber; an exhaust device evacuating the vacuum process chamber; a mass flow controller supplying a process gas into the vacuum process chamber; a stage electrode receiving a workpiece in the vacuum process chamber and holding it by adsorption; a high-frequency electrical source applying a high-frequency electrical power to the supplied process gas to generate plasma; and a transfer device placing the workpiece on the stage electrode and taking out the workpiece after it is processed. In the plasma processing apparatus described above, the apparatus controller comprises a diagnosis device which acquires a plurality of recipes, one of which corresponding to the workpiece being applied thereto, and apparatus parameters of the plasma processing apparatus when a specific recipe of said plurality of recipes is executed and which diagnoses whether the condition of the plasma processing main frame is good or not based on the acquired apparatus parameters.
According to the present invention, since the plasma processing apparatus has the structure described above, a preventive maintenance technique can be provided which can diagnose the condition of the apparatus without causing a serious decrease in uptime ratio.
Hereinafter, an embodiment of the present invention will be described with reference to accompanying figures.
In
Subsequently, plasma 3 is excited by a high-frequency electrical source 8 for plasma generation, and in addition, by a bias high-frequency electrical source 9, ions generated in the plasma are pulled onto the surface of the workpiece 2, so that etching proceeds. In etching, the temperature of the workpiece 2 in the plasma 3 is increased by heat generated therein. Hence, a cooling gas is supplied to the back side of the workpiece 2 via a mass flow controller 11. The pressure of the cooling gas is monitored by a pressure gage 12 and is maintained at a predetermined level.
An apparatus controller 13 controls a plasma processing main frame 50 in accordance with a predetermined procedure and processes workpieces by respective recipes, the workpieces being carried in the process chamber 1 by a transfer device not shown in the figure. The apparatus controller 13 stores a plurality of recipes and acquires apparatus parameters of the plasma processing main frame 50 when specific recipes (such as a diagnosis recipe using a dummy wafer) of said plurality of stored recipes are executed, so that the apparatus parameters thus obtained are stored in an apparatus parameter input portion 101 (in this case, in the apparatus parameter input portion 101, apparatus parameters obtained when all recipes are executed may also be stored).
In this case, the apparatus controller 13 stores information of the workpiece 2 carried in the vacuum process chamber 1 by the transfer device and workpiece management information thereof (such as dummy wafer No., wafer No., lot name, recipe No., and the like) which specifies and manages a process (recipe) to be executed for this workpiece in a workpiece management information input portion 103.
The apparatus parameters stored in the apparatus parameter input portion 101 and the workpiece management information stored in the workpiece management information input portion 103 are saved in an apparatus information database 102. In this case, it is convenient when the apparatus parameters are saved based on respective workpieces stored in the workpiece management information.
Of the workpiece management information stored in the workpiece management information input portion 103, as for workpiece management information including the above specific recipes (such as a diagnosis recipe using a dummy wafer), diagnosis programs are prepared for respective specific recipes and are stored in a diagnosis program reference table 104.
When a process in accordance with the above specific recipe is performed, for example, for a dummy wafer, the apparatus controller 13 selects a diagnosis program corresponding to the specific recipe from a diagnosis program group and starts the program to diagnose the apparatus condition. In this step, as described later, after reading the apparatus parameters stored in the apparatus information database 102, the diagnosis program diagnoses the apparatus condition, displays the diagnosis result thereof, and issues an alarm when the result is abnormal.
As shown in
In
In
The parameters described above are software values of the apparatus including output values of respective devices such as an output value of a plasma electrical source, input values such as a measured value of a pressure gage, and set values of a recipe. In general, since the aforementioned process parameters are monitored at the main frame side of the apparatus in many cases, without additionally providing measurement means, the parameters may be received as the data from the main frame side. In addition, as described above, the diagnosis program is automatically started in accordance with a recipe No. which is processed, so that measured process parameters are analyzed. In accordance with the diagnosis result, this program may have a function to issue an alarm to a host computer managing the main frame and the apparatus.
