Abstract:
An article having a protective coating for use in semiconductor applications and methods for making the same are provided. In certain embodiments, a method of coating an aluminum surface of an article utilized in a semiconductor processing chamber is provided. The method comprises providing a processing chamber; placing the article into the processing chamber; flowing a first gas comprising a carbon source into the processing chamber; flowing a second gas comprising a nitrogen source into the processing chamber; forming a plasma in the chamber; and depositing a coating material on the aluminum surface. In certain embodiments, the coating material comprises an amorphous carbon nitrogen containing layer. In certain embodiments, the article comprises a showerhead configured to deliver a gas to the processing chamber.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
       [0001]    This application if a continuation of U.S. patent application Ser. No. 12/255,638 filed Oct. 21, 2008, and published Feb. 19, 2009, as United States Patent Publication 2009/0044753, which is a divisional application of U.S. patent application Ser. No. 11/689,278, filed Feb. 28, 2007, and patented Apr. 7, 2009, as U.S. Pat. No. 7,514,125, which claims benefit of U.S. provisional patent application Ser. No. 60/805,706 (APPM/011269L), filed Jun. 23, 2006, all of which are incorporated herein by reference. 
     
    
     BACKGROUND 
       [0002]    1. Field 
         [0003]    Embodiments of the invention as recited by the claims generally relate to an article having a protective coating for use in a semiconductor processing chamber and a method of making the same. 
         [0004]    2. Description of the Related Art 
         [0005]    Integrated circuits have evolved into complex devices that can include millions of transistors, capacitors and resistors on a single chip. The evolution of chip designs continually requires faster circuitry and greater circuit density that demand increasingly precise fabrication techniques and processes. One fabrication process frequently used is plasma enhanced chemical vapor deposition (PECVD). 
         [0006]    PECVD is generally employed to deposit a thin film on a substrate or a semiconductor wafer. PECVD is generally accomplished by introducing a precursor gas or gases into a vacuum chamber. The precursor gas is typically directed through a showerhead typically fabricated from aluminum situated near the top of the chamber. Plasma is formed in the vacuum chamber. The precursor gas reacts with the plasma to deposit a thin layer of material on the surface of the substrate that is positioned on a substrate support. Purge gas is routed through holes in the support to the edge of the substrate to prevent deposition at the substrate&#39;s edge that may cause the substrate to adhere to the support. Deposition by-products produced during the reaction are pumped from the chamber through an exhaust system. 
         [0007]    One material frequently formed on substrates using a PECVD process is amorphous carbon. Amorphous carbon is used as a hard mask material in semiconductor application because of its chemical inertness, optical transparency, and good mechanical properties. Precursor gases that may be used to form amorphous carbon generally include a hydrocarbon, such as propylene and hydrogen. 
         [0008]    The etch selectivity of amorphous carbon films has been correlated to film density. Ion bombardment densification of amorphous carbon films is one method of increasing the etch selectivity of an amorphous carbon film, however, ion-bombardment induced film densification invariably leads to a proportional increase in the compressive film stress, both on the showerhead of the PECVD chamber and the substrate. Highly compressive carbon residues on the showerhead poorly adhere to the showerhead surfaces, producing flakes and particles during prolonged durations of deposition. The stray carbon residue builds on the showerhead and may become a source of contamination in the chamber. Eventually, the stray carbon residue may clog the holes in the showerhead that facilitate passage of the precursor gas therethrough thus necessitating removal and cleaning of the showerhead or possibly replacement. 
         [0009]    Therefore, there is a need for an apparatus or method that reduces formation of loose carbon deposits on aluminum surfaces in semiconductor processing chambers. 
       SUMMARY 
       [0010]    Embodiments of the present invention as recited by the claims generally provide an apparatus and method that reduces formation of loose carbon deposits on aluminum surfaces and reduces in-film particle formation in semiconductor processing chambers. 
