Abstract:
A system of cleaning a CMP pad used for removing copper from a substrate, the system comprising an abrasive cleaning pad, a cleaning solution delivery system that delivers a cleaning solution, an analyzing system that monitors the characteristics of the cleaning solution optically and chemically, and a carriage that allows the analyzing system to monitor the cleaning solution at a plurality of locations on the CMP pad. The use of the abrasive cleaning pad and the cleaning solution removes contaminants from the CMP pad, and the contaminants are dissolved in the cleaning solution. By measuring the concentration of contaminants in the cleaning solution, the condition of the CMP pad can be monitored. To measure the concentration of the contaminants, changes in the refractive index and absorption of light in the cleaning solution are measured, wherein the refractive index and absorption depend on the concentration of the contaminants. The concentration of the contaminants in the cleaning solution is also measured chemically. Knowing the actual condition of the CMP pad during the cleaning process allows for improved condition of the CMP pad.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to semiconductor processing technology and, in particular, concerns a method of cleaning and monitoring pads used in planarizing of the surfaces of a wafer using chemical mechanical polishing. 
     2. Description of the Related Art 
     Chemical mechanical polishing or planarization (CMP) is a technique whereby surfaces, such as semiconductor substrates, are planarized by the simultaneous application of both etching and polishing processes. CMP is typically used to globally planarize surfaces such as the upper surface of a semiconductor wafer. The wafer is typically positioned within a carriage and is rotated with respect to a polishing pad. In one approach, a slurry containing abrasive particles and an etchant is interposed between the polishing pad and the surface of the semiconductor wafer that is to be planarized. The polishing pad is then brought into contact with the surface of the wafer that is to be planarized and the combination of the mechanical polishing and the etchant results in the exposed surfaces of the wafer being removed by the CMP process. 
     One specific technique of CMP, known as copper CMP (CuCMP), is used to remove copper (Cu) from the wafer surface. CuCMP is presently used extensively in conjunction with a copper application technique known as copper Damascene process. One method of laying metal lines and interconnects in the integrated circuits is to form a layer of metal on the wafer and chemically etch away the metal. Copper is the metal of choice over other metals such as aluminum and tungsten, due to its desirable electrical properties. Copper, however, is difficult to use in the etching technique due to its high susceptibility to corrosion during the process. Corrosion leads to unpredictable electrical properties of the resulting copper interconnects, thus making copper essentially unusable for such an application. The copper Damascene process overcomes the corrosion problem by depositing copper directly into the groove patterns of interconnects already formed within the dielectric layer of the wafer. Since the copper is not etched away chemically, copper corrosion is no longer a problem. The excess copper from the Damascene process is removed by CuCMP. 
     As any material is removed globally from the surface of the wafer, it is desirable to be able to stop the CMP process after a predetermined amount has been removed. Endpoint technique is a method of stopping the CMP process after a right amount of material has been removed. Typically, endpoint techniques rely on frictional properties and/or light reflecting properties of the surfaces involved in the CMP process. As a layer of material is being removed from the wafer, that layer exhibits certain friction and reflectivity. When that layer is polished off and a new layer is exposed, friction between the pad and the wafer surface changes. Also, the reflectivity of the surface changes when the new layer is exposed. The CMP system can detect either or both of these changes and establish an endpoint. One of the parameters that aids in accurate endpoint technique is the removal rate that depends on the condition of the polishing pad. 
     One of the problems associated with the CuCMP is that slurries used in the CuCMP process are highly reactive with copper, and the various copper byproducts end up being lodged in the pad. As the copper is removed, copper byproducts are formed and begin to clog the pores and grooves on the pad. As the pores and the grooves get clogged, the slurry cannot flow uniformly throughout the surface of the pad, and glazing may occur at various locations, thus causing a non-uniform removal rate of the pad. To overcome this problem, pads are typically cleaned prior to use on a wafer. 
     Pad cleaning involves restoring the surface of the pad followed by chemically rinsing away the copper byproducts from the pad. The surface is restored typically by using a diamond grinding disk that comes into contact with the pad in a manner similar to that of the silicon wafer being planarized. The abrasive diamond grinding disk breaks up any glaze that may have formed on the pad&#39;s surface, and also restores a desired roughness of the pad&#39;s surface. Once the surface is mechanically restored, residual particles and the copper byproducts from the pores and grooves are dissolved away using a rinse solution. A typical rinse solution comprises a 5% ammonium citrate solution. 
