Abstract: A plasma process reactor is disclosed that allows for greater control in varying the functional temperature range for enhancing semiconductor processing and reactor cleaning. The temperature is controlled by splitting the process gas flow from a single gas manifold that injects the process gas behind the gas distribution plate into two streams where the first stream goes behind the gas distribution plate and the second stream is injected directly into the chamber. By decreasing the fraction of flow that is injected behind the gas distribution plate, the temperature of the gas distribution plate can be increased. The increasing of the temperature of the gas distribution plate results in higher O2 plasma removal rates of deposited material from the gas distribution plate. Additionally, the higher plasma temperature aids other processes that only operate at elevated temperatures not possible in a fixed temperature reactor.

Abstract: A novel batch processing system used, for example, in plasma etching and chemical vapor deposition, wherein the pressure in the reactor is cycled through a varying pressure to increase the transfer of the reactant materials to the center of the wafer. One version of the invention provides a method that includes the steps of (I) feeding reactant gases into a reaction vessel, (ii) exhausting unused reactive gases and/or reaction by-products from the reaction vessel, and (iii) cycling the pressure in the reaction vessel between a higher pressure Phigh and a lower pressure Plow. Another version of the invention provides an apparatus that comprises (I) a reaction vessel, (ii) a feed means for feeding reactive gases into the reaction vessel, (iii) an exhaust means for exhausting unused reactive gases and/or reaction by-products from the reaction vessel, and (d) a pressure control means for cycling the pressure in the reaction vessel between a higher pressure Phigh and a lower pressure Plow.

Abstract: An apparatus and method for providing a modulated-bias plasma are described. In particular, an RF source or collector includes one or more sources to provide differing driving frequencies or bias frequencies, respectively. These frequencies, over time, interfere with one another to produce beating at one or more controllable, infinitely variable beat frequencies. As a beat frequency has significantly fewer cycles per second than a driving or bias frequency, a modulated-bias plasma may be provided without turning power on and off as in conventional “pulsed” plasma systems. Beat frequencies facilitate modulation of the driving or bias frequencies, which may lie within a relatively narrow frequency band. Also, the use of a plurality of driving or bias frequencies facilitates use of more conventional RF sources or collectors owing to lower power requirements at each frequency.

Abstract: An apparatus and method for providing a modulated-bias plasma are described. In particular, a radio frequency (RF) source or collector includes one or more sources to provide differing driving frequencies or bias frequencies, respectively. These frequencies, over time, interfere with one another to produce beating at one or more controllable, infinitely variable beat frequencies. As a beat frequency has significantly fewer cycles per second than a driving or bias frequency, a modulated-bias plasma may be provided without turning power on and off as in conventional “pulsed” plasma systems. Beat frequencies facilitate modulation of the driving or bias frequencies, which may lie within a relatively narrow frequency band. Also, the use of a plurality of driving or bias frequencies facilitates use of more conventional RF sources or collectors owing to lower power requirements at each frequency.

Abstract: A plasma process reactor is disclosed that allows for greater control in varying the functional temperature range for enhancing semiconductor processing and reactor cleaning. The temperature is controlled by splitting the process gas flow from a single gas manifold that injects the process gas behind the gas distribution plate into two streams where the first stream goes behind the gas distribution plate and the second stream is injected directly into the chamber. By decreasing the fraction of flow that is injected behind the gas distribution plate, the temperature of the gas distribution plate can be increased. The increasing of the temperature of the gas distribution plate results in higher O2 plasma removal rates of deposited material from the gas distribution plate. Additionally, the higher plasma temperature aids other processes that only operate at elevated temperatures not possible in a fixed temperature reactor.

Abstract: In one aspect, the invention encompasses a semiconductor processing method of forming a material over an uneven surface topology. A substrate having an uneven surface topology is provided. The uneven surface topology comprises a valley between a pair of outwardly projecting features. A layer of material is formed over the uneven surface topology. The layer comprises outwardly projecting portions over the outwardly projecting features of the surface topology and has a gap over the valley. The layer is etched, and the etching forms protective material within the gap while removing an outermost surface of the layer. The etching substantially does not remove the material from the bottom of the gap. In another aspect, the invention encompasses a semiconductor processing method of forming a material over metal-comprising lines. A first insulative material substrate is provided. A pair of spaced metal-comprising lines are formed over the substrate.