         [0011]    An article having a protective coating for use in semiconductor applications and methods for making the same are provided. In certain embodiments, a method of coating an aluminum surface of an article utilized in a semiconductor processing chamber is provided. The method comprises providing a processing chamber, placing the article into the processing chamber, flowing a first gas comprising a carbon source into the processing chamber, flowing a second gas comprising a nitrogen source into the processing chamber, and depositing a coating material on the aluminum surface. In certain embodiments, the coating material comprises a nitrogen containing amorphous carbon layer. In certain embodiments, the coated article is a showerhead configured to deliver a gas to the processing chamber. 
         [0012]    In certain embodiments, a method of reducing contaminants in a layer deposited in a semiconductor processing chamber containing an aluminum surface is provided. The method comprises providing a semiconductor processing chamber, placing a substrate into the processing chamber, flowing a first gas comprising a carbon source into the processing chamber, flowing a second gas comprising a hydrogen source into the processing chamber, forming a plasma from an inert gas in the chamber, and depositing a layer on the substrate. 
         [0013]    In certain embodiments, an article for use in a semiconductor processing chamber is provided. The article comprises a showerhead, a support pedestal, or a vacuum chamber body having an aluminum surface and a coating material comprising a nitrogen containing amorphous carbon material applied on the aluminum surface in a plasma enhanced chemical vapor deposition process. 
         [0014]    In certain embodiments a showerhead having an aluminum surface coated with a nitrogen containing amorphous carbon material is provided. The nitrogen containing amorphous carbon material is applied to the showerhead by a method comprising flowing a first gas comprising a carbon source into the processing chamber, flowing a second gas comprising a nitrogen source into the processing chamber, forming a plasma in the chamber, and depositing the nitrogen containing amorphous carbon material on the aluminum surface. 
         [0015]    In certain embodiments, a showerhead configured to deliver gas to a semiconductor processing chamber is provided. The showerhead comprises an upper surface, a lower surface comprising aluminum, wherein the lower surface has a surface roughness of between about 30 nm and about 50 nm, and a plurality of openings formed between the upper surface and the lower surface. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0016]    A more particular description of the invention, briefly summarized above, may be had by reference to certain embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only certain embodiments and are therefore not to be considered limiting of its scope. 
           [0017]      FIG. 1  is a sectional view of a PECVD chamber assembly; 
           [0018]      FIG. 2  is a sectional view of a showerhead used in the PECVD chamber assembly of  FIG. 1 ; 
           [0019]      FIG. 3  depicts an exemplary flow diagram of a method of coating an aluminum surface of an article; 
           [0020]      FIG. 4  is a graph demonstrating the effect of an exemplary coating material on in-film particle performance of 10 kÅ thick Low k amorphous carbon layer; 
           [0021]      FIG. 5A  is a sectional view of a showerhead before the showerhead is treated to increase surface roughness; 
           [0022]      FIG. 5B  is a sectional view of a showerhead with a roughened surface; 
           [0023]      FIG. 5C  is a sectional view of a showerhead with carbon residue attached to the roughened surface; 
           [0024]      FIG. 6  illustrates a graph demonstrating the effect of faceplate roughness on the in-film particle performance of 10 kÅ thick Low k amorphous carbon layer; and 
           [0025]      FIG. 7  illustrates a graph demonstrating the effect of H 2  dilution on the in-film particle performance of 10 kÅ thick Low k amorphous carbon layer. 
       
    
    
       [0026]    To facilitate understanding, identical reference numerals have been used, wherever possible, to designate identical elements that are common to the figures. It is contemplated that elements and/or process steps of one or more embodiments may be beneficially incorporated in one or more other embodiments without additional recitation. 
       DETAILED DESCRIPTION 
       [0027]    In certain embodiments, a processing system having coated aluminum surfaces that are advantageous for the deposition of amorphous carbon and other films is disclosed. 
