Abstract: A fluorine-free integrated process for plasma etching aluminum lines in an integrated circuit structure including an overlying anti-reflection coating (ARC) and a dielectric layer underlying the aluminum, the process being preferably performed in a single plasma reactor. The ARC open uses either BCl3/Cl2 or Cl2 and possibly a hydrocarbon passivating gas, preferably C2H4. The aluminum main etch preferably includes BCl3/Cl2 etch and C2H4 diluted with He. The dilution is particularly effective for small flow rates of C2H4. An over etch into the Ti/TiN barrier layer and part way into the underlying dielectric may use a chemistry similar to the main etch. A Cl2/O2 chamber cleaning may be performed, preferably with the wafer removed from the chamber and after every wafer cycle.

Abstract: A method of etching a noble metal electrode layer disposed on a substrate to produce a semiconductor device including a plurality of electrodes separated by a distance equal to or less than about 0.35 ?m and having a noble metal profile equal to or greater than about 80°. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the noble metal electrode layer by employing a high density inductively coupled plasma of an etchant gas comprising a gas selected from the group consisting of nitrogen, oxygen, a halogen (e.g., chlorine), argon, and a gas selected from the group consisting of BCl3, HBr, and SiCl4 mixtures thereof. Masking methods and etching sequences for patterning high density RAM capacitors are also provided.

Abstract: A method of etching a platinum electrode layer disposed on a substrate to produce a semiconductor device including a plurality of platinum electrodes. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the platinum electrode layer by employing a plasma of an etchant gas comprising nitrogen and a halogen (e.g. chlorine), and a gas selected from the group consisting of a noble gas (e.g. argon), BCl3, HBr, SiCl4 and mixtures thereof. The substrate may be heated in a reactor chamber having a dielectric window including a deposit-receiving surface having a surface finish comprising a peak-to-valley roughness height with an average height value of greater than about 1000 Å.

Abstract: A fluorine-free integrated process for plasma etching aluminum lines in an integrated circuit structure including an overlying anti-reflection coating (ARC) and a dielectric layer underlying the aluminum, the process being preferably performed in a single plasma reactor. The ARC open uses either BCl3/Cl2 or Cl2 and possibly a hydrocarbon passivating gas, preferably C2H4. The aluminum main etch preferably includes BCl3/Cl2 etch and C2H4 diluted with He. The dilution is particularly effective for small flow rates of C2H4. An over etch into the Ti/TiN barrier layer and part way into the underlying dielectric may use a chemistry similar to the main etch. A Cl2/O2 chamber cleaning may be performed, preferably with the wafer removed from the chamber and after every wafer cycle.

Abstract: A method and apparatus for use in conjunction with a plasma reaction chamber provide both throttling functionality and independent vacuum isolation for a turbomolecular pump. A throttle valve provides for precise reaction chamber pressure regulation, and a gate valve prevents extended exposure of the turbomolecular pump to atmospheric conditions during cleaning or other maintenance operations. The throttle valve and the gate valve may be actuated independently.

Abstract: A method of etching a noble metal electrode layer disposed on a substrate to produce a semiconductor device including a plurality of electrodes separated by a distance equal to or less than about 0.35 &mgr;m and having a noble metal profile equal to or greater than about 80°. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the noble metal electrode layer by employing a high density inductively coupled plasma of an etchants gas comprising a gas selected from the group consisting nitrogen, oxygen, a halogen (e.g., chlorine), argon, and a gas selected from the group consisting of BCl3, HBr, and SiCl4 mixtures thereof. A semiconductor device having a substrate and a plurality of noble metal electrodes supported by the substrate. The noble metal electrodes have a dimension (e.g., a width) which include a value equal to or less than about 0.3 &mgr;m and a platinum profile equal to or greater than about 85°.

Abstract: A method of etching a platinum electrode layer disposed on a substrate to produce a semiconductor device including a plurality of platinum electrodes. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the platinum electrode layer by employing a plasma of an etchant gas comprising nitrogen and a halogen (e.g. chlorine), and a gas selected from the group consisting of a noble gas (e.g. argon), BCl3, HBr, SiCl4 and mixtures thereof. The substrate may be heated in a reactor chamber having a dielectric window including a deposit-receiving surface having a surface finish comprising a peak-to-valley roughness height with an average height value of greater than about 1000 Å.