In this example, the diagnosis program which is started in accordance with the recipe No. is described; however, the diagnosis program may be started in accordance with the recipe name instead of the recipe No. or may be started associated with datum such as the lot No. or lot name which is given to a lot to be processed. The importance is that the structure is reliably formed in which when an object diagnosis recipe is executed, a diagnosis program associated therewith is automatically executed.
Next, with reference to
Hence, when the change in gas flow rate is checked, a dummy workpiece (dummy wafer) is used. As dummy wafers, a lot for the purpose of preventive maintenance may be supplied, or dummy wafers may be supplied between lots which are processed for production. As described above, the dummy wafers are processed only under specific recipe (diagnosis recipe) conditions. In this case, since an object of this recipe (recipe 1 shown in
Next, the variable conductance valve 7 is narrowed to a predetermined level (such as 0.1%) so that the pressure inside the process chamber 1 is increased to an approximately full scale level of the process-chamber pressure gage 81. In this example, the gas flow rate of the recipe and the opening of the variable conductance valve 7 are optimized beforehand, and the ultimate pressure at the initial apparatus condition is recorded.
Next, the diagnosis recipe is executed during operation of the apparatus. Since this recipe is executed as a part of automatic operation of the apparatus, it is not necessary to stop the operation of the apparatus. In addition, since production can be started immediately after the execution of this recipe, only the execution time of this recipe is a downtime (non-operation time) of the apparatus.
Simultaneously with the execution of this recipe, the process parameters of the apparatus are recorded by a recording device. After the execution of the recipe, when this recipe No. is registered beforehand, a diagnosis program which is also registered is started in the diagnosis device. This program executes diagnosis operation based on the recorded process parameters described above.
In this case, the result of the execution of the diagnosis recipe, that is, the ultimate pressure of the process chamber is measured which is obtained at a predetermined valve opening of the variable conductance valve and at a predetermined gas flow rate. In order to eliminate noises, the pressure is obtained by averaging pressures in a stable period during the execution of the recipe.
A particular calibration capability of the check method described above is to be considered. Although the full scale of a general pressure gage is approximately 13 Pa in many cases, it is assumed that the gas flow rate (Q) and the opening of the variable conductance valve are optimized so that the pressure (P) is increased to approximately 10 Pa. Under the conditions described above, when 1% of the gas flow rate is changed, from the equation P=Q×V, the pressure inside the process chamber is also changed by 1% (in the above equation, V indicates the volume of the process chamber). In this case, since the change is 1% of 10 Pa, the change of pressure is 0.1 Pa. Since this value is approximately less than 1% of the full scale of the pressure gage, it is believed that this value is sufficiently large to be recognized as the deviation. That is, since a change of 1% of an actual flow rate via the mass flow controller can be detected by the method described above, as a daily check for preventive maintenance, it is said that the method described above is a satisfactory level.
The set values of the gas flow rates in steps 1 and 2 are each adjusted so that the pressure inside the process chamber is close to the full scale of the pressure gage at this set flow rate and this opening of the variable conductance valve. Since the absolute value of the check result is not required in the present invention, the maximum flow rate is not always necessary, and an optimum value for checking operation may be used as the set value. The results of the respective etching steps are registered in the apparatus information database 102 as described above, and the diagnosis program acquires the process parameters listed in the registered and permissible value table from the database.
In this example, from the pressures measured in steps 1 and 2, the averages thereof are obtained after the dead time. The averaged values are compared to the respective registered values, and when the results are outsides the permissible ranges, the gas flow rates are determined abnormal (defects of mass flow controller), so that an alarm indicating abnormality is issued.
While the flow rate of the mass flow controller 5 is maintained constant, an exhaust valve 61 is closed, and the increase in pressure inside the process chamber 1 is monitored.