         [0028]      FIG. 1  is a sectional view of an exemplary PECVD chamber assembly  100 . The PECVD chamber may be any plasma enhanced CVD chamber or system including systems such as the CENTURA ULTIMA HDP-CVD™ system, PRODUCER APF PECVD™ system, PRODUCER BLACK DIAMOND™ system, PRODUCER BLOK PECVD™ system, PRODUCER DARC PECVD™ system, PRODUCER HARP™ system, PRODUCER PECVD™ system, PRODUCER STRESS NITRIDE PECVD™ system, and PRODUCER TEOS FSG PECVD™ system, available from Applied Materials, Inc. of Santa Clara, Calif. An exemplary PRODUCER® system is further described in commonly assigned U.S. Pat. No. 5,855,681, issued Jan. 5, 1999, which is herein incorporated by reference. 
         [0029]    Plasma enhanced chemical vapor deposition (PECVD) techniques generally promote excitation and/or disassociation of the reactant gases by the application of an electric field to a reaction zone near the substrate surface, creating a plasma of reactive species immediately above the substrate surface. The reactivity of the species in the plasma reduces the energy required for a chemical reaction to take place, in effect lowering the required temperature for such PECVD processes. 
         [0030]      FIG. 1  is a sectional view of a PECVD chamber assembly  100 . The chamber assembly  100  has a sidewall  105 , a ceiling  106 , and a base  107  which enclose a processing region  121 . A substrate pedestal  115 , which supports a substrate  120 , mounts to the base  107  of the chamber assembly  100 . A backside gas supply (not shown) furnishes a gas, such as helium, to a gap between the backside of the substrate  120  and the substrate pedestal  115  to improve thermal conduction between the substrate pedestal  115  and the substrate  120 . In certain embodiments, the substrate pedestal  115  is heated and/or cooled by use of embedded heat transfer fluid lines (not shown), or an embedded thermoelectric device (not shown), to improve the plasma process results on the substrate  120  surface. A vacuum pump  135  controls the pressure within the process chamber assembly  100 , typically holding the pressure below 0.5 milliTorr (mT). A gas distribution showerhead  110  can consist of a gas distribution plenum  140  connected to a gas supply  125  and can communicate with the process region over the substrate  120  through plural gas nozzle openings  142 . The showerhead  110 , made from a conductive material (e.g., anodized aluminum, etc.), acts as a plasma controlling device by use of a first impedance match element  175 A and a first RF power source  180 A. A bias RF generator  162  can apply RF bias power to the substrate pedestal  115  and substrate  120  through an impedance match element  164 . A controller  170  is adapted to control the impedance match elements (i.e.,  175 A and  164 ), the RF power sources (i.e.,  180 A and  162 ) and certain other aspects of the plasma process. In certain embodiments dynamic impedance matching is provided to the substrate pedestal  115  and the showerhead  110  by frequency tuning and/or by forward power serving. 
         [0031]    In operation, the substrate  120  can be secured to the substrate pedestal  115  by providing a vacuum therebetween. The temperature of the substrate is elevated to a pre-determined process temperature by regulating thermal transfer to the substrate pedestal  115  by, for example, a heating element (not shown). During the deposition process, the substrate is heated to a steady temperature typically between about 200° C. and 700° C. 
         [0032]    Gaseous components, which in certain embodiments may include propylene and hydrogen, can be supplied to the process chamber assembly  100  via the gas nozzle openings  142  in showerhead  110 . A plasma is formed in the process chamber assembly  100  by applying RF power to a gas source such as argon or nitrogen. The gaseous mixture reacts to form a layer of amorphous carbon, for example Advanced Patterning Film or “APF” available from Applied Materials, Inc. of Santa Clara, Calif., on the surface of the substrate  120 . 
         [0033]      FIG. 2  is a sectional view of an exemplary showerhead  110 . As shown in  FIG. 2 , the showerhead can comprise an upper surface  215  and a lower surface  205 . A plurality of gas nozzle openings  142  can be formed between the lower surface  205  and the upper surface  215 . In certain embodiments, the coating material  210  is disposed on the lower surface  205  of the showerhead  110 . The coating material  210  can be applied before final assembly of the process chamber assembly  100 . The coating material  210  can also be applied to other parts of the showerhead  110  such as the face plate and the gas distribution plate. However, in certain embodiments, the coating material  210  can be applied to the showerhead  110  after final assembly of the process chamber assembly  100 . Optionally, the coating material  210  can be applied to other aluminum surfaces within the process chamber assembly  100 , for example, the chamber  100  itself and the support pedestal  115 . In certain embodiments, it may be necessary to periodically reapply the coating material  210  to the showerhead  110  or other aluminum surface. In certain embodiments, aluminum surface is cleaned prior to reapplication of the coating material  210 . 
