Abstract: A near substrate reactant homogenization apparatus reduces the excess reactive species in a region at or near the edge of a substrate surface to provide a uniform reactant concentration over the substrate, thereby improving etch rate uniformity over the substrate. The near substrate reactant homogenization apparatus has a substantially planar surface that is parallel to said substrate surface and that extends beyond the substrate edge, at or below the substrate surface. In a first preferred embodiment of the invention, the temperature of the gas absorber area is changed to promote recombination or condensation of excess reactive species at the substrate edge, where the excess species are removed. In another, equally preferred embodiment of the invention, the gas absorber area is formed of a porous material having a large surface area. Excess reactive species enter the porous structure and are subsequently recombined.

Abstract: An apparatus (20) for uniformly processing substrates (25) having a surface with a center (80) and a peripheral edge (85). The apparatus (20) comprises (i) a process chamber (30) having a gas distributor (55) for distributing process gas in the process chamber (30); (ii) a support (75) for supporting a substrate (25) in the process chamber (30); (iii) a plasma generator for forming a plasma from the process gas in the process chamber (30); and (iv) a focus ring (90) in the process chamber (30). The focus ring (90) comprises (a) a wall (95) surrounding the substrate (25) to substantially contain the plasma on the substrate surface, and (b) a channel (100) in the wall (95). The channel (100) has an inlet (105) adjacent to, and extending substantially continuously around the peripheral edge (85) of the substrate surface.

Abstract: A process for etching single crystal silicon, polysilicon, silicide and polycide using iodinate or brominate gas chemistry, is disclosed. The iodinate/brominate gas chemistry etches narrow deep trenches with very high aspect ratios and good profile control and without black silicon formation or other undesirable phenomena.

Abstract: A sealing structure 20 for forming a seal around a chuck 30 used to hold a substrate 45 having a peripheral edge 50. An actuated, position-adjustable, sealing diaphragm 165 is disposed along the peripheral edge of the substrate. The diaphragm has a conformal sealing surface 170 capable of forming a seal when pressed against the peripheral edge of the substrate 45. A diaphragm actuator 175 actuates the sealing diaphragm from (i) a first non-sealing position 180 in which the conformal sealing surface of the diaphragm is spaced apart from the substrate held on the chuck to form a gap 190 therebetween, to (ii) a second sealing position 185 in which the conformal sealing surface of the diaphragm presses against, and forms a seal with, the peripheral edge of the substrate.

Abstract: A method for etching a tungsten containing layer 25 on a substrate 10 substantially anisotropically, with good etching selectivity, and without forming excessive passivating deposits on the etched features. In the method, the substrate 10 is placed in a plasma zone 55, and process gas comprising SF.sub.6, CHF.sub.3, and N.sub.2, is introduced into the plasma zone. A plasma is formed from the process gas to anisotropically etch the tungsten containing layer 22. Preferably, the plasma is formed using combined inductive and capacitive plasma operated at a predefined inductive:capacitive power ratio.

Abstract: During the etching of a silicon-containing material using a halogen-containing etch gas, a silicon-hydride gas is added to the etch gas to provide increased sidewall protection during the etch. Suitably up to about 50 percent by volume of a silicon-containing gas such as silane is added to improve anisotropy of the etch and to prevent notching at the silicon-substrate interface.

Abstract: An etchant composition of nitrogen trifluoride and chlorine, preferably also including a passivation material such as hydrogen bromide, etches tungsten silicide-polysilicon gate layers with high selectivity to a thin underlying silicon oxide gate oxide layer to form straight wall, perpendicular profiles with low microloading and excellent profile control.

Abstract: An electrostatic chuck (20) for holding a substrate (45) in a process chamber (80) having a voltage supply terminal (65) for charging the chuck (20). The chuck includes an electrostatic member (25) comprising at least one electrode (30), an electrically insulated holding surface (40) for holding a substrate (45) thereon, and an electrical contact surface (48) for providing charge to the electrode. A unidirectionally conducting coupler layer (70) electrically couples the contact surface (48) of the electrostatic member to the voltage supply terminal to conduct charge substantially only in a single direction from the terminal to the contact surface. Preferably, an electrical connector (50) having a junction surface (55) bonded to the contact surface (55) of the electrode, and a terminal surface (60) for electrically contacting the voltage supply terminal (65), is used to electrically couple the unidirectionally conducting coupler layer (70) to the voltage supply terminal (65).