     Despite cleaning prior to each use, pads used in CuCMP still show drifts in removal rate, and recent data show that amount of copper byproducts absorbed in the pad increases over time as the pad is cycled between cleanings and uses. Some of the methods used to measure such data are disclosed in technical publications such as “Cu dissolution from Si(111) into an SC-1 process solution”, D. Chopra et al., Journal of Electrochemical Society, Vol. 145, No. 4, 1998, and “An optical method for monitoring metal contamination during aqueous processing of silicon wafers”, D. Chopra et al., Journal of Electrochemical Society, Vol. 145, No. 5, 1998. Such measurements indicate that the present method of cleaning of pad does not remove the copper byproducts sufficiently. Furthermore, a fabricator using a typical conventional pad cleaning method does not know the actual condition of the pad. 
     While the current method of cleaning the pads for use in CuCMP process does remove copper byproducts, it is desirable that there be a more consistent method of cleaning and monitoring the pad. In particular, it is desirable to have a method of determining the concentration of the copper byproducts lodged in the pad accurately so that a fabricator can better understand the cleaning process so as to form an endpoint technique in the cleaning process. Additionally, it is desirable to map out the condition of the entire pad boundary so as to be able to achieve uniform cleaning that will lead to uniform removal of material from the wafer. By knowing the copper byproduct concentration over the entire boundary of a given pad, a proper cleaning and a proper endpoint technique can be worked out for that particular pad to yield a predictable and uniform removal rate, thus yielding a higher quality planarized wafer. 
     SUMMARY OF THE INVENTION 
     The aforementioned needs are satisfied by a system for cleaning a chemical mechanical polishing (CMP) pad. According to one aspect of the invention, the system comprises a CMP pad that is used to perform the CMP process on a device. The system further comprises a carriage that holds the device such that the CMP pad and the carriage are rotatable with respect to each other so as to allow the device to come in contact with the CMP pad. The system further comprises a slurry supply system that supplies slurry to the interface between the CMP pad and the device such that the combination of the slurry and the rotational movement between the CMP pad and the device results in removal of material from the device. The system further comprises a cleaning pad that rotates with respect to the CMP pad, and a cleaning solution supply system that supplies cleaning solution to the interface between the cleaning pad and the CMP pad. The combination of the cleaning solution and the rotational movement between the cleaning pad and the CMP pad results in removal of contaminants from the CMP pad. The system further comprises a cleaning solution analyzing system that analyzes the cleaning solution after the cleaning solution has been introduced to the interface between the CMP pad and the cleaning pad and determines, based upon the analysis the cleanliness of the CMP pad. 
     In the preferred embodiment of the invention, the material removed from the device is copper metal, and the CMP pad and the slurry are adapted to remove copper from the device. The cleaning pad is an abrasive diamond impregnated disk, and the cleaning solution comprising 5% ammonium citrate spiked with nitric acid is adapted to remove the copper oxides from the CMP pad. The cleaning solution analyzing system comprises an optical analyzing system and a chemical analyzing system. The optical analyzing system comprises a light source and a light detector. The light source directs a light into the cleaning solution towards the light detector, wherein the light detector detects changes to the light induced by the cleaning solution. One change induced by the cleaning solution is a change in the refraction of the light due to refractive index being dependent on concentration of ions from the contaminants. Another change induced by the cleaning solution is a change in the absorption of the light, wherein the absorption depends on the concentration of the contaminants. The chemical analyzing system samples the cleaning solution and also determines the concentration of the contaminants. 
     Another aspect of the invention comprises a system for analyzing the cleanliness of a CMP pad that is cleaned by a combination of mechanical abrasion and a cleaning solution. This analyzing system comprises a light source that projects a beam of light into the cleaning solution flow after the cleaning solution has been introduced onto the CMP pad during and after the mechanical abrasion. The analyzing system further comprises a detector that receives the light from the light source, and a controller that receives signals from the detector that are indicative of at least one characteristics of the light that is travelling through the cleaning solution flow. The controller determines the cleanliness of the CMP pad based upon the signals received from the detector. 