Abstract: A method of processing a metal layer on a substrate. The method comprises disposing the substrate in a chamber having a dielectric member and processing gas. An interior surface of the dielectric member is heated to a temperature above about 150° C. and the metal layer is processed when processing power is passed through the heated dielectric member. Heating of the interior surface of the dielectric member essentially prevents deposits from forming on the interior surface and allows a stable power transmission through the dielectric member.

Abstract: A method of etching a platinum electrode layer disposed on a substrate to produce a semiconductor device including a plurality of platinum electrodes. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the platinum electrode layer by employing a plasma of an etchant gas comprising nitrogen and a halogen (e.g. chlorine), and a gas selected from the group consisting of a noble gas (e.g. argon), BCl3, HBr, SiCl4 and mixtures thereof. The substrate may be heated in a reactor chamber having a dielectric window including a deposit-receiving surface having a surface finish comprising a peak-to-valley roughness height with an average height value of greater than about 1000 Å.

Abstract: An assembly for allowing stable power transmission into a plasma processing chamber comprising a dielectric member; and at least one material deposition support assembly secured to the dielectric member for receiving and supporting the deposition of materials during processing of a substrate and a chamber having a controlled environment and containing a plasma of a processing gas. A plasma reactor for processing substrates having a reactor chamber including a chamber sidewall and a dielectric window supported by the chamber sidewall. A plurality of deposition support members is coupled to an inside surface of the dielectric window for receiving and supporting a deposition of materials during processing of substrates. In an alternative embodiment of the invention, the plurality of deposition support members is connected to a liner assembly instead of to the dielectric window. The liner assembly is supported by the chamber sidewall.

Abstract: An RF plasma etch reactor having an etch chamber with electrically conductive walls and a protective layer forming the portion of the walls facing the interior of the chamber. The protective layer prevents sputtering of material from the chamber walls by a plasma formed within the chamber. The etch reactor also has an inductive coil antenna disposed within the etch chamber which is used to generate the plasma by inductive coupling. Like the chamber walls, the inductive coil antenna is constructed to prevent sputtering of the material making up the antenna by the plasma. The coil antenna can take on any configuration (e.g. location, shape, orientation) that is necessary to achieve a desired power deposition pattern within the chamber. Examples of potential coil antenna configurations for achieving the desired power deposition pattern include constructing the coil antenna with a unitary or a segmented structure.

Abstract: A method of etching an electrode layer (e.g., a platinum electrode layer or an iridium electrode layer) disposed on a substrate to produce a semiconductor device including a plurality of electrodes separated by a distance equal to or less than about 0.3 &mgr;m and having a profile equal to or greater than about 85°. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the electrode layer by employing a high density inductively coupled plasma of an etchant gas comprising oxygen and/or chlorine, argon and a gas selected from the group consisting of BCl3, HBr, HCl and mixtures thereof. A semiconductor device having a substrate and a plurality of electrodes supported by the substrate. The electrodes have a dimension (e.g., a width) which include a value equal to or less than about 0.3 &mgr;m and a profile equal to or greater than about 85°.

Abstract: A plasma etch reactor having interior surfaces facing the plasma composed of boron carbide, preferably principally composed of B.sub.4 C. The boron carbide may be a bulk sintered body or may be a layer of boron carbide coated on a chamber part. The boron carbide coating may be applied by thermal spraying, such as plasma spraying, by chemical vapor deposition, or by other layer forming technique such as a surface converting reaction. The boron carbide is highly resistant to high-density plasma etchants such as BCl.sub.3. The plasma sprayed coating is advantageously applied to only a portion of an anodized aluminum wall. The boron carbide may be sprayed over the exposed portion of the aluminum over which the anodization has been removed. A band of the aluminum substrate at the transition between the anodization and the boron carbide is roughened prior to anodization so that the boron carbide sticks to the correspondingly roughened surface of the anodization.

