Patent Document

BACKGROUND OF THE INVENTION 
     The present invention generally relates to the treatment of a substrate surface. Surface treatment, for example oxidizing, cleaning, or planarizing a substrate surface, is a critical operation, especially in the semiconductor industry, where irregularities within a surface or foreign contaminants on the surface can cause device failure. The sensitivity to foreign matter on the surface and to irregularities within the surface is increased as device sizes shrink in the semiconductor industry. Foreign matter as small as sub-micron particles can destroy a semiconductor integrated circuit. Furthermore, when a surface treatment is being carried out, it is desirable that the treatment does not otherwise damage the substrate surface being treated. 
     An example of foreign matter which commonly must be removed from a surface in the semiconductor industry is organic material. Photoresist is an example of an organic material frequently used in the semiconductor processing industry. After a photoresist film has been used to create a mask on a semiconductor surface being processed, it is generally necessary that the photoresist film be completely removed before subsequent fabrication processes may be carried out. The complete removal of the photoresist film is made more difficult when the photoresist film becomes hardened on the substrate surface. Hardening of the photoresist film occurs when the photoresist film is exposed to a plasma environment or ion implantation, two common fabrication processes. Incompletely removed photoresist can cause device failures. 
     It is commonly known that organic contaminants may be removed by ultraviolet (uv) cleaning. Ultraviolet light, which is defined by the wavelength range of 4 nm to 380 nm, has been known to decompose organic molecules. Another method known in the art which is useful for removing or assisting in the removal of unwanted organic material is the chemical oxidation of these organics. 
     Processes and apparatus for using uv light to decompose organic molecules and treat a substrate surface are known in the related art. The related art also provides a method for the generation of ozone for use in surface treatment. The production of ozone from high voltage discharges between metal electrodes, however, frequently produces metal ion contaminants unsuitable for the semiconductor processing industry. A further shortcoming of the prior art is that separate sources of energy are required for ozone production and uv light surface treatment. 
     SUMMARY OF THE INVENTION 
     The present invention embodies both the method and apparatus for the treatment of a substrate surface, by generating ozone, utilizing the ozone for surface treatment and using a light energy source for additionally treating the substrate surface. The invention includes at least one optical source having an optical path. The light energy source used for surface treatment in the treatment chamber may be the same light energy source used to generate ozone in a separate generation chamber. 
     The present invention includes at least two distinct chambers: An ozone generation chamber containing oxygen and disposed along the optical path of the optical source; and a surface treatment chamber. Ozone generation and surface treatment may occur simultaneously. The chambers may be separated by a quartz plate to provide for a single optical source to be used for the simultaneous surface treatment in the treatment chamber and ozone generation in the generation chamber. The surface treatment of the present invention may involve oxidation, cleaning, planarization, or a combination of the three. 
     The generation chamber includes optical condensing means which function as a collimator to focus the optical energy source into a focal point where ozone is generated. Ozone produced in this manner is free of the undesirable metal ion contaiminants associated with ozone generation between metal electrodes using high voltage. 
     The generated ozone is withdrawn from the generation chamber and transported to the treatment chamber to chemically assist in the surface treatment. The ozone gas may be mixed with another constituent prior to its introduction into the treatment chamber, or the ozone and constituent may be intermixed with each other once both have been transported to the treatment chamber. The other component may be a gas, a liquid, or a liquid which has been heated by the ozone to form a vapor. 
     Within the treatment chamber, the gases or components may be delivered to the surface of the substrate or they may be delivered into the chamber at a location remote from the surface to be treated. The treatment chamber contains a substrate with matter on the surface, as well as a substrate holder. This holder may also include a chilling plate or a heating element. 
     The present invention is directed to both the process for generating ozone and for performing the surface treatment detailed above, and also the multi-chamber apparatus for carrying out this treatment. 
    
    
     BRIEF DESCRIPTION OF THE DRAWING 
     The invention is best understood from the following detailed description when read in connection with the accompanying drawing. It is emphasized that, according to common practice, the various features of the drawing are not the scale. On the contrary, the dimensions of the various features are arbitrarily expanded or reduced for clarity. Included in the drawing are the following figures: 
     FIG. 1 is a schematic side view of selected components of a light source and a light beam being focused. 
     FIG. 1A is a schematic side view of selected components of a light source and a light beam being focused, including a quartz window. 
     FIG. 2 is a schematic view of a two chamber embodiment of the invention for treating a substrate. 