     In the preferred embodiment of the analyzing system, the beam of light is a beam of HeNe laser, and the detector is a pin-diode array that can resolve the detected beam of light spatially and by intensity. The signals from the detector comprise a change in the location and a change in the intensity of the detected beam of light, wherein the changes are induced by refraction and absorption of the light, respectively, in the cleaning solution flow in a manner described above. 
     In a preferred method of cleaning a CMP pad to remove contaminants, a cleaning pad is positioned adjacent the CMP pad and moved relative the CMP pad. Preferably, the cleaning pad is an abrasive diamond disk. As the cleaning pad is moved relative the CMP pad, a cleaning fluid is provided to the interface between the cleaning pad and the CMP pad so as to facilitate the cleaning. Preferably, the fluid comprises 5% ammonium citrate spiked with nitric acid. During the cleaning process, the cleaning fluid is evaluated to determine the condition of the CMP pad. Preferably, measurements of optical properties and chemical composition of the cleaning fluid yield a fluid characteristic value that is indicative of the condition of the CMP pad. Specifically, a change in the refractive index of the fluid is indicative of a change in the concentration of contaminants in the fluid. Also, a change in the absorption of light in the fluid is indicative of a change in the concentration of contaminants in the fluid. Preferably, measurement of the concentration of the contaminants in the fluid is performed chemically also. 
     From the foregoing, it will be appreciated that the process of the present invention allows for cleaning of the CMP pad in a manner such that the cleanliness of the CMP pad can be monitored. These and other objects and advantages of the present invention will become more apparent from the following description taken in conjunction with the accompanying drawings. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a schematic illustration of an exemplary CMP device; 
     FIG. 2A is a schematic illustration of a CuCMP process about to remove excess copper from a surface of a wafer after copper was deposited by a Damascene process; 
     FIG. 2B is a schematic illustration of the planarize wafer after removing the excess copper by the CuCMP process; 
     FIG. 3 is a schematic illustration of a CMP pad being cleaned by an abrasive disk such as a diamond disk; 
     FIG. 4A is a schematic illustration showing a perspective view of the pad being chemically cleaned by a chemical solution to dissolve the contaminants in the pad; 
     FIG. 4B is a schematic illustration showing a side view of FIG. 4A; 
     FIG. 4C is a schematic illustration showing a plan view of FIG. 4A; 
     FIG. 5A is an illustration of an exemplary plot of copper ion concentration in the chemical solution as a function of time during the chemical cleaning of the pad; 
     FIG. 5B is a plot of intensity of light that has passed through the chemical solution as a function of time corresponding to the process illustrated in FIG. 5A; 
     FIG. 6 is a schematic illustration showing a carriage that allows cleaning system to be moved with respect to the pad; and 
     FIG. 7 illustrates an exemplary scale that grades cleanliness of the pad based on the of copper concentration in the chemical solution. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Reference will now be made to the drawings wherein like numerals refer to like parts throughout. FIG. 1 schematically illustrates a manner in which chemical mechanical polishing (CMP) is often performed on a semiconductor wafer  210 . As shown in FIG. 1, a typical CMP system  200  includes a rotating polishing pad  201  that is rotated by a shaft  202  attached to a motor (not shown). The pad  201  may comprise a relatively soft and porous material, such as a plastic like polyurethane, and a slurry  205  is provided by a supply tube  204  to the pad  201  while the pad  201  is rotated. The slurry  205  provided by the tube  204  is typically comprised of an abrasive material, such as alumina or silica particles, that is encapsulated within an etchant liquid and also, possibly, a suspension fluid. The exact composition of the slurry  205  will vary depending on the material that is to be removed from the wafer via the CMP process. The slurry is typically distributed throughout the pad  201  by a plurality of grooves formed in the pad  201 , and the porous material of the pad  201  retains the slurry during the CMP process. 
     The CMP system  200  also includes a rotatable wafer carrier  206  that is rotatable about a shaft  208  by a motor (not shown). The wafer  210  is attached to the carrier  206  so that the wafer  210  can be positioned against the pad  201  in the manner schematically illustrated in FIG.  1 . The wafer carrier  206  and the pad  201  are moveable with respect to each other so that the plane of the pad  201  can be positioned against the plane of the wafer  210  that is positioned within the carrier  206 . When the wafer  210  is positioned proximate the pad  201 , the surface of the wafer  210  adjacent the pad  201  is preferably planarized by the combination of the abrasive polishing the surface of the wafer  210  and the etchant of the slurry  205  chemically interacting with the materials on the exposed surface of the wafer  210 . 