Next, a method for checking the flow rate of the mass flow controller without stopping the operation is then considered. When the pressure and the volume of the process chamber are represented by P and V, respectively, s gas flow rate flowing into the process chamber is obtained by the equation Q=P/V.
In general, since V is constant, it is understood that Q is proportional to the pressure P. Hence, when the pressure P is measured, the gas flow rate Q can be obtained.
According to the present invention, since the original object of preventive maintenance is to detect the change of the apparatus with time, the absolute value of the flow rate is not always required. When the change with respect to the initial flow rate is grasped, more detailed measurement may be separately performed. Hence, preventive maintenance can be performed in the case in which a pressure corresponding to a certain flow rate is recorded beforehand, and when the amount of change in pressure exceeds a predetermined value, an alarm is issued. However, as described above, it is difficult to check the change in gas flow rate while actual workpieces are being processed for production.
In an etching apparatus, the exhaust device 6 is generally formed of a turbo molecular pump and a dry pump. Of the pumps described above, in the turbo molecular pump, a rotor is rotated generally at a predetermined revolution speed, and under a steady state, the exhaust capability thereof is not decreased. The failure of the turbo molecular pump is caused by the stop of the rotor, and in this case, the failure mode is characterized in that the exhaust capability is rapidly decreased to zero. That is, in the case of the dry pump, the exhaust capability thereof is decreased with time, and when it is decreased to a certain level or less, the exhaust capability of the entire system becomes insufficient.
The exhaust capability of the dry pump is generally evaluated by an exhaust time measured from the atmospheric pressure; however, for this evaluation, the operation of the apparatus must be stopped. In addition, the exhaust capability can be estimated to a certain extent when the increase in pressure is monitored by a vacuum gage provided between the dry pump and the turbo molecular pump while a predetermined amount of a gas is supplied; however, it is also difficult to perform this measurement during normal operation.
Among the reasons for this, first, since in an apparatus using a corrosive reactive gas, purging is performed by a nitrogen gas in order to prevent corrosion of a pump system, and the amount of a purging gas is not generally controlled, the flow rate thereof cannot be precisely grasped. Second, since the amount of an etching gas is small, the difference in total amount of gases is small between the cases in which an etching gas is supplied and is not supplied, and in addition, since the flow rate of an etching gas is set by the recipe, the degree of increase in pressure cannot be estimated.
Accordingly, in this example, the exhaust capability is checked by the following method. First, under the condition in which a gas is not supplied (etching step 1 of a recipe 2 shown in
As shown in
The workpiece directly receives energy from plasma by a bias voltage. Since being exposed to high energy, the holder is a part whose properties are liable to be changed with time. For example, etching reaction products deposit on the electrode surface, and the surface roughness and surface electrical properties of the electrode are changed. These changes with time influence the adsorption of the workpiece and the cooling properties, and when the above properties are degraded, displacement of the workpiece due to insufficient adsorption and degradation in etching performance due to insufficient cooling may occur in some cases.
As preventive maintenance, the adsorption condition of the workpiece is monitored; however, in general, the condition of a cooling gas, such as the pressure of a cooling gas, is monitored. As the gas pressure control, the following two methods may be mentioned. One method is to change the flow rate of the cooling gas, and the other method is to change the opening of the pressure control valve while the flow rate of the cooling gas is maintained constant. In both cases, when the flow rate of the cooling gas is integrated over the control period, the total gas volume which is supplied to the back side of the workpiece can be calculated. This total gas flow volume is a volume leaking between the workpiece and the holding portion, and hence when the change in total gas volume with time is measured, the change in electrostatic adsorption properties can be detected.
Also in this case, since variation among workpieces used for production exists, and the amount of a film material deposited on the back side of the workpiece is not known, conditions which define the total gas flow volume during production operation cannot be precisely determined, the film material being supplied to form a film on the front surface of the workpiece.
Hence, in this example, a dummy wafer is used as the workpiece. Accordingly, the total gas flow volume can be reproducibly obtained from measurement to measurement.