     FIG. 3 is a schematic side view of selected components of a light source and a beam being focused, including optical control means. 
     FIG. 4 is a schematic view of an alternative embodiment of the two chamber apparatus with two optical sources. 
     FIG. 5 is a schematic view of an alternate embodiment of the two chamber apparatus used to treat substrates. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     The present invention provides both a method and an apparatus for treating the surface of a substrate. Substrates which may be treated by use of the present invention may include a semiconductor substrate, for example a silicon wafer, a photo mask, a flat panel display, a glass component, or any substrate with a surface requiring cleaning, planarizing, or oxidizing in a controlled fashion. 
     The surface treatment presented by the invention may include chemically oxidizing the surface and/or foreign matter contained on the surface by use of ozone; it may include oxidation of foreign matter contained on the surface coupled with cleaning the surface; it may include the oxidation of the surface followed by the planarization of that surface, and it may also include the oxidation the surface followed by both a cleaning and planarizing treatment. The cleaning process may include laser steam cleaning, liquid spray cleaning, or chemical bath cleaning, or any other suitable cleaning method. 
     The invention presents an apparatus for carrying out this treatment process. The apparatus includes at least two distinct chambers. The two chambers include an ozone generation chamber and a substrate surface treatment chamber. An additional treatment and/or generation chamber may be used, depending on the process requirements. In the generation chamber, ozone (O 3 ) is produced from an oxygen source using an optical energy source such as an ultraviolet (uv) light beam. Optical condensing means disposed along the optical path are used to focus the light beam to a focal point at (or near) which location ozone is generated from the oxygen contained in the generation chamber. The generation of ozone in this manner is a clean process, compared with the generation of ozone by use of high voltage across metallic electrodes. The generation of ozone by use of high voltage metallic electrodes often produces metal ion contaminants within the ozone generated. Such metal ion contamination is undesirable on a substrate, especially on a semiconductor substrate where metal ion contamination can cause device failure. 
     The apparatus for the present invention also provides a method for withdrawing the generated ozone in a first stream from the generation chamber and transporting it into the treatment chamber. The generated ozone may be mixed with another stream before or after it is delivered to the treatment chamber. In the treatment chamber, the substrate surface is processed first by being exposed to ozone, which can oxidize the substrate surface and foreign material contained on the surface. This ozone treatment may completely remove some foreign material, and, by oxidation, will render other foreign matter more easily removable in subsequent processing. 
     After the oxidation, or “pre-treatment,” is complete, the substrate surface is further treated. The subsequent treatment procedure may comprise both a physical component using the light source and a chemical component using a liquid and/or gas source which has been delivered to the treatment chamber and includes the generated ozone. In a preferred embodiment the optical source used to produce the ozone in the generation chamber is the same optical source which extends into the treatment chamber and is used as the laser or ultraviolet light component of the surface treatment. 
     The various embodiments of the present invention may be understood by reference to the following drawings. 
     FIG. 1 shows a beam  1  which provides optical energy. The optical source from which beam  1  emanates may be a laser or uv light source capable of producing ozone at a focal point along the optical path  9 . In a preferred embodiment an Excimer laser at 193 nm may be used as the optical source. As shown in FIG. 1, beam  1  is focused to a focal point  3  along the optical axis  8 . Ozone is generated at (and around) the focal point  3 . Various known optical condensing means may be used to focus the beam to a focal point  3 . 
     Examples of optical condensing means include a relay system, a Keplerian telescope, and a multi-facet homogenizer. A Keplerian telescope is depicted in FIG.  1 . Beam  1  from the laser/uv source is directed into a spherical or cylindrical lens  2  whereby a focal point  3  is generated at the focal length of the lens  2 . At and around the focal point  3 , ozone is generated and captured within an enclosure surrounding the optical system—the generation chamber. An aperture stop  4  may be used to constrain the optical light bundle directed to the optical element  5  which may also be a cylindrical or spherical lens. The second lens  5  allows for the beam to provide energy to the work surface  6  of the substrate  11 . In a preferred embodiment the ratio of the focal lengths of the first lens  2  and the second lens  5  is approximately 4:1 to develop a thin rectangular beam of light at the work surface  6  of approximately four inches by 0.125 inches. 