     The CMP process removes material from the wafer  210  until an endpoint is reached. The endpoint occurs when a desired amount of material has been removed from the wafer  210 . One technique of determining the endpoint is to monitor the friction between the pad  201  and the wafer  210 . Endpoints are typically situated near the boundaries of layers, where each layer is composed of different material. Friction between the pad  201  and the surface of the wafer  201  is measurably different for the different materials at the surface of the wafer  201 . Thus, a change in the friction between the pad  201  and the wafer  210  is indicative of a boundary being crossed, at which point the endpoint is reached. Change in the friction between the pad  201  and the wafer  210  is detected by monitoring the currents that are drawn by the motors used to rotate the pad  201  and the wafer  210 . 
     Another technique of determining the endpoint is to detect a change in the reflectivity of the surface of the wafer  210  as material is being removed. Different surface materials have measurably different reflectivity values that can be measured in a manner known in the art. Thus change in the reflectivity at the surface of the wafer  210  is indicative of having reached the endpoint. 
     One type of material often removed by CMP from the wafer  210  is metal. Metals are used in semiconductor wafers  210  to form interconnects in integrated circuits. Copper is the metal of choice as far as electrical properties are concerned; however, copper is not applied using typical methods of metal application to the wafers  210 . A typical method of metal application to the wafer  210  for metals such as aluminum and tungsten is to first deposit a layer of the metal on the surface of the wafer  210 . Using a lithography method well known in the art, the metal layer is selectively chemically etched away to leave patterns of interconnects. The chemicals typically used in most metal etching processes are often highly corrosive to the copper metal, resulting in interconnects with unpredictable electrical properties. Because of copper&#39;s susceptibility to corrosion to the etching chemicals, copper is generally not applied to form conductors using typical lithography pattern and etch methods. 
     Recent developments in semiconductor fabrication techniques have increased the use of copper. A process known as Damascene process allows forming of interconnects in the wafers  210  without using the lithography technique described above. In the Damascene process, groove patterns are formed in a dielectric layer of the wafer  210 , such that the groove patterns match the desired interconnect patterns. Metal is then deposited directly into the grooves such that once the grooves are filled, the desired interconnects are formed without the etching chemical intervention. Thus, the Damascene process allows for the use of copper to form the interconnects. Excess metal layer at the top of the filled grooves is removed by the CMP process. In particular, a specific type of the CMP process known as copper CMP (CuCMP) is used in conjunction with the Damascene process involving copper. As the name implies, CuCMP is geared towards removal of copper from the surface of the wafer  210 . 
     It will be appreciated that the Damascene process is not restricted to application of copper. Furthermore, CuCMP process is not restricted to use in conjunction with the Damascene process. However, due to the great advantages afforded by the use of copper and the Damascene process, copper usage is generally associated with the Damascene process, and in turn, CuCMP is generally associated with the Damascene process. 
     FIGS. 2A and 2B schematically illustrate the CuCMP process. As illustrated in FIG. 2A, a dielectric layer  302  is initially positioned on a substrate  301  using typical deposition techniques. The dielectric layer  302  can consist of any of a number of insulative materials such as silicon oxide (SiO 2 ). After the dielectric layer  302  is formed, a conductor receiving space, such as a groove  304  is formed in the dielectric layer  302  using well known patterning and etching processes. The conductor receiving space in this embodiment is comprised of a groove for a lateral interconnect. However, it will be appreciated that the conductor receiving space can comprise such things as grooves, vias and the like without departing from the spirit of the present invention. 
     In FIG. 2A, the surface of the wafer  210  has gone through the Damascene process, and one of the plurality of grooves is illustrated. The groove  304  in the dielectric substrate  302  is filled with copper  306  by the Damascene process such that copper is globally deposited over the dielectric layer  302  using a known metal deposition technique in the manner described above. A layer of excess copper  307  is about to be removed by the pad  201  using a known CuCMP process. FIG. 2B illustrates the wafer  210  after the CuCMP process has reached the endpoint, where the excess copper layer  307  has been removed completely to yield a planarized surface  312 . As is illustrated in FIG. 2B, the excess copper  307  is removed until the end-point determination technique has indicated that the upper surface  312  of the dielectric layer  302  has been exposed. 