In this example, by using a dummy wafer, the emission in discharge by a specific recipe (diagnosis recipe) is monitored. Accordingly, a stable emission condition can always be obtained. The emission condition can be monitored by an optical emission spectroscope (OES) 4 through a window of an opening portion provided for the process chamber. When the emission is always monitored under the same condition as is the case of this example, the change in emission condition with time can be understood from the degree of haze of the window, and hence the deposition in the process chamber can be estimated.
As shown in
In general, it is difficult to detect the degree of wear of components exposed to electrical discharge, and the exchange of components is performed using the total discharge time as an index in many cases. When the exchange of components is not properly performed, a local discharge phenomenon, a so-called abnormal discharge, is generated, and as a result, an adverse influence may occur on the process in some cases. Hence, since the exchange is too late when abnormal discharge occurs, the degree of wear of components must be detected before the generation of abnormal discharge. However, right before an abnormal discharge phenomenon occurs, every parameter of the apparatus normally works in many cases. Accordingly, heretofore, the exchange of components must be performed earlier.
In this example, the life of components can be estimated by detecting a discharge unstable region. In general, the discharge system has a discharge stable region and a discharge unstable region, and by changing discharge parameters such as pressure, type of gas, gas flow rate, and set electrical powers of an electrical source and a bias electrical source, the system may be placed in a discharge stable region or in a discharge unstable region. In the discharge unstable region, flameout or flicker of plasma, abnormal peak voltage Vpp of a high-frequency electrical source for plasma generation or variation thereof may be observed.
As shown in
As described above, the discharge unstable region has been known beforehand, and in addition, the unstable discharge can be detected. Hence, when the check steps of the recipe are sequentially executed, the transfer of the discharge unstable region can be detected. Since the reason for this transfer is believed that characteristics of the discharge system are changed, for example, by the wear of components, the life of components can be indirectly detected according to this method.
Hence, when a check step in which discharge becomes unstable is detected by performing the above check steps, the degree of wear of components can be indirectly checked.
In Step S806, a check step following an immediately previous one is then executed, and when a final step is executed in Step S807, a check step in which the discharge becomes unstable is investigated. When the check step in which the discharge is unstable is changed, it is construed that the discharge condition is being changed, and a signal indicating abnormal is issued in Step S810.
Next, the detection of unstable discharge in Step S805 will be described. In the region in which the discharge is unstable, as described above, phenomena such as flicker, abnormal ignition, and flameout of plasma emission occur.
In the case of abnormal ignition of plasma, since the system detects this phenomenon as an error, subsequent steps are not further executed. Accordingly, when the error occurs, the step in which the error occurs is investigated, and subsequent steps are recorded as “unstable”.
Flicker of plasma may be detected by several methods and is detected in this example by flicker of light emission. When the emission spectrum value is Fourier-transformed in the time direction, the frequency component of variation in emission with time can be obtained. Of this variation component, when the value obtained by addition of intensities of frequency components, for example, of 2 Hz or more is a certain threshold value or more, it is determined that flicker occurs. In addition, in the case of flameout, since the average of the amount of emission is lower than that in a general case, the detection can be performed. As described above, when the ignition defect, flicker, and flameout are checked in every step, a step in which the unstable discharge occurs can be grasped.
In order to detect the unstable discharge, in Step S811, the average is first calculated by addition of the emission spectrum in the wavelength direction. The Fourier-transformation is performed in the time direction in Step S812, components at a flicker frequency or more are then integrated in Step S813, and the ratio to the entire intensity is then calculated. In Step S814, the above calculated ratio and the flicker intensity ratio (see
In Step S814, when the above calculated ratio is not larger, in Step S815, the average of emission spectrum in the step is calculated, and the ratio to the emission intensity obtained when no discharge occurs is calculated. In Step S817, the calculated ratio and the emission intensity ratio (see
In this example, the unstable discharge is detected by the flicker of emission; however, in addition, the unstable discharge may be detected, for example, by checking apparatus parameters of discharge, such as abnormal Vpp voltage, drift thereof, high-frequency electrical power, abnormal tuning position of a bias voltage, or drift thereof.