Abstract: A method of etching a multicomponent alloy on a substrate, without forming etchant residue on the substrate, is described. In the method, the substrate is placed in a process chamber comprising a plasma generator and plasma electrodes. A process gas comprising a volumetric flow ratio V.sub.r of (i) a chlorine-containing gas capable of ionizing to form dissociated Cl.sup.+ plasma ions and non-dissociated Cl.sub.2.sup.+ plasma ions, and (ii) an inert gas capable of enhancing dissociation of the chlorine-containing gas, in introduced into the process chamber. The process gas is ionized to form plasma ions that energetically impinge on the substrate by (i) applying RF current at a first power level to the plasma generator, and (ii) applying RF current at a second power level to the plasma electrodes. The combination of (i) the volumetric flow ratio V.sub.r of the process gas and (ii) the power ratio P.sub.

Abstract: A removable insulation jacket for a fluid carrying conduit includes an inner backing layer preformed to securely fit around the conduit. Insulation material is affixed to the inner backing layer and joined to an outer shell. The insulation jacket is placed around the conduit by engaging the insulation jacket with the conduit along an axial opening formed along the length of the insulation jacket, and the opening is then sealed at the outer shell to secure the insulation material about the conduit. The insulation jacket is pleated to conform to bends and curves that may occur along the length of the conduit.

Abstract: A process for fabricating an electrostatic chuck (20) comprising the steps of (c) forming a base (80) having an upper surface with cooling grooves (85) therein, the grooves sized and distributed for holding a coolant therein for cooling the base; and (d) pressure conforming an electrical insulator layer (45) to the grooves on the base by the steps of (i) placing the base into a pressure forming apparatus (25) and applying an electrical insulator layer over the grooves in the base; and (ii) applying a sufficiently high pressure onto the insulator layer to pressure conform the insulator layer to the grooves to form a substantially continuous layer of electrical insulator conformal to the grooves on the base.

Abstract: A failure resistant electrostatic chuck 20 for holding a substrate 35 during processing of the substrate 35, is described. The chuck 20 comprises a plurality of electrodes 25 covered by an insulator 30, the electrodes 25 capable of electrostatically holding a substrate 35 when a voltage is applied thereto. An electrical power bus 40 has a plurality of output terminals 45 that conduct voltage to the electrodes 25. Fuses 50 electrically connect the electrodes 25 to the output terminals 45 of the power bus 40, each fuse 50 connecting at least one electrode 25 in series to an output terminal from the power bus 40. The fuses 50 are capable of electrically disconnecting the electrode 25 from the output terminals 45 when the insulator 30 punctures and exposes the electrode 25 to the process environment causing a current to flow through the fuse 50.

Abstract: An electrostatic chuck (20) for holding a substrate (75) comprises (i) a base (80) having an upper surface (95) with grooves (85) therein, the grooves (85) sized and distributed for holding coolant for cooling a substrate (75), and (ii) a substantially continuous insulator film (45) conformal to the grooves (85) on upper surface (95) of the base (80). The base (80) can be electrically conductive and capable of serving as the electrode (50) of the chuck (20), or the electrode (50) can be embedded in the insulator film (45). The insulator film (45) has a dielectric breakdown strength sufficiently high that when a substrate (75) placed on the chuck (20) and electrically biased with respect to the electrode (50), electrostatic charge accumulates in the substrate (75) and in the electrode (50) forming an electrostatic force that attracts and holds the substrate (75) to the chuck (20).

Abstract: An electrostatic chuck (20) comprises at least one mesh electrode (30) on an underlying dielectric layer (25), the mesh electrode having apertures therethrough. A monocrystalline ceramic (28) covers the mesh electrode (30). The monocrystalline ceramic (28) comprises a layer of large crystals substantially oriented to one another, the layer of crystals having a resistivity sufficiently high to electrically insulate the mesh electrode (30). The monocrystalline ceramic (28) further comprises integral bonding interconnects (40) that form a unitary structure with the layer of large crystals, the bonding interconnects extending through the apertures in the mesh electrode (30) to bond directly to the underlying dielectric layer (25), substantially without adhesive.