     One of the problems associated with the CuCMP process is that the slurries  205  used are highly reactive with copper, and various copper byproducts end up being lodged in the pad  201 . The copper byproducts, such as copper oxides CuO and Cu2O, clog the grooves and the pores at the surface of the pad  201  such that the slurry  205  does not get distributed evenly and be retained by the pad  201 . Furthermore, the pad  201  may form a glazed surface when used for a period of time with poorly circulated slurry  205 . Degradation of the pad  201  results in the removal rate and the uniformity of the pad  201  being unpredictable, both of which are critical for accurate endpoint determination and quality of the planarized surface. To overcome this problem, pads  201  laden with copper oxides are cleaned prior to use on the wafers  210 . 
     Typical cleaning of the pad  201  comprises two stages. First, the pad  201  is mechanically cleaned by an abrasive surface such as a diamond disk  316 , as schematically illustrated in FIG.  3 . In this process, the diamond disk  316  attached to a grinder arm  317  that is adapted to allow the diamond disk  316  to rotate, move over the surface of the pad  201 , and come in contact with the pad  201 . The grinding action of the diamond disk  316  removes the glaze that may have formed at the surface of the pad  201 , and also leaves a desired “roughness” on the surface. During the grinding process, a rinse solution is introduced between the diamond disk  316  and the pad  201  to rinse away the debris removed, and to aid in obtaining the desired texture of the pad  201 . 
     Following the first stage of mechanical cleaning of the surface, the pad  201  is further cleaned by a chemical cleaning solution  324  as schematically illustrated in FIG.  4 A. The cleaning solution  324 , such as a 5% ammonium citrate solution, is introduced to the surface of the pad  201  through a rinse arm  322 . The pad  201  rotates as indicated to distribute the cleaning solution  324  that is being continuously introduced such that a cleaning solution layer  326  runs off the pad  201  as indicated by flow patterns  325 . Typically, this process continues for a predetermined amount of time, and the copper oxides are dissolved out of the pores and the grooves of the pad  201 . One aspect of the preferred embodiment of the present invention is illustrated in FIG. 4A to monitor the cleaning process, and is described in detail below. 
     Despite such cleaning comprising two stages prior to each use, pads  201  used in CuCMP process still have a tendency to drift in removal rate and uniformity. Recent data show that amount of copper oxides retained in the pad  201  increases over time as the pad  201  is cycled between cleanings and uses, indicating that the present method of cleaning pads does not remove the copper oxides sufficiently. Furthermore, removal of copper oxides from the pad  201  is not well understood, such that the actual condition of the pad  201  is not known accurately prior to use. 
     FIGS. 4A,  4 B, and  4 C schematically illustrate one aspect of the preferred embodiment of the present invention that monitors the chemical cleaning described above. FIG. 4A depicts a perspective view of a pad cleaning system  320 . The cleaning system  320  comprises the rinse arm  322  that delivers the cleaning solution  324  to the pad  201  at a fixed rate. The cleaning system  320  further comprises the pad  201  that is attached to a carriage (not shown) so as to allow the pad  201  to rotate with respect to the rinse arm, as indicated in FIG.  4 A. The rotating motion of the pad  201  allows the cleaning solution  324  to be distributed evenly on the surface of the pad  201 , and chemically clean the pad in a manner described in detail below. As the cleaning solution  324  is added to the pad  201 , excess fluid is allowed to run off the edge of the pad as depicted by the flow patterns  325 . The cleaning system  320  further comprises a monitoring assembly  330  that is described in detail below. 
     The cleaning solution  324  is delivered to the surface of the rotating pad  201  through the rinse arm  322  at a fixed rate, such that a layer of cleaning solution  326  is formed on the surface of the pad  201 , and excess fluid runs off the edge of the pad  201 . This layer of cleaning solution  326  is better illustrated in FIG.  4 B. The monitoring assembly  330  comprises a light analyzer ( 332 ,  334 ,  342 ,  336 ) and a chemical analyzer  337  to determine the state of the cleaning process. The light analyzer comprises a light source  332 , light beams  334  and  342 , a light detector  336 , and a monitor carriage ( 348  shown in FIG. 6) adapted to allow the light source  332  and the light detector  336  to be moved with respect to the wafer  201 . The chemical analyzer  337  analyzes the excess fluid that runs off the edge of the pad  201  in a manner described below. 