Abstract: A novel batch processing system used, for example, in plasma etching and chemical vapor deposition, wherein the pressure in the reactor is cycled through a varying pressure to increase the transfer of the reactant materials to the center of the wafer. One version of the invention provides a method that includes the steps of (I) feeding reactant gases into a reaction vessel, (ii) exhausting unused reactive gases and/or reaction by-products from the reaction vessel, and (iii) cycling the pressure in the reaction vessel between a higher pressure Phigh and a lower pressure Plow. Another version of the invention provides an apparatus that comprises (I) a reaction vessel, (ii) a feed means for feeding reactive gases into the reaction vessel, (iii) an exhaust means for exhausting unused reactive gases and/or reaction by-products from the reaction vessel, and (d) a pressure control means for cycling the pressure in the reaction vessel between a higher pressure Phigh and a lower pressure Plow.

Abstract: Methods of forming contact openings and methods of controlling the degree of taper of contact openings are described. In one implementation, a layer is first etched through a contact mask opening using a first set of etching conditions. The etching conditions provide a first degree of sidewall taper from vertical, if etching completely through the layer. After the first etching, the layer is second etched through the contact mask opening using a second set of etching conditions. The second set of etching conditions provide a second degree of sidewall taper from vertical, if etching completely through the layer. The second degree of sidewall taper is different from the first degree of taper. In another embodiment, a material through which a contact opening is to be etched to a selected depth is formed over a substrate. A masking layer having an opening therein is formed over the material.

Abstract: This invention is a hardware modification which permits greater uniformity of etching to be achieved in a high-density-source plasma reactor (i.e., one which uses a remote source to generate a plasma, and which also uses high-frequency bias power on the wafer chuck). The invention addresses the uniformity problem which arises as the result of nonuniform power coupling between the wafer and the walls of the etch chamber. The solution to greatly mitigate the nonuniformity problem is to increase the impedance between the wafer and the chamber walls. This may be accomplished by placing a cylindrical dielectric wall around the wafer. Quartz is a dielectric material that is ideal for the cylindrical wall if silicon is to be etched selectively with respect to silicon dioxide, as quartz it is virtually inert under such conditions.

Abstract: A plasma etching method includes forming a polymer comprising carbon and a halogen over at least some internal surfaces of a plasma etch chamber. After forming the polymer, plasma etching is conducted using a gas which is effective to etch polymer from chamber internal surfaces. In one implementation, the gas has a hydrogen component effective to form a gaseous hydrogen halide from halogen liberated from the polymer. In one implementation, the gas comprises a carbon component effective to getter the halogen from the etched polymer. In another implementation, a plasma etching method includes positioning a semiconductor wafer on a wafer receiver within a plasma etch chamber. First plasma etching of material on the semiconductor wafer occurs with a gas comprising carbon and a halogen. A polymer comprising carbon and the halogen forms over at least some internal surfaces of the plasma etch chamber during the first plasma etching.

Abstract: An etching method for forming an opening includes providing a substrate assembly having a surface and an oxide layer thereon. A patterned mask layer is provided over the oxide layer exposing a portion of the oxide layer. A plasma including one or more of CxHyFz+ ions and CxFz+ ions and further including xenon or krypton ions is used to etch the oxide layer at the exposed portion to define the opening in the oxide layer while simultaneously depositing a polymeric residue on a surface defining the opening. The etching is continued until the opening in the oxide layer is selectively etched to the surface of the substrate assembly.

Abstract: In one aspect, the invention encompasses a semiconductor processing method of forming a material over an uneven surface topology. A substrate having an uneven surface topology is provided. The uneven surface topology comprises a valley between a pair of outwardly projecting features. A layer of material is formed over the uneven surface topology. The layer comprises outwardly projecting portions over the outwardly projecting features of the surface topology and has a gap over the valley. The layer is etched, and the etching forms protective material within the gap while removing an outermost surface of the layer. The etching substantially does not remove the material from the bottom of the gap. In another aspect, the invention encompasses a semiconductor processing method of forming a material over metal-comprising lines. A first insulative material substrate is provided. A pair of spaced metal-comprising lines are formed over the substrate.