Abstract: In accordance with the present invention, the plasma dry cleaning rate of semiconductor process chamber walls can be improved by placing a non-gaseous dry cleaning enhancement material in the position which was occupied by the workpiece during semiconductor processing. The non-gaseous dry cleaning enhancement material is either capable of generating dry cleaning reactive species and/or of reducing the consumption of the dry cleaning reactive species generated from the plasma gas feed to the process chamber. When process chamber non-volatile contaminant deposits are removed from plasma process chamber surfaces during plasma dry cleaning by placing a non-gaseous source of reactive-species-generating material within the plasma process chamber, the non-gaseous source of reactive-species-generating material need not be loacted upon or adjacent the workpiece support platform: however, this location provides excellent cleaning results in typical process chamber designs.

Abstract: The plasma dry cleaning rate of semiconductor process chamber walls can be improved by placing a non-gaseous dry cleaning enhancement material in the position which was occupied by the workpiece during semiconductor processing. The non-gaseous dry cleaning enhancement material is either capable generating dry cleaning reactive species and/or of reducing the consumption of the dry cleaning reactive species generated from the plasma gas feed to the process chamber.When process chamber non-volatile contaminant deposits are removed from plasma process chamber surfaces during plasma dry cleaning by placing a non-gaseous source of reactive-species-generating material within the plasma process chamber, the non-gaseous source of reactive-species-generating material need not be located upon or adjacent the workpiece support platform: however, this location provides excellent cleaning results in typical process chamber designs.

Abstract: A semiconductor processing chamber includes a substrate support member on which the substrate is positioned during processing in the chamber. To align the substrate on the substrate support member, an alignment member extends about the perimeter of the substrate receiving portion of the support member. The alignment member includes an alignment face thereon, which urges a substrate into alignment with the substrate receiving face of the support member as the substrate is deposited on the support member. The alignment member may also include a recessed portion, which ensures the presence of a gap between the edge of the substrate and the support member when the substrate contacts the support member.

Abstract: A multi-electrode electrostatic chuck (20) for holding a substrate (42) such as a silicon wafer during processing is described. The electrostatic chuck (20) comprises (i) a first electrode (22), (ii) a second electrode (24), and (iii) an insulator (26) having a lower portion (26a), a middle portion (26b) and an upper portion (26c). The lower portion (26a) of the insulator (26) is below the first electrode (22) and has a bottom surface (28) suitable for resting the chuck (20) on a support (44) in a process chamber (41). The middle portion (26b) of the insulator (26) lies between the first and second electrodes (22), (24). The upper portion (26c) of the insulator (26) is on the second electrode (24), and has a top surface (30) suitable for holding a substrate (42). The first and second electrodes (22, 24) can have a unipolar or bipolar configurations. In operation, the chuck (20) is placed on a support (44) in a process chamber (41) so that the bottom surface (28) of the chuck (20) rests on the support (44).

Abstract: The present invention is a method for bonding a lubricant onto the surface of rotating storage media. In particular, the method bonds reactive and non-reactive lubricants onto the carbon based protective coating of a magnetic storage disk. The lubricant is first applied onto the disk surface through conventional coating techniques, such as dipping, spinning, spraying, or vapor deposition. The thickness of the applied coating is thicker than the final bonded thickness of the lubricant. Typically, the applied thickness of the film is approximately 30 Angstroms. The lubricant coated disk surface is then exposed to low energy electron irradiation. The energy level of the accelerated electrons is below 100 eV. The lubricated film is exposed to a dosage level of approximately 1000 microcoulombs per square centimeter. This dosage level bonds approximately 15 Angstroms of lubricant to the disk surface. The non-bonded or excess lubricant is then rinsed off in a liquid freon or other suitable rinse.

Abstract: According to the present invention, a blank of an aluminum alloy is partially cut so as to form several disks maintained in the blank by portions of the remaining uncut aluminum. This results in the disks being supported in the blank during formation of the thin films, yet easily separated from the blank into individual disks after the thin films have been deposited. Therefore, multiple disks can be processed during a single manufacturing step.