Abstract: An electrically activated focus ring (90) for plasma processing a substrate (25) in a plasma zone comprises a dielectric barrier (92) with a plasma focusing surface (95) for focusing the plasma onto the substrate surface, and an opposing surface (98). The focus ring (90) comprises an electrical conductor element (100) abutting at least a portion of the opposing surface (98) of the dielectric barrier (92). The conductor element (100) is electrically isolated from the plasma and capable of being electrically charged to attract the plasma to reduce formation of deposits on the plasma focusing surface (95) of the dielectric barrier (92).

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 gas injection system for injecting gases into a plasma reactor having a vacuum chamber with a sidewall, a pedestal for holding a semiconductor wafer to be processed, and a RF power applicator for applying RF power into the chamber. The gas injection system includes at least one gas supply containing gas, a gas distribution apparatus which has at least one slotted aperture facing the interior of the chamber, and one or more gas feed lines connecting the gas supply or supplies to the gas distribution apparatus. A preferred embodiment of a radial gas distribution apparatus in accordance with the present invention is disposed in the chamber sidewall and includes plural gas distribution nozzles each with a slotted aperture facing an interior of the chamber. Gas feed lines are employed to respectively connect each gas distribution nozzle to separate ones of the gas supplies.

Abstract: The present invention provides an apparatus and process for plasma cleaning the interior surfaces of semiconductor processing chambers. The method is directed to the dry etching of accumulated contaminant residues attached to the inner surfaces of the plasma processing chamber and includes introducing a cleaning gas mixture of a halogen-containing gas; activating a plasma in an environment substantially free of oxygen species; contacting the contaminant residues with the activated cleaning gas to volatilize the residues; and removing the gaseous by-products from the chamber. The etchant gaseous mixture comprises an even or greater amount of at least one fluorine-containing gas and an even or lesser amount of at least one chlorine-containing gas. The instant invention enables the intermittent use of the cleaning steps in an ongoing plasma processing of semiconductor wafers without chamber downtime and significant loss of wafer production.

Abstract: The invention is embodied in a gas injection apparatus for injecting gases into a plasma reactor vacuum chamber having a chamber housing, a pedestal holding a workpiece to be processed, a device for applying RF energy into the chamber, the gas injection apparatus having a gas supply containing an etchant species in a gas, an opening in the chamber housing, a gas distribution apparatus disposed within the opening in the chamber housing which has at least one slotted aperture facing the interior of the chamber and a device for controlling the flow rate of gas from the one or more slotted apertures, and a gas feed line from the supply to the gas distribution apparatus. In a preferred embodiment, the gas distribution apparatus includes a center member surrounded by at least one annular member with a gap therebetween comprising the slotted aperture. Preferably, each of the members of the gas distribution apparatus comprises a material at least nearly impervious to attack from the etchant species.

Abstract: The invention is embodied in a gas injection apparatus for injecting gases into a plasma reactor vacuum chamber having a chamber housing, a pedestal holding a workpiece to be processed, means for applying RF energy into the chamber, the gas injection apparatus having a gas supply containing an etchant species in a gas, an opening in the chamber housing, a gas feed line from the supply to the opening in the chamber housing, and gas distribution apparatus near the opening in the chamber housing, the gas feed apparatus having at least one slit nozzle facing the interior of the chamber. In a preferred embodiment, the gas distribution apparatus includes a disk member surrounded by at least one annular member with a gap therebetween comprising the slit nozzle, the disk member and annular member blocking gas flow through the opening in the chamber housing. Preferably, each of the members of the gas distribution apparatus comprises a material at least nearly impervious to attack from the etchant species.

Abstract: A process for passivating, and optionally stripping and inhibiting corrosion of an etched substrate (20), is described. In the process, a substrate (20) having etchant byproducts (24) thereon, is placed into a vacuum chamber (52), and passivated in a multicycle passivation process comprising at least two passivating steps. In each passivating step, passivating gas is introduced into the vacuum chamber (52) and a plasma is generated from the passivating gas. When the substrate also has remnant resist (26) thereon, the resist (26) is stripped in a multicycle passivation and stripping process, each cycle including a passivating step and a stripping step. The stripping step is performed by introducing a stripping gas into the vacuum chamber (52) and generating a plasma from the stripping gas. In the multicycle process, the passivating and optional stripping steps, are repeated at least once in the same order that the steps were done.