In general, when the amount of a leak gas or the amount of an out-gas is obtained, after the process chamber is evacuated for a predetermined period of time, as shown in
According to this example, although being simple, a method is provided which is capable of detecting the increase in amount of a leak gas or that of an out-gas, and in addition, this method can determine one of the two types of gases, the amount of which is increased.
In this example, discharge is performed using a single element gas except nitrogen, oxygen, and hydrogen; however, experiments using the aforementioned gases are performed beforehand. In this experiment, as shown in
In addition, as shown in
According to a related technique, a method has been proposed in which a spectrum in discharge is measured so as to determine whether leak occurs or not; however, when the leak amount is small, the S/N ratio is degraded by adverse influence of other emission spectra. On the other hand, in this example, since check is performed under the condition in which discharge hardly occurs, the entire emission intensity itself is small. Hence, the sensitivity of a spectrometer can be set high. Furthermore, since the ratio of the leak amount which contributes to discharge is high, the S/N ratio can be increased.
When the difference is outside the permissible range, in Step S907, peaks values of registered number of wavelengths of the emission spectra are added, (for example, when the leak gas amount is to be determined, values of a plurality of peaks of emission spectrum of a nitrogen gas are added). In Step S908, the ratio between the value thus obtained by addition and the entire intensity is calculated, and in Step S909, the ratio is compared with a classification threshold value. In Step S910, it is determined whether the ratio is larger than the classification threshold value or not. When the ratio is larger than the classification threshold value, it is determined in Step S911 that the leak gas exists, and when the ratio is not larger than the classification threshold value, it is determined in Step S912 that the outgas exists. In Step S913, a signal indicating abnormal leak gas amount or outgas amount is issued.
Respective parameters of etching are gradually changed as the number of processed wafers is increased. For example, since reflecting plasma impedance, the Vpp voltage is changed, for example, by deposition of reaction products in the process chamber and the degree of wear of components. In a manner similar to that described above, the tuning point of the high-frequency electrical source is also changed.
The values of the respective process parameters of etching which are obtained when the amount of deposition of reaction products is small in the apparatus are recorded as standard values. The permissible ranges are set with respect to the standard values, and when the respective parameters obtained when the process is performed under the same condition are outside the ranges, the process is determined to be abnormal.
Heretofore, the method as described above has been applied to an etching process for production; however, in actual etching, as the etching proceeds, respective parameters themselves are considerably changed. In addition, in the case of multi-product production, there has been a problem in that the standard value and the permissible value are difficult to set for each product.
In this example, since the check is not performed for product wafers but for dummy wafers, the apparatus condition is stable when the measurement is performed. In addition, since the products are not processed, the number of recipes used for the check can be reduced.
As the recipe, a normal etching condition may be used; however, in order to more sensitively detect the change in condition of the apparatus, check is preferably performed using a recipe having a very limit condition as described in Example 5 in which the discharge is barely in a stable region.
In general, the change in apparatus with time which is apparently observed is generally a very small change in many cases. In actual etching for production, since the change in condition itself of the apparatus caused by the progress of etching is significant, it is difficult to detect the change in apparatus. In addition, since various many parameters are simultaneously and gradually changed, even when the parameters are individually checked as described in Example 7, the changes thereof are small, and hence the change in condition may not be precisely grasped in some cases.