         [0034]    In certain embodiments, the coating material  210  comprises a layer of nitrogen containing amorphous carbon or other material that inhibits flaking of carbon residue from the showerhead  110 . The thickness of the coating material  210  is sufficient to provide a “sticky” seasoned layer and is typically between about 500 Å and about 3000 Å, such as between about 1000 Å and about 2000 Å, for example about 1500 Å. The coating material  210  functions as an adhesion promoting layer between the bare lower surface  205  of the showerhead  110  and the carbon residues deposited on the showerhead  110  during the amorphous carbon deposition. Thus the coating material  210  adheres to aluminum surfaces as well as amorphous carbon surfaces. Since nitrogen can bond with carbon as well as aluminum surfaces, it can create a “sticky” seasoned layer. In certain embodiments, the seasoned layer can be predominantly carbon which can allow forthcoming amorphous carbon residues to adhere to the showerhead and thereby can inhibit flaking or fall-on particles. 
         [0035]      FIG. 3  depicts a flow diagram  300  of certain embodiments of a method of coating an aluminum surface of an article. For example, in step  310 , a processing chamber is provided. In step  320 , the article is placed into the processing chamber. In step  330 , a first gas comprising a carbon source is flowed into the processing chamber. In step  340 , a second gas comprising a nitrogen source is flowed into the processing chamber. In step  350 , a plasma is formed in the chamber. In step  360 , a coating material is deposited on the aluminum surface. 
         [0036]    Typical carbon sources include hydrocarbon compounds with the general formula C x H y  where x has a range of between 2 and 10 and y has a range of between 2 and 22. For example, propylene (C 3 H 6 ), propyne (C 3 H 4 ), propane (C 3 H 8 ), butane (C 4 H 10 ), butylene (C 4 H 8 ), butadiene (C 4 H 6 ), acetelyne (C 2 H 2 ), pentane, pentene, pentadiene, cyclopentane, cyclopentadiene, benzene, toluene, alpha terpinene, phenol, cymene, norbornadiene, as well as combinations thereof, may be used as the hydrocarbon compound. Liquid precursors may be used to deposit amorphous carbon films. The use of liquid precursors in the deposition of amorphous carbon films is further discussed in United States Patent Application Publication No. 2005/0287771, published Dec. 29, 2005, entitled LIQUID PRECURSORS FOR THE CVD DEPOSITION OF AMORPHOUS CARBON FILMS, which is herein incorporated by reference to the extent it does not conflict with the current specification. These liquid precursors include, but are not limited to, toluene, alpha terpinene (A-TRP), and norbornadiene (BCHD). 
         [0037]    Similarly, a variety of gases such as hydrogen (H 2 ), nitrogen (N 2 ), ammonia (NH 3 ), or combinations thereof, among others, can be added to the gas mixture, if desired. Argon (Ar), helium (He), and nitrogen (N 2 ) can be used to control the density and deposition rate of the amorphous carbon layer. 
         [0038]    The carbon source compound may be introduced into the chamber at a flow rate of between about 200 sccm and about 2000 sccm, such as between about 1,500 sccm and about 2,000 sccm, for example, 700 sccm. The nitrogen source may be introduced into the chamber at a flow rate of between about 100 sccm and about 15,000 sccm, such as between about 5,000 sccm and about 10,000 sccm, for example, 8,000 sccm. Optionally, a carrier gas can be introduced into the chamber at a flow rate of between about 0 sccm and about 20,000 sccm. The carrier gas may be nitrogen gas or an inert gas. In certain embodiments, the flow rates are chosen such that the coating material is predominately carbon. For example, the carbon source compound may be introduced into the chamber at a first flow rate, and the nitrogen source compound may be introduced into the chamber at a second flow rate such that the ratio of the second flow rate to the first flow rate is between about 50:1 and about 1:1, such as between about 10:1 and about 1:1, for example, about 7:1. In certain embodiments, the carbon source compound is propylene and the nitrogen source is nitrogen. 