     Numerous optical configurations may be used to achieve the desired goal of both generating ozone and providing a light beam component at the work surface  6 . The embodiment depicted in FIG. 1 is just one example. In a preferred embodiment, the configuration of the optical systems may be chosen to achieve the most uniform beam and energy density at the work surface, while simultaneously producing a sufficient supply of ozone in the generation chamber. 
     FIG. 1A shows an alternative embodiment of the optical system depicted in FIG.  1 . FIG. 1A includes a quartz window  7  between the optical condensing means and the work surface  6 . The quartz window allows for transmission of the light energy beam. An anti-reflective coating common to the optics industry may be added to the quartz plate to minimize the attenuation during transmission of the beam. This configuration may be used in the embodiment wherein the same optical source is used to perform both the ozone generation in the generation chamber and the substrate surface treatment in the treatment chamber. If the quartz plate is not perpendicular to the incident light beam, an optical compensator, such as a slightly angled lens or another quartz plate, may be used to correct for any abberation of the transmission light beam. 
     FIG. 2 shows a side view of the present invention according to a preferred embodiment having two chambers. The treatment chamber  10  is the chamber in which the substrate is treated. The generation chamber  12  is the chamber where ozone is generated. 
     In the generation chamber  12 , a light source  14  produces a beam  44  which provides optical energy. The source  14  may be adjusted to produce light energy sources of various intensities and configurations. The optical source may be a laser or other uv source. As depicted in FIGS. 1 and 1A, optical condensing means are disposed along the optical path  9  to focus the beam  44  to focal point  16  at which ozone will be generated. In an alternative embodiment (not shown), the light source may be positioned outside of the generation chamber and a quartz window or other light permeable member may provide for transmission of the beam into the generation chamber. 
     The ozone generated at the focal point  16  within the generation chamber  12  is produced from an atmosphere including oxygen. The atmosphere may be ambient air, or it may include an oxygen containing gas stream  18  delivered to the chamber from a gas source  17  which includes oxygen. The oxygen source stream  18  may include oxygen with a number of other carrier or diluent gases such as nitrogen or a noble gas. The ozone produced in the generation chamber is withdrawn from the generation chamber in a first stream  20  exiting the generation chamber. The means for withdrawing the generated ozone out of the generation chamber may include gas tubing or conduit  24 . 
     The ozone generation process may be regulated by regulating means. Generation chamber atmospheric measuring device  56  senses the atmospheric conditions within the chamber. These conditions include the concentration of ozone and oxygen within the generation chamber  12 . Measuring device  56  provides this information to atmospheric control means  58  which controls the gas flow  18  into generation chamber  12  by controlling valve  59  which regulates the amount of gas transported into the generation chamber, depending on processing needs. 
     First stream  20  which contains the generated ozone may also include other diluent or carrier gases from the generation chamber such as N 2  or a noble gas depending on processing conditions and the oxygen source, or may be purely ozone. The first stream  20  may be delivered to the process chamber  10  in various manners, with or without prior mixing with another gas or vapor or liquid. In one embodiment, with valves  32  and  30  closed, the first stream containing ozone  20 , is delivered to the treatment chamber  10  through tube or conduit  26  and opened valve  31 , whereby the stream is introduced into the chamber at a point not proximate to the substrate surface to be treated. In an alternative embodiment, valves  31  and  32  are closed while valve  30  is open so that first stream  20  is delivered to treatment chamber  10  at a point proximate to the substrate surface. In another alternative embodiment valve  31  may be closed and valves  30  and  32  may be opened. In this embodiment, the first stream  20  may be mixed with a second stream  34  at the junction  29  of gas tubing members  24  and  46 . The second stream  34  may be a liquid, a gas, or it may be a liquid which is vaporized by the use of heating coils  36  to produce a vapor at the point  29  where the two streams mix. 
     The second gas source  33  of the second stream  34  may include other inert or reactive constituents. These constituents may include noble gasses, N 2 , water, HCl, HF, NH 3 , helium, IPA, or DI water. The particular constituent or constituents selected depends on the processing needs and other parameters. In the preferred embodiment, the ozone-containing stream  20  is mixed with deionized water vapor provided by the heating of second stream  34 . The two streams combine at junction  29  to form a gaseous mixture  54  which is transported via tubing member  28  to the substrate surface. The point of delivery  39  may be configured so that it is proximate to the substrate surface being treated, as depicted in FIG.  2 . In the preferred embodiment, the mixture  54  of DI water vapor and the ozone-containing stream are delivered proximately to the substrate surface. In an alternate embodiment the point of delivery  39  may be chosen so that it is not proximate to the surface being treated. 