In this example, arithmetic processing is performed for the entire parameters of the apparatus, and from the calculation results, the change in apparatus is detected. When the diagnosis is performed, the entire parameters of the apparatus when it is in the initial state are recorded beforehand and are set to standard values. In this case, in order to place the apparatus in a predetermined state, dummy wafers are used. In addition, as the process conditions, since the change may not be easily observed under normal stable conditions, a recipe having the very limit condition of Example 5 (see recipe 8 shown in
The two types of entire parameters thus obtained are compared with each other, and the differences of respective parameters are measured. In this case, since the amount of change may have a minus or a plus sign with respect to the standard value, the absolute value thereof is used. Next, all the amounts of change are normalized to have the same value. In particular, coefficients are obtained so that all the amounts of change have a predetermined value, such as 1. However, according to this calculation, a parameter having a smaller amount of change has a larger coefficient. As a result, a mere noise may be regarded as a significant change in some cases, and hence the amount of change to a certain level or less must be ignored. For this purpose, for example, additional process is also performed such that a parameter having a small change such as 1% or less of the full scale is excluded from the calculation.
After the pre-treatment described above is performed, the actual check is then performed. In this case, between processes performed for products, a dummy wafer is used, and discharge process is performed using the recipe (recipe 8) exclusive therefor.
After the process is performed, as for parameters which showed the changes in experiment performed beforehand, the differences from the standard values are obtained and are then added. When the value thus obtained reaches a certain predetermined value or more, a process such as issue of an alarm is performed.
First, the parameters obtained in the state in which the number of processed wafers is small and the parameters right before maintenance obtained using the recipe 8 are recorded (columns named “first wafer” and “n-th wafer”). The differences therebetween are calculated, and the use of the individual parameters is determined depending on whether the value thus obtained is 1% or more of the full scale or not.
In particular, although the difference in high-frequency incident electrical power in this table is 10 W, since the full scale is 2,000 W, the change is only 0.5%. As a result, this parameter is not employed. By the same calculation as described above, parameters provided with O in the employment column in the table are selected. Since being different from each other in terms of physical value and/or full scale, these amounts of changes cannot be discussed on the same level, and hence the normalization is performed.
In detail, the high-frequency reflected electrical power has a change of −20 W. Since the change has a plus or minus sign, an absolute value of 20 is used. Since the maximum change is 20, in order to normalize it to 1, the normalization coefficient is set to 0.05. For example, when this parameter is change by 10 W, by multiplying 0.05 which is the normalization coefficient, 0.5 is obtained. Hereinafter, this value is called a score of this parameter.
Accordingly, the scores of the respective parameters are each in the range of 0 to 1. When the number of parameters employed in this case is assumed to be m, the total of the scores is in the range of 0 to m. By periodically executing the recipe 8, the total score is calculated. When this value exceeds the permissible range, the process is determined to be abnormal. When the permissible range is set to a value of m/2 by way of example, when an abnormal case occurs, it is considered that the apparatus is approximately in the state between the state of the first wafer and the state right before the maintenance. In this example described above, the case is described in which extraction of parameters is performed by a hand work; however, when a method of multivariate analysis such as a principle component analysis is used, the characteristics of the change can also be extracted.
Accordingly, when a wavelength having a close relationship with properties of an etching process is extracted from the plasma emission and monitored, the etching properties can be estimated. Heretofore, the emission condition in etching is checked; however, in the case of multi-product production, since the emission condition is changed from product to product, the change cannot be grasped. However, in this example, since dummy wafers are used, and the comparison of emission can be performed under the same condition (using the same recipe 8), the change with time can be easily grasped. In addition, as the dummy wafer, since a wafer provided with an oxide film, a wafer provided with a resist, or the like may be used in addition to a normal silicon wafer, emission monitoring associated with various processes can be performed.
Heretofore, the nine examples have been individually described, and in practical operation, when a lot (dummy lot) only composed of dummy wafers is prepared, and the diagnosis recipes shown in the above examples and the diagnosis programs associated with the recipes are allocated to the respective dummy wafers, for example, by processing the dummy lot once per day, most of preventive maintenance operations can be completed.
Number | Date | Country | Kind |
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2005-144043 | May 2005 | JP | national |