         [0039]    In certain embodiments, during deposition of the nitrogen containing amorphous carbon layer, the substrate can be typically maintained at a temperature between about 200° C. and about 700° C., preferably between about 250° C. and about 350° C., such as about 300° C. In certain embodiments, a RF power level of between about 20 W and about 1,600 W, for example, about 1,000 W, for a 300 mm substrate is typically used in the chamber. The RF power can be provided at a frequency between about 0.01 MHz and 300 MHz, for example, 13.56 MHz. In certain embodiments, the RF power can be provided to a gas distribution assembly or “showerhead” electrode in the chamber. In certain embodiments, the RE power may be applied to a substrate support in the chamber. In certain embodiments, the RF power may be provided at a mixed frequency, such as at a high frequency of about 13.56 MHz and a low frequency of about 350 kHz. The RF power may be cycled or pulsed and continuous or discontinuous. 
         [0040]    In certain embodiments, the spacing between the showerhead and support pedestal during the deposition of the nitrogen containing amorphous carbon layer may be between about 280 mils and about 1,500 mils, for example, 400 mils, and the pressure in the chamber may be between about 1 Torr and about 10 Torr, for example, 7 Torr. 
         [0041]      FIG. 4  is a graph demonstrating the effect of certain embodiments of the coating material on in-film particle performance of 10 kÅ thick Low k amorphous carbon.  FIG. 4  shows the effect of a nitrogen amorphous carbon layer of approximately 1,500 Å thick deposited on the showerhead prior to the bulk Low k amorphous carbon deposition. The exemplary coating material was deposited using the following conditions: a substrate temperature of 300° C., a chamber pressure of 7 Torr, a spacing of 400 mils, a nitrogen flow rate of 8,000 sccm, a propylene flow rate of 700 sccm, a RF power level of 1,000 W, a deposition rate of 2,100 Å/min. These conditions produced a nitrogen containing amorphous carbon layer with a refractive index of 1.69, a light absorption coefficient of 0.02, and a stress of −80 MPa. 
         [0042]    Still referring to  FIG. 4 , the exemplary Low k amorphous carbon layer was deposited on wafer  1  without the benefit of the nitrogen containing amorphous carbon layer. The exemplary Low k amorphous layer was deposited on wafers  2 - 4  with the benefit of the nitrogen containing amorphous carbon layer. The results show a significant reduction in in-film adders or contaminants, represented by A 1  and A 2 , for the exemplary Low k amorphous carbon layers deposited on wafers  2 - 4 . 
         [0043]    In certain embodiments a method for improving the adhesion strength of the lower surface  205  of the showerhead  110  is provided.  FIG. 5A  is a sectional view of the showerhead  110  before the showerhead  110  is treated to increase surface roughness. The showerhead  110  can comprise an upper surface  215  and a lower surface  205 . A plurality of gas nozzle openings  142  can be formed between the lower surface  205  and the upper surface  215 . In certain embodiments, this method increases the surface roughness of the lower surface  205  of the showerhead  110 . In certain embodiments, this method may also be used to increase the surface roughness of other parts of the chamber  100 . For example, in certain embodiments this method increases the root mean square (“RMS”) roughness of the lower surface  205  of the showerhead  110  from about 20 nm to between about 30 nm and about 50 nm, for example, about 40 nm.  FIG. 5B  is a sectional view of the showerhead  110  with a roughened surface  502 . Roughening of the lower surface  205  to produce roughened surface  502  may be performed by a variety of methods known to those of skill in the art. For example, two such methods of roughening can be achieved by physically bombarding the showerhead with small metallic balls, also known as a “bead blasting process,” and/or application of various chemical treatments known in the art. 
