Abstract: A first embodiment of the present invention pertains to a method of patterning a semiconductor device conductive feature while permitting easy removal of any residual masking layer which remains after completion of the etching process. A multi-layered masking structure is used which includes a layer of high-temperature organic-based masking material overlaid by either a patterned layer of inorganic masking material or by a layer of patterned high-temperature imageable organic masking material. The inorganic masking material is used to transfer a pattern to the high-temperature organic-based masking material and is then removed. The high-temperature organic-based masking material is used to transfer the pattern and then may be removed if desired. This method is also useful in the pattern etching of aluminum, even though aluminum can be etched at lower temperatures.

Abstract: The invention is embodied in a plasma reactor for processing a semiconductor wafer, the reactor having a pair of parallel capacitive electrodes at the ceiling and base of the processing chamber, respectively, each of the capacitive electrodes capacitively coupling RF power into the chamber in accordance with a certain RF phase relationship between the pair of electrodes during processing of the semiconductor wafer for ease of plasma ignition and precise control of plasma ion energy and process reproducibility, and an inductive coil wound around a portion of the chamber and inductively coupling RF power into the chamber for independent control of plasma ion density. Preferably, in order to minimize the number of RF sources while providing independent power control, the invention includes power splitting to separately provide power from a common source or sources to the pair of electrodes and to the coil.

Abstract: Copper can be pattern etched at acceptable rates and with selectivity over adjacent materials using an etch process which utilizes a solely physical process which we have termed "enhanced physical bombardment". Enhanced physical bombardment requires an increase in ion density and/or an increase in ion energy of ionized species which strike the substrate surface. To assist in the removal of excited copper atoms from the surface being etched, the power to the ion generation source and/or the substrate offset bias source may be pulsed. In addition, when the bombarding ions are supplied from a remote source, the supply of these ions may be pulsed. Further, thermal phoresis may be used by maintaining a substrate temperature which is higher than the temperature of a surface in the etch chamber.

Abstract: Copper can be pattern etched in a manner which provides the desired feature dimension and integrity, at acceptable rates, and with selectivity over adjacent materials. To provide for feature integrity, the portion of the copper feature surface which has been etched to the desired dimensions and shape must be protected during the etching of adjacent feature surfaces. To avoid the trapping of reactive species interior of the etched copper surface, hydrogen is applied to that surface. Hydrogen is adsorbed on the copper exterior surface and may be absorbed into the exterior surface of the copper, so that it is available to react with species which would otherwise penetrate that exterior surface and react with the copper interior to that surface. Sufficient hydrogen must be applied to the exterior surface of the etched portion of the copper feature to prevent incident reactive species present due to etching of adjacent feature surfaces from penetrating the previously etched feature exterior surface.

Abstract: In the preparation of semiconductor structures having multilevel copper conductive features which must be interconnected, it is frequently desired to remove portions of a copper layer deposited over a substrate. In particular, where lines and contacts are created by depositing a copper layer to fill trenches and vias present in a dielectric layer, it is desired to remove the portion of the copper layer which does not form the desired line or contact. The present invention provides a method of etching a copper layer (film) to remove the portion of the film which is not part of the desired conductive interconnect structure, while avoiding over etching of the structure and the formation of corrosive surface contaminants on the surface of the etched copper. The method of etching is referred to as the etchback process, since, in a typical fabrication process, the deposited copper layer is etched back to the upper or "field" surface of a substrate containing trenches and vias which are filled by the copper.

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: The invention is carried out in a plasma reactor for processing a semiconductor wafer, the plasma reactor having a chamber for containing a processing gas and having a conductor connected to an RF power source for coupling RF power into the reactor chamber to generate from the processing gas a plasma inside the chamber, the chamber containing at least one surface exposed toward the plasma and susceptible to contamination by particles produced during processing of the wafer, the invention being carried out by promoting, during processing of the wafer, bombarding of particles from the plasma onto the one surface to remove therefrom contaminants deposited during processing of the wafer. Such promoting of bombarding is carried out by providing an RF power supply and coupling, during processing of the wafer, RF power from the supply to the one surface. The coupling may be performed by a capacitive cleaning electrode adjacent the one surface, the capacitive cleaning electrode connected to the RF power supply.

Abstract: The plasma source power frequency in a plasma etch reactor is reduced to a low RF frequency such as about 2 MHz. It is a discovery of this invention that at this low frequency, capacitive coupling from the plasma power source is reduced, and the plasma source power level may be increased beyond 750 Watts to reduce capacitive coupling and provide a high density inductively coupled plasma without appreciably increasing the ion bombardment energy. Moreover, under these conditions the etchant (e.g., chlorine) concentration in the plasma may be increased to about 80 percent without decreasing etch uniformity to provide a very high metal alloy etch rate with complete residue removal, no profile microloading, and no etch rate microloading, the process being applicable over a wide window of metal alloy compositions.

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: An inductively coupled RF plasma reactor for processing semiconductor wafer includes a reactor chamber having a side wall and a ceiling, a wafer pedestal for supporting the wafer in the chamber, an RF power source, apparatus for introducing a processing gas into the reactor chamber, and a coil inductor adjacent the reactor chamber connected to the RF power source, the coil inductor including (a) a side section facing a portion of the side wall and including a bottom winding and a top winding, the top winding being at a height corresponding at least approximately to a top height of the ceiling, and (b) a top section extending radially inwardly from the top winding of the side section so as to overlie at least a substantial portion of the ceiling. The present invention adheres to an optimized coil-dome geometry including a particular dome apex height range relative to the dome base and a particular wafer position range relative to the dome apex.

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 embodiment in a plasma reactor for processing a semiconductor wafer, the reactor having a pair of parallel capacitive electrodes at the ceiling and base of the processing chamber, respectively, each of the capacitive electrodes capacitvely coupling RF power into the chamber in accordance with a certain RF phase relationship between the pair of electrodes during processing of the semiconductor wafer for ease of plasma ignition and precise control of plasma ion energy and process reproducibility, and an inductive coil wound around a portion of the chamber and inductively coupling RF power into the chamber for independent control of plasma ion density. Preferably, in order to minimize the number of RF sources while providing independent power control, the invention includes power splitting to separately provide power from a common source or sources to the pair of electrodes and to the coil.