Abstract: Methods for depositing a ruthenium metal layer on a dielectric substrate are provided. The methods involve, for instance, exposing the dielectric substrate to an amine-containing compound, followed by exposing the substrate to a ruthenium precursor and an optional co-reactant such that the amine-containing compound facilitates the nucleation on the dielectric surface.

Abstract: A disclosed form of mechanically assisted electroplating leads to a flat, thin, overburden. In one example, an accelerator is deposited on a copper surface and mechanically removed in a simplified CMP-like apparatus. The wafer is then plated in an electrolyte containing little or no accelerating additives.

Abstract: To make a metal feature, a non-plateable layer is applied to a workpiece surface and then patterned to form a first plating region and a first non-plating region. Then, metal is deposited on the workpiece to form a raised field region in said first plating region and a recessed region in said first non-plating region. Then, an accelerator film is applied globally on the workpiece. A portion of the accelerator film is selectively removed from the field region, and another portion of the accelerator film remains in the recessed acceleration region. Then, metal is deposited onto the workpiece, and the metal deposits at an accelerated rate in the acceleration region, resulting in a greater thickness of metal in the acceleration region compared to metal in the non-activated field region. Then, metal is completely removed from the field region, thereby forming the metal feature.

Abstract: A process for enhancing the adhesion of directly plateable materials to an underlying dielectric is demonstrated, so as to withstand damascene processing. Using diffusion barriers onto which copper can be deposited facilitates conventional electrolytic processing. An ultra-thin adhesion layer is applied to a degassed, pre-cleaned substrate. The degassed and pre-cleaned substrate is exposed to a precursor gas containing the adhesion layer, optionally deposited by a plasma-assisted CVD process, resulting in the deposition of an adhesion layer inside the exposed feature. The treated wafer is then coated with a diffusion barrier material, such as ruthenium, so that the adhesion layer reacts with incoming diffusion barrier atoms. The adhesion layer may be selectively bias-sputter etched prior to the deposition of the diffusion barrier layer. A copper layer is then deposited on the diffusion barrier layer.

Abstract: A shielding system for a physical vapor deposition chamber having a sputter target above the pedestal. The shielding system comprises a pedestal shield attachable to the pedestal and movable therewith. The pedestal shield surrounds and extends outward from the pedestal toward the chamber side or lower walls. The system also comprises a sidewall shield adapted to extend substantially around and within the chamber sidewalls, and downward from an upper portion thereof. The sidewall shield has a lower end extending inward and disposed adjacent the pedestal shield upper portion when the pedestal is in the raised position. The pedestal shield and sidewall shield cooperate, when the pedestal is in the raised position, to prevent line-of-sight deposition transmission from the sputter target to the side and lower walls of the deposition chamber.

Abstract: A ruthenium-containing thin film is formed. Typically, the ruthenium-containing thin film has a thickness in a range of about from 1 nm to 20 nm. The ruthenium-containing thin film is annealed in an oxygen-free atmosphere, for example, in N2 forming gas, at a temperature in a range of about from 100° C. to 500° C. for a total time duration of about from 10 seconds to 1000 seconds. Thereafter, copper or other metal is deposited by electroplating or electroless plating onto the annealed ruthenium-containing thin film. In some embodiments, the ruthenium-containing thin film is also treated by UV radiation.

Abstract: An apparatus which can control thickness uniformity during deposition of conductive material from an electrolyte onto a surface of a semiconductor substrate is provided. The apparatus has an anode which can be contacted by the electrolyte during deposition of the conductive material, a cathode assembly including a carrier adapted to carry the substrate for movement during deposition, and a conductive element permitting electrolyte flow therethrough. A mask lies over the conductive element and has openings permitting electrolyte flow. The openings define active regions of the conductive element by which a rate of conductive material deposition onto the surface can be varied. A power source can provide a potential between the anode and the cathode assembly so as to produce the deposition. A deposition process is also disclosed, and uniform electroetching of conductive material on the semiconductor substrate surface can additionally be performed.

Abstract: This invention relates to electronic device fabrication processes for making devices such as semiconductor wafers and resolves the fluorine loading effect in the reaction chamber of a HDP CVD apparatus used for forming dielectric layers in high aspect ratio, narrow width recessed features. The fluorine loading effect in the chamber is minimized and wafers are provided having less deposition thickness variations by employing the method using a hydrogen plasma treatment of the chamber and the substrate after the chamber has been used to grow a dielectric film on a substrate. After the hydrogen plasma treatment of the chamber, the chamber is treated with an etchant gas to etch the substrate. Preferably a hydrogen gas is then introduced into the chamber after the etching process and the process repeated until the fabrication process is complete. The wafer is then removed from the chamber and a new wafer placed in the chamber and the above fabrication process repeated.

Abstract: A method is provided for measuring edge exclusion on a workpiece that includes a wafer having a film disposed thereon. The method is performed by a CMP system employing a platen and a thickness sensor coupled to the platen and positioned to repeatedly travel a path over the edge of the film during polishing. The method comprises measuring the thickness of the workpiece during selected iterations of the probe path, and establishing from the wafer thickness measurements the length of time the probe is over the film (ton) during the selected iterations. Edge exclusion is determined for at least one iteration utilizing a function related to ton.

Abstract: An apparatus for electropolishing a conductive layer on a wafer using a solution is disclosed. The apparatus comprises an electrode assembly immersed in the solution configured proximate to the conductive layer having a longitudinal dimension extending to at least a periphery of the wafer, the electrode assembly including an elongated contact electrode configured to receive a potential difference, an isolator adjacent the elongated contact electrode, and an elongated process electrode adjacent the isolator configured to receive the potential difference, a voltage supply is configured to supply the potential difference between the contact electrode and the process electrode to electropolish the conductive layer on the wafer.

Abstract: A system for electrochemical mechanical polishing of a conductive surface of a wafer is provided. The system includes a wafer holder to hold the wafer and a belt pad disposed proximate to the wafer to polish the conductive surface. Application of a potential difference between conductive surface and an electrode