         [0044]      FIG. 5C  is a sectional view of a showerhead with carbon residue  504  securely attached to the roughened surface  502 . In certain embodiments, the “bead blasting process” can provide a textured and roughened surface  502  that enhances the adherence of carbon residue  504  to the roughened surface  502  of the showerhead  110 . In bead blasting, beads are propelled toward the surface by air at a pressure that is suitably high to roughen the surface. The beads may comprise a material having a hardness higher than that of the underlying structure to allow the beads to erode and roughen the lower surface  205  of the showerhead  110  to form a roughened surface  502 . Suitable bead materials include for example, aluminum oxide, glass, silica, or hard plastic. In certain embodiments, the beads comprise a grit of aluminum oxide having a mesh size selected to suitably grit blast the surface, such as for example, a grit of alumina particles having a mesh size of about 200. The bead blasting may take place in, for example, a bead blaster, comprising an enclosed housing. 
         [0045]    In certain embodiments,  FIG. 6  illustrates a graph demonstrating the effect of faceplate roughness on the in-film particle performance of 10 kÅ thick Low k amorphous carbon layer. For example,  FIG. 6  compares the In-Film adders for a 10 kÅ thick Low k amorphous carbon layer deposited in a chamber containing an exemplary bead-blasted faceplate versus a standard faceplate. In certain embodiments, the exemplary bead-blasted faceplate can have a roughness of 40 nm where the standard faceplate has a roughness of 10 nm. For example the results show a significant reduction of in-film adders/contaminants for 10 kÅ thick Low k amorphous carbon deposited in a chamber containing an exemplary bead-blasted faceplate with a roughness of 40 nm versus a chamber containing a standard faceplate with a roughness of 10 nm. These results demonstrate that an increase in the surface roughness of the showerhead increases the adhesion strength between the showerhead and carbon residues thus reducing the presence of in-film adders in the deposited Low k amorphous carbon layer. 
         [0046]    In certain embodiments, a method of reducing the presence of in-film adders is provided. The method comprises the addition of H 2  as a dilution gas during the bulk deposition process. In certain embodiments, this method may be used with deposition processes described in United States Patent Application Publication No. 2005/0287771, published Dec. 29, 2005, entitled LIQUID PRECURSORS FOR THE CVD DEPOSITION OF AMORPHOUS CARBON FILMS and U.S. patent application Ser. No. 11/427,324, filed Jun. 28, 2006, entitled METHOD FOR DEPOSITING AN AMORPHOUS CARBON FILM WITH IMPROVED DENSITY AND STEP COVERAGE which are herein incorporated by reference to the extent they do not conflict with the current specification. In certain embodiments, the addition of H 2  has been shown to significantly reduce the in-film particles. It is believed that several mechanisms play a role in this phenomenon. For example, hydrogen species can passivate the gas phase CH x  species, thereby limiting the growth of these radicals into potential particle nuclei. Additionally, for example, the addition of H 2  may lead to a widening of the plasma sheath at the electrode surfaces, thus leading to a reduction in the momentum of the ions bombarding the electrodes. 
         [0047]    In certain embodiments,  FIG. 7  illustrates a graph demonstrating the effect of H 2  dilution on the in-film particle performance of an exemplary 10 kÅ thick Low k amorphous carbon layer. Deposition for the first sample, represented by “A,” was performed with an exemplary argon flow rate of 8,000 sccm and an exemplary helium flow rate of 400 sccm. Deposition for the second sample, represented by “B,” was performed with an exemplary argon flow rate of 7,000 sccm and an exemplary hydrogen flow rate of 1,000 sccm. Deposition for the third sample, represented by “C,” was performed with an exemplary argon flow rate of 5,000 sccm and an exemplary hydrogen flow rate of 2,000 sccm. Deposition for the fourth sample, represented by “D,” was performed with an exemplary argon flow rate of 5000 sccm and an exemplary hydrogen flow rate of 3,000 sccm. The results show that an increase in the addition of H 2  as a dilution gas can yield a decrease in in-film adders. 
         [0048]    While the foregoing is directed to certain embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.