     In operation of the light analyzer, the light source  332  projects a beam of light  334  that enters the layer of cleaning solution  326  as illustrated in FIG.  4 B. The beam of light  334  is refracted in the layer of cleaning solution  326  according to the refractive index of the solution layer  326 . Refraction of the beam of light  334  yields a refracted beam  342  in the solution  326 . In FIG. 4C, the refracted beam  342  is shown in relation to a projected line  344  that is an extension of the beam of light  334 . The refracted beam  342  exits the solution  326  and is detected by the light detector  336 . The monitoring assembly  330  is adapted such that the light detector  336  can detect the amount of deflection of the refracted beam  342 , from which the refractive index of the solution  326  can be determined. 
     A controller  338 , as illustrated in FIGS. 4A,  4 B, and  4 C, controls the operation of the monitoring assembly  330 . The outputs from the chemical analyzer  337  and the light detector  336  are processed by the controller  338  to determine the condition of the pad  201 . 
     In the preferred embodiment of the invention, the light source  332  is a laser such as a HeNe laser, and the light detector  336  is a pin diode array (PAD) capable of spatially resolving small changes in the deflection of the beam  342 . The fresh cleaning solution  324  is a 5% ammonium citrate rinse solution spiked with nitric acid. As the layer of cleaning solution  326  dissolves the copper oxides from the pad  201 , the copper ion concentration in the solution  326  increases. In general, an increase in ion concentration in an aqueous solution increases the refractive index of the solution in a linear fashion up to a certain point. Thus, as the copper ion concentration increases in the solution  326 , the refractive index increases, and the refracted beam  342  is deflected more. The monitoring assembly  330  can therefore monitor the copper ion concentration of the solution continuously. 
     FIG. 5A illustrates a plot of copper ion concentration in the solution  326  as a function of time during the chemical cleaning process. At the beginning of the cleaning process, denoted by time T0 in FIG. 5A, fresh cleaning solution  324  is introduced onto the surface of the pad  201 , and forms the layer of solution  326 . The solution  326  begins to dissolve the copper oxides from the pad  201  to form copper ions in the solution  326 . As the fresh cleaning solution  324  is continuously added onto the surface of the pad  201  at a constant rate, the ion concentration in the solution  326  will be diluted. At the same time, the copper ions are being generated from dissolving of the copper oxides from the pad  201 . The net effect is an increase in the ion concentration in the solution  326 , as depicted by curve  352  in FIG. 5A, until a steady state is reached at time T1. This is a state where the rate of dilution is equal to the rate of ion production, and the ion concentration essentially remains constant during this phase, as depicted by curve  353  between T1 and T2. As the solution  326  dissolves away the copper oxides from the pad  201 , the pad  201  becomes cleaner, and the copper oxides content of the pad  201  begins to decrease, resulting in decrease of the ion production rate. Thus, the net ion concentration in the solution  326  decreases, as shown by curve  354  between T2 and T3, until the ion concentration levels off to a background level depicted by curve  355 . Beyond time T3, the ion production rate is negligible compared to the dilution rate, and the pad  201  is now “clean” as far as removal of copper oxides is concerned. 
     Knowing the ion concentration in the solution  326  allows determination of an endpoint for the chemical cleaning. FIG. 5A illustrates an exemplary endpoint situated at time T3 where the ion concentration has been restored to the background level similar to that encountered at time T0. 
     The light detector  336 , in addition to spatially resolving the refracted light  342 , is sensitive to the intensity of the light it detects. Typically, absorption of light is proportional to the concentration of dissolved ions in a solution. Thus, the intensity of detected light at the light detector  336  is indicative of the ion concentration in the layer of solution  326  in an inverse manner. A plot of detected light intensity as a function of time, as depicted in FIG. 5B, shows a behavior that tracks the plot of ion concentration as a function of time (FIG. 5A) in an inverse manner. Thus, the intensity measurement gives a second measurement to monitor the chemical cleaning process. 