Abstract: In but one aspect of the invention, a plasma etching method includes forming polymer material over at least some internal surfaces of a dual powered plasma etch chamber while first plasma etching an outer surface of a semiconductor wafer received by a wafer holder within the chamber. After the first plasma etching, second plasma etching is conducted of polymer material from the chamber internal surfaces while providing a bias power at the wafer holder effective to produce an ac peak voltage at the wafer surface of greater than zero and less than 200 Volts. In one implementation, second plasma etching is conducted of polymer material from the chamber internal surfaces while providing a bias power at the wafer holder of greater than zero Watts and less or equal to about 1 Watt/cm2 of wafer surface area on one side.

Abstract: A container for use in a processing chamber to lessen the amount of contaminant particles found within the chamber after processing. The container fits closely within the chamber and includes ports for a gas conduit and a vacuum conduit. The container may be locked to the chamber through a locking mechanism and a recess in the container. The container may be guided into the chamber with a plurality of chamfers. The container may be used in inductively coupled plasma chambers, electron cyclotron resonance chambers, and chambers capable of receiving microwaves.

Abstract: In one aspect, the invention encompasses a semiconductor processing method of forming a material over an uneven surface topology. A substrate having an uneven surface topology is provided. The uneven surface topology comprises a valley between a pair of outwardly projecting features. A layer of material is formed over the uneven surface topology. The layer comprises outwardly projecting portions over the outwardly projecting features of the surface topology and has a gap over the valley. The layer is etched, and the etching forms protective material within the gap while removing an outermost surface of the layer. The etching substantially does not remove the material from the bottom of the gap. In another aspect, the invention encompasses a semiconductor processing method of forming a material over metal-comprising lines. A first insulative material substrate is provided. A pair of spaced metal-comprising lines are formed over the substrate.

Abstract: A container for use in a processing chamber to lessen the amount of contaminant particles found within the chamber after processing. The container fits closely within the chamber and includes ports for a gas conduit and a vacuum conduit. The container may be locked to the chamber through a locking mechanism and a recess in the container. The container may be guided into the chamber with a plurality of chamfers. The container may be used in inductively coupled plasma chambers, electron cyclotron resonance chambers, and chambers capable of receiving microwaves.

Abstract: An etching method for forming an opening includes providing a substrate assembly having a surface and an oxide layer thereon. A patterned mask layer is provided over the oxide layer exposing a portion of the oxide layer. A plasma including one or more of CxHyFz+ ions and CxFz+ ions and further including xenon or krypton ions is used to etch the oxide layer at the exposed portion to define the opening in the oxide layer while simultaneously depositing a polymeric residue on a surface defining the opening. The etching is continued until the opening in the oxide layer is selectively etched to the surface of the substrate assembly.

Abstract: An inductively coupled plasma-based device for use during integrated circuit fabrication is described which includes a planar coil electrode positioned adjacent to a dielectric structure physically separating the electrode from a reaction chamber in which a plasma is formed. The electrode presents a variable width adjacent to the dielectric structure, with the width of inner coil windings being less than the width of outer coil windings. The electrode is connected to a terminal capacitance, whose value may be varied to present different voltage amplitudes at different locations along the coil electrode. By locating the larger width coil windings near the reaction chamber walls, and by varying the capacitance value of the terminal capacitor, improved plasma-based processing may result.

Abstract: Plasma processing tools, dual-source plasma etchers, and etching methods are described. In one embodiment, a processing chamber is provided having an interior base and an interior sidewall joined with the base. A generally planar inductive source is mounted proximate the chamber. A dielectric liner is disposed within the chamber over the interior sidewall with the liner being received over less than an entirety of the interior sidewall. In a preferred embodiment, the interior sidewall has a groundable portion and the dielectric liner has a passageway positioned to expose the groundable interior sidewall portion. Subsequently, a plasma developed within the chamber is disposed along a grounding path which extends to the exposed interior sidewall. In another preferred embodiment, the dielectric liner is removably mounted within the processing chamber.

Abstract: Plasma processing tools, dual-source plasma etchers, and etching methods are described. In one embodiment, a processing chamber is provided having an interior base and an interior sidewall joined with the base. A generally planar inductive source is mounted proximate the chamber. A dielectric liner is disposed within the chamber over the interior sidewall with the liner being received over less than an entirety of the interior sidewall. In a preferred embodiment, the interior sidewall has a groundable portion and the dielectric liner has a passageway positioned to expose the groundable interior sidewall portion. Subsequently, a plasma developed within the chamber is disposed along a grounding path which extends to the exposed interior sidewall. In another preferred embodiment, the dielectric liner is removably mounted within the processing chamber.