     In another embodiment the mixing between stream  20  and second stream  34  may take place after both have been introduced into the treatment chamber  10 . With valve  30  closed and valves  32  and  31  open, the first stream  20  enters the treatment chamber  10  through tube  26  at point of delivery  37 . The second stream  34  is delivered into the chamber through tube  28  at point of delivery  39 . The point of delivery  39  may again be chosen to be near the substrate surface being treated or may be remote from the surface. In this embodiment, the mixing of the two streams takes place within the treatment chamber  10 . 
     Substrate holder  38  holds the substrate  48  within the treatment chamber  10 . The substrate holder  38  may include a chilling element or a heating element depending on the processing treatment so desired. If a chiller is used, a condensate  41  may form on the surface of the substrate from the vapors delivered from tube member  28  to the surface through port  47  which may be a diffuser, nozzle or other orifice at the point of delivery  39 . In the preferred embodiment, the mixture of DI water vapor and ozone forms a condensate  41  at the surface. The substrate holder  38  may also include movement means for moving the substrate holder during processing (surface treatment) in a known manner. 
     The substrate surface  40  may contain foreign, contaminating material. In the semiconductor processing industry, the surface of a substrate to be treated may be a silicon wafer with an integrated circuit being fabricated onto it. 
     Within the semiconductor industry, organic contaminating matter is commonly found on the surface of the substrate, especially due to residual photoresist which may be hardened due to aggressive processing conditions. This is particularly true when the photoresist residual on the substrate surface has been hardened by an ion implantation or plasma etching process. While organic contaminants are common, other contaminants may be present such as metals, silicon, oxides, and minerals. 
     Each type of contaminant may require different treatment conditions for most efficient removal. The ozone containing stream  20  or mixture  54  first treats the surface  40  of the substrate  48  by oxidizing matter on the substrate surface  40 . The “pre-treatment,” or oxidation, of foreign matter on the surface makes some matter easier to be subsequently removed. Such is the case for organic contaminants, such as residual photoresist. Alternatively, this oxidation of foreign matter may completely remove the material from the surface  40 . 
     With the foreign matter contained on the substrate now oxidized (the “pre-treatment” complete), the subsequent treatment processing may now take place. The subsequent processing may include the cleaning and/or planarizing of the surface  40 . Cleaning may include laser steam cleaning, cleaning by use of liquid spray, or cleaning within a chemical bath. Each type of cleaning requires different conditions for efficient treatment. Cleaning is accomplished using both chemical cleaning processes and physical processes. Light energy can be used to physically decompose foreign matter such as organics. The light energy source  44  used at the substrate surface  40  in the treatment chamber  10  may be the same light beam  44  as used in the generation chamber  12  to generate ozone. 
     In a preferred embodiment, a solid light permeable member  52  (e.g., a quartz plate) disposed between the two chambers, allows for transmission of a laser beam  44  between chambers. In an alternative embodiment, an optical compensator may replace the quartz plate to correct for any abberations induced and to allow transmission, while retaining ozone generation. In a preferred method for treating the substrate, the substrate holder  48  is moved relative to the laser by use of movement means in a known way, so that the laser sweeps across the substrate surface for steam cleaning. In another preferred method for cleaning, the light source (feature  14  of FIG. 2) may include means such as a rotating mirror or a galvanometer, for moving the beam  44  with respect to a stationary substrate. 
     Processing conditions may be chosen to maximize cleaning efficiency for the particular substrate and foreign material being removed. In an alternate embodiment, the processing conditions may be chosen so that the transported ozone, which may be in combination with other carrier or diluent inert gases, reacts more aggressively with the surface to planarize the substrate surface being treated. In yet another embodiment, all three processes may take place: oxidation followed by the cleaning and/or planarizing treatment of the surface. 
     Conditions within the treatment chamber  10  may be monitored and controlled to produce the desired surface treatment. A measuring device  42  may be used to measure a plurality of treatment chamber conditions, including the vapor concentration. The measuring device  42  provides information to control means  50  which may control the flow of first stream  20  and the flow of the second stream  34  by means of regulating and modulating means which control gas delivery into the treatment chamber. Ozone gas stream regulating and modulating means  22  regulates and modulates the flow of stream  20 ; second stream regulating and modulating means  23  regulates and modulates the flow of second stream  34 , and both modulating means are responsive to control means  50 . By monitoring and regulating the gas delivery to the treatment chamber, the gas mixture concentration requirements may be maintained, and the process conditions at the site on the surface being treated may be controlled to produce the desired treatment. 
     FIG. 3 shows the optical control means which controls light energy in the treatment process as well as the focal point produced by the optical condensing means used in the generation process. Optical control means  77  is responsive to inputs from both the measuring device  42  (as also depicted in FIG. 2) and generation chamber atmospheric measuring device  56  (also as depicted in FIG.  2 ). Regulating means  79 ,  81 , and  83  are responsive to the optical control means  77 . Based on the process conditions, and the conditions for the desired treatment processes, the optical control means  77  may be used to control the optics to maximize ozone generation at the focal point  3 , or, alternatively, the energy distribution and beam density achieved in the treatment chamber at surface  6 . The optical control means  77  may be responsive to real time changes within the treatment chamber and within the generation chamber so that regulating means  79 ,  81 , and  83  may regulate the optical source so that the process of ozone generation and the process of surface treatment may be alternately maximized during the simultaneous production of ozone and treatment of a substrate surface. 
     In addition to the optical control means described in conjunction with FIG. 3, the settings within the light source (feature  14  of FIG. 2) may also be varied to produce the light beam characteristics to achieve the desired ozone production or surface treatment needs. Such settings, or set of parameters, of a light source, and the manipulation of such settings to achieve the desired light beam characteristics, are well-known in the art. 
     FIG. 4 shows an alternative embodiment of the two chamber apparatus containing a treatment chamber  10  and a generation chamber  12 . In this alternate embodiment two distinct optical energy sources are produced by two light sources  60  and  62 . Within the generation chamber  12 , light source  60  provides a beam  64  which by way of optical condensing means is focused to focal point  68  where the ozone is generated. This source  60  may provide a laser or other uv light source capable of producing ozone. A second light source  62  positioned within the treatment chamber  10  provides a separate beam  66  as an optical energy source which is used in surface treatment. The beam  66  typically used for surface treatment will be a laser. In an alternative embodiment (not pictured) either optical source  60  or  62  may be situated outside of the generation chamber and the treatment chamber. 
     The substrate  48  may be introduced into the treatment chamber by a substrate loading means (also not depicted). The substrate loading means may provide for automated loading, and may further comprise substrate unloading means. Thus, the introduction of the substrate to the treatment chamber may be done manually, automatically, or continuously. The substrate loading means may further include movement means  70 , which provide for motion of the substrate relative to the optical energy source, during the treatment process. This will allow for the optical beam to sweep across the substrate surface during processing. 
     FIG. 5 shows an alternative embodiment of the two chamber apparatus including a generation chamber  12  and a treatment chamber  10 . In the embodiment depicted in FIG. 5, the first stream containing ozone  20  is delivered into the process chamber by means of gas tubing or conduit  72 . The second stream  34  is delivered into the treatment chamber by use of gas tubing or conduit  74 . In this alternative embodiment gas tubings  72  and  74  are distinct and are not connected. In this embodiment no mixing may occur prior to the introduction of the two streams to the treatment chamber where the streams are intermixed. 
     The previous embodiments were shown to illustrate some of the various embodiments of the present invention and are not intended to limit the scope nor the spirit of the present invention. The method of ozone generation at the focal point of the optical energy source may be carried out in a number of manners. The oxygen source from which the ozone is produced may be delivered to the generation chamber in a number of manners with a number of additional components or it may comprise ambient air. The means for withdrawing and delivering the generated ozone from the generation chamber to the treatment chamber may take many forms. A second stream may be added to the ozone containing stream, or it may not be utilized. The mixing location and method may be varied. The treatment carried out within the treatment chamber may include oxidation, cleaning, planarization, or any combination of the three. The invention may include one light source for carrying out both processes, or it may include more than one. 
     Although illustrated and described herein with reference to certain specific examples, the present invention is nevertheless not intended to be limited to the detail shown. Rather, various modifications may be made to the details within the scope and range of equivalence of the claims and without departing from the spirit of the invention. Such modifications include, for example, various embodiments of the apparatus configuration, the treatment process, the gas or liquid transporting means, the mixing points, the applications for different substrates, the means for regulating and controlling the conditions in the generation chamber, the conditions in the treatment chamber, and the optical energy source used. The scope of the present invention is expressed by the appended claims.

Technology Category: 7