     Furthermore, as illustrated in FIGS. 4A and 4B, the monitoring assembly  330  includes the chemical analyzer  337  that analyzes the excess fluid that runs off the pad  201 . The chemical analyzer  337  also monitors the concentration of copper ions in the layer of solution  326 . This independent measurement of the copper ion concentration is used to further aid the determination of the endpoint for the chemical cleaning. 
     Aside from being able to clean the pad  201  with accurate endpoint, the pad cleaning system  320  allows determination of the overall condition of the pad  201 . The duration of the steady state (time between T2 and T1 in FIGS. 5A and 5B) of the ion concentration curve is indicative of how “dirty” the pad  201  was before the chemical cleaning. Longer duration of the steady state means more copper oxides had to be dissolved away. 
     FIG. 6 schematically illustrates the preferred embodiment of the invention further comprising the monitor carriage  348  and a monitor carriage arm  349  adapted so as to allow the monitor assembly  330  (FIG. 4C) to be moved with respect to the pad  201 . The monitor carriage  348  further adapted so as to allow the chemical analyzer  337  to move along the monitor carriage  348  as indicated by an arrow  347 , wherein the position of an input receptacle of the chemical analyzer  337  that collects the runoff cleaning solution is preferably always at the edge of the pad  201 . An exemplary motion of the monitor carriage  348  is illustrated by an arrow  346 . In one embodiment of the invention, the pad may stop rotating, and the monitor carriage  348  sweeps half of the pad  201  starting from the right side to the middle of the pad  201 . Then, the pad  201  is rotated partially in the direction indicated by an arrow  345 , and the monitor carriage  348  again sweeps half of the pad  201 . This process continues until substantially all of the pad  201  is swept by the monitor carriage  348 . This allows the cleaning system  320  to sample one area of the pad  201 , or many areas of the pad  201  by selectively moving the monitor assembly  330  over that pad  201  to map the condition of the pad  201 . The mapped condition of the pad  201 , determined by the methods utilizing refraction, absorption, and chemical analysis as described above, further aids the operator to work out the proper endpoint method so as to improve the process and result of the CuCMP. 
     It will be appreciated that in one embodiment of the invention, the CMP system illustrated in FIG. 1, the mechanical pad cleaning system illustrated in FIG. 3, and the chemical pad cleaning system illustrated in FIGS. 4A,  4 B,  4 C, and  6  may be adapted so as to allow all three systems to be integrated into a single unit. 
     FIG. 7 illustrates a scale of copper concentration in the layer of solution  326  adjacent the pad  201 , indicating typical cleanliness markers. Copper concentration of 2.4 parts per million (ppm) or less for some applications is considered to be clean. A value of 3.3 ppm is considered to be a normal usable cleanliness for these applications, whereas a value of 11.4 ppm is considered to be high. A value of 19.9 ppm is considered to be very high. In practice, a uniform copper concentration throughout the pad  201 , anywhere in the range between 3 and 11 ppm usable for uniform planarization. The pad  201  with copper concentration of 3 ppm throughout would be considered ideal. Also, the pad  201  with copper concentration of 11 ppm throughout, while not as ideal as that with 3 ppm, is still usable for obtaining uniform planarization. On the other hand, the pad  201  that exhibits a gradient in the copper concentration throughout the pad  201  will yield non-uniform planarization. For example, even though the range of 3 to 11 ppm is considered to be usable, the pad  201  that has a center to edge gradient of 8 ppm (3 to 11 ppm) may lead to unacceptable uniformity result. 
     Thus, it will be appreciated that the preferred embodiment of the present invention allows not only globally monitoring the chemical cleaning of the pad  201 , but also the profile of the cleanliness throughout the pad  201 . As such, the operator can establish the endpoint that corresponds to the actual condition of the pad  201 . 
     Although the foregoing description of the preferred embodiment of the present invention has shown, described and pointed out the fundamental novel features of the invention, it will be understood that various omissions, substitutions and changes in the form of the detail of the apparatus illustrated, as well as the uses thereof, may be made by those skilled in the art without departing from the spirit of the present invention. Consequently, the scope of the invention should not be limited to the foregoing discussion, but should be defined by the appended claims.