Abstract:
A cleaning tool for simultaneously abrading a contaminated surface and collecting contaminating particles and a method for using the same is provided the cleaning tool including an abrasive member including an abrasive surface said abrasive surface including a recessed area forming a collection space; said collection space in gaseous communication with at least one gaseous pathway; said at least one gaseous pathway passing longitudinally through a rotatably adjustable elongated handle rotatably attached to the abrasive member for adjustably varying an orientation angle defined by the elongated handle and the abrasive surface; whereby a suction force may be applied along the at least one gaseous pathway to collect particles loosened by the abrasive surface through the collection space.

Description:
FIELD OF THE INVENTION 
     This invention generally relates to cleaning apparatus and methods applied to the semiconductor processing arts and more particularly to a cleaning tool for removing contamination including small particles in a critical area such as a wafer chuck and wafer support plate in a photolithographic stepper. 
     BACKGROUND OF THE INVENTION 
     In semiconductor fabrication, various layers of insulating material, semiconducting material and conducting material are formed to produce a multilayer semiconductor device. The layers are patterned to create features that taken together, form elements such as transistors, capacitors, and resistors. These elements are then interconnected to achieve a desired electrical function, thereby producing an integrated circuit (IC) device. The formation and patterning of the various device layers are achieved using conventional fabrication techniques, such as oxidation, implantation, deposition, epitaxial growth of silicon, lithography, etching, and planarization. 
     Photolithography, for example, a lithographic technique for optically transferring a pattern including semiconductor device circuit features onto a substrate is widely used in the fabrication of semiconductor devices. Generally, photolithography involves the performance of a sequence of process steps, including coating a semiconductor wafer with a photoresist layer, exposing the photoresist layer to an activating light source through a photomask, developing the photoresist layer, processing the semiconductor wafer according to the developed photoresist layer, and removing the photoresist layer. An optical photolithography stepper, including those available from ASM Lithography, Inc., located in Eindhoven, Netherlands, is typically used to expose the photoresist layer. An image of a portion of an integrated circuit (IC) is formed on a small, rectangular piece of glass referred to as a reticle, or photomask. The photomask is placed on the stepper and a reduced image formed therethrough is projected onto a portion of the photoresist layer covering the semiconductor wafer. 
     Where numerous semiconductor devices are to be fabricated from a single wafer, a mask may be used several times over portions of the semiconductor wafer surface. This is accomplished by using a stepper to index, or step the wafer supported on a wafer stage under an optical system including the mask and projection lens, in the wafer plane by a predetermined pitch. At each step, a portion of the wafer surface including the photoresist is exposed by the optical system, for example, with ultraviolet light, to form an image of the mask in the layer of photoresist. Once the wafer surface has been stepped to expose the photoresist, the wafer is then removed from the stepper and the image developed. Further processing steps follow to create features forming a portion integrated circuit, including repeating the photolithographic process in each layer of a multi-layer semiconductor device. 
     In operation, at each step, or “cell”, the stepper performs a focusing operation, typically by altering the height of the wafer surface to achieve optimal focusing. To achieve optimal focusing over the entire surface of the wafer, the moveable stage, or chuck, on which the wafer rests and the wafer itself must be planar within the focal plane to a high degree of accuracy. For example, a particles smaller than 1 micron resting under the wafer surface between the stage and the wafer are enough to create a non-planer discontinuity or deformation in the wafer surface in the area where even one particle is. As a result, the area where the wafer is deformed will be out of focus causing loss of critical dimension in semiconductor device features. This effect is typically referred to as a “hotspot”, a “chuck spot” or a “chuck ring”. Such hot spots result in semiconductor devices with substandard features geometries, causing the entire wafer to be scrapped or the entire wafer reworked to correct the error. 
     In many cases, the particle that caused the defect adheres to the chuck itself, causing the defocusing error to be multiplied over several wafers until detected by visual or automated optical inspection. Consequently, both productivity and yield are detrimentally affected. 
     According to the prior art cleaning methods are generally used periodically to clean the wafer chuck. One problem with the prior art methods for cleaning, which generally involve manual methods for cleaning the wafer chuck, is that the cleaning process itself may contribute to particle contamination of the wafer chuck. For example, during the cleaning procedure, the wafer chuck including locating pins for slidably fitting into semiconductor wafer locating notches to hold the wafer in place are cleaned of contamination including loose particles. According to the prior art, the typical procedure is to use for example, a sponge to first wipe the wafer chuck manually with a solvent such as acetone prior to manually applying a cleaning abrasive, for example solid piece of Al 2 O 3 , to the surface to remove, for example, oxidation deposits and loosen adhering particles. During this manual process, the cleaning abrasive is typically hand held and abrading action applied to the wafer chuck surface. Frequently, during the manual cleaning process to remove contaminating particles, cleaning abrasive particles are dislodged from the cleaning abrasive causing additional contamination that must be removed in yet another cleaning step performed afterwards. Frequently, the is ineffective in removing all loose particles, including those that fall from the locating pins to the wafer chuck surface which are difficult to reach. As a result, the cleaning process has shortcomings including the additional cleaning step made necessary by use of the cleaning abrasive and the possibility that the manual cleaning process of the prior art will result in particle contamination of the wafer chuck surface from the cleaning process itself thereby leading to localized defocusing during the photolithographic exposure process. 
     There is therefore a need in the semiconductor processing art to develop an apparatus and method for more efficiently and effectively cleaning a wafer chuck used in a photolithographic exposure process thereby reducing particle contamination levels. 
     It is therefore an object of the invention to provide an apparatus and method for more efficiently and effectively cleaning a wafer chuck used in a photolithographic exposure process thereby reducing particle contamination levels while overcoming other shortcomings and deficiencies in the prior art. 
     SUMMARY OF THE INVENTION 
     To achieve the foregoing and other objects, and in accordance with the purposes of the present invention, as embodied and broadly described herein, the present invention provides a cleaning tool for simultaneously abrading a contaminated surface and collecting contaminating particles and a method for using the same. 
     In a first embodiment of the invention, a cleaning tool is provided including an abrasive surface said abrasive surface including a recessed area forming a collection space; said collection space in gaseous communication with at least one gaseous pathway; said at least one gaseous pathway passing longitudinally through a rotatably adjustable elongated handle rotatably attached to the abrasive member for adjustably varying an orientation angle defined by the elongated handle and the abrasive surface; whereby a suction force may be applied along the at least one gaseous pathway to collect particles loosened by the abrasive surface through the collection space. 
     These and other embodiments, aspects and features of the invention will be better understood from a detailed description of the preferred embodiments of the invention which are further described below in conjunction with the accompanying Figures. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1A is a cross sectional side view representation of the cleaning tool according to an exemplary embodiment of the present invention. 
     FIG. 1B is a top view representation of the cleaning tool abrasive surface according to an exemplary embodiment of the present invention. 
     FIG. 1C is a cross sectional side view representation of the cleaning tool according to an exemplary embodiment of the present invention. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     It will be appreciated that the method and apparatus is explained by reference to a cleaning process using an Al 2 O 3  abrasive applied to a wafer chuck used in a photolithographic stepping process, however the cleaning tool according to the present invention may be supplied with different types of abrasives and used in any cleaning process where it would be advantageous to use a cleaning abrasive to clean the target area while simultaneously removing additional contamination caused by the cleaning abrasive. 
     Referring to FIG. 1A, the cleaning tool  10  of the present invention includes an elongated handle  12 , having a rotatable means  14  on a first end of elongated handle  12  that rotatably connects the elongated handle  12  to an adjustable clamping means  16 . The adjustable clamping means  16  in turn is fixed to an abrasive means  18  having an abrasive means surface  20  such that both the adjustable clamping means  16  and the abrasive means  18  are rotatable around a rotating axis included in rotating means  14  the rotating axis being substantially parallel to the abrasive means surface  20  and substantially perpendicular to an axial direction of the elongated handle  12 . The adjustable clamping means  16  includes means for adjustably fixing an orientation angle the elongated handle  12  makes with the abrasive means surface  20  upon rotating the elongated handle  12  about the rotating axis included in rotating means  14 . Elongated handle  12  is supplied with a first gaseous pathway  12 A, for example, along the axial dimension of the elongated handle  12 , gaseously communicating through rotatable means  14  with a second gaseous pathway  18 A disposed through a central portion of abrasive means  18  to penetrate abrasive means surface  20  to form a suction opening  18 B. 
     In one embodiment, the abrasive means surface  20  includes a space, for example a concave surface having a radius surrounding the suction opening  18 B to form a collection space  22 . It will be appreciated that the collection space  22  may be of any suitable geometry allowing a vacuum suction force to be applied over a surface area for collecting small particles, for example, the collection space  22  may be cone shaped with the suction opening  18 B at the apex. Further, the edges of the collection space  22  at abrasive means surface  20  are preferably rounded to avoid sharp edged features that are potentially damaging to a target cleaning surface. 
     In another embodiment, when the cleaning tool is intended for use as a wafer chuck cleaning tool, the abrasive means  18  for example, preferably includes polycrystalline Al 2 O 3  at least one a cleaning surface, for example abrasive means surface  20  with a purity of, for example, greater than about 99.7 percent. Further, the abrasive means  18  is preferably a cylindrical shape having at least the contacting surface (abrasive means surface  20 ) smoothed along the peripheral edges to form a curvature radius to prevent damage from sharp edged surface features. 
     Referring to FIG. 1B showing a top view of the abrasive means  18 , the abrasive means surface  20  may range, for example, from about 3 to about 5 cm in diameter, more preferably about 4 cm in diameter, with the diameter of the suction opening  18 B for providing a vacuum suction force to the abrasive means surface through collection space  22  ranging from about 0.5 cm in diameter to about 1.5 cm in diameter, more preferably about 1 cm in diameter. Further, the collection space  22  formed in abrasive means surface  20  surrounding the suction opening  18 B, is preferably centrally disposed around suction opening  18 B forming for example, a concave depression that may, for example, range from about 1 cm in diameter to about 2 cm in diameter, with for example, a depth measured from the planar portion of abrasive means surface  20  of about 0.25 cm to about 0.5 cm. It will be appreciated that the size and depth of collection space  22  may vary depending on the cleaning operation to be performed and the suction force of the vacuum applied. For example, the collection space area may be increased thereby spreading the vacuum suction force over a larger area while correspondingly increasing a vacuum suction force supplied by a vacuum source. The collection space  22  together with the vacuum suction force is preferably sized to collect for example, Al 2 O 3  particles having nominal diameters of at least less than about 10 microns resting on a surface. 
     Referring to FIG. 1C is an expanded view showing an exemplary embodiment of the rotatable means  14  including adjustable clamping means  16 , for rotating the abrasive means  18  about a rotating axis substantially perpendicular to the elongated handle  12 . The rotatable means preferably allows rotation such that an orientation angle theta formed between the abrasive means surface  20  and the elongated handle may be varied from about 0 degrees to at least about 90 degrees. The rotatable means  14 , for example is a hollow cylinder (bearing)  30 A closed at both ends and fixed to the elongated handle  12  such that the axis of the hollow cylinder  30 A is perpendicular to the elongated handle  12  axis disposed along the first gaseous pathway  12 A communicating with a first opening  12 B through the hollow cylinder  30 A which in turn communicates with second gaseous pathway  18 A as further explained below. The hollow cylinder (bearing), for example may be disposed in a bearing seat  30 B housed in a clamping means  16 . The clamping means  16  may be any conventional means for fixing the rotation of the hollow cylinder (bearing)  30 A in the bearing seat  30 B to fix an orientation angle theta formed between the elongated handle  12  and the abrasive means surface  20 , including for example, a set screw  32  disposed through a bearing housing  34  along a radial rotation path  34 A for tightening the elongated handle  12 . It will be appreciated that the bearing  30 A and bearing seat  30 B may also form, for example, a ball and socket configuration. The second gaseous pathway  18 A forms gaseous communication with the first gaseous pathway  12 A through the rotatable means  14 , for example, by a second opening  18 C extending through the bearing seat to communicate with a slot  12 C formed along the radial rotation path of the hollow cylinder (bearing)  30 A to form continuous gaseous communication with the hollow cylinder (bearing) and first gaseous pathway  12 A during rotation. For example, the slot  12 C may be formed in about a half circle through the hollow cylinder (bearing)  30 A along a radial rotation pathway, that portion of the slot adjacent the bearing seat forming a closed communication with the bearing seat excepting that portion overlying the second opening  18 C in bearing seat to form open communication with second gaseous pathway  18 A and first gaseous pathway  12 A as indicated by gaseous flow directional arrow  18 D. 
     The elongated handle  12 , the rotatable means  14 , and clamping means  16  may be formed of, for example, stainless steel. Referring again to FIG. 1A, the distal end of the elongated handle  12  may include a vacuum tight fitting for attaching a flexible hose  26  connected to a vacuum source (not shown) for supplying a vacuum suction force through the elongated handle  12  to the collectible space  22 . It will be appreciated that the flexible hose  26  may alternatively extend into gaseous pathway  12 A and be housed thereby. 
     In operation, for example, elongated handle  12  is adjusted to an advantageous orientation angle theta for performing a cleaning operation. A vacuum source is supplied to flexible hose  26  to supply a vacuum suction force through first gaseous pathway  12 A, rotatable means  14  and second gaseous pathway  18 A to create a suction force extending through suction opening  18 B and applied to collection space  22 . The cleaning tool is then applied to the target cleaning surface, for example a wafer chuck including locating pins. In exemplary operation, the cleaning tool  10  with abrasive means surface  20 , for example polycrystalline Al 2 O 3 , including collection space  22  is carefully applied to the wafer chuck including the locating pins to lightly abrade the contaminated surface. As contaminating particles are dislodged by the abrading action from the wafer chuck including the tips of locating pins the vacuum suction force created in collection area  22  collects the contaminating particles, the contaminating particles including an occasional dislodged particle from the Al 2 O 3  surface. The contaminating particles are collected from the target surface and transported through suction opening  18 B along second gaseous pathway  18 A through rotatable means  14  and gaseous pathway  12 A to a vacuum source where they may be collected by a filtering means. 
     According to the cleaning tool of the present invention, an apparatus and method for cleaning, for example, a wafer chuck included in a photolithographic stepping apparatus has been presented thereby providing a cleaning tool and procedure with greater efficiency and effectiveness compared to the prior art. As a result, the shortcomings of the prior art leading to loose particle contamination causing localized defocusing and a consequent reduction in semiconductor wafer yield are minimized while providing decreased preventative maintenance downtime and increased semiconductor wafer yields. 
     The preferred embodiments, aspects, and features of the invention having been described, it will be apparent to those skilled in the art that numerous variations, modifications, and substitutions may be made without departing from the spirit of the invention as disclosed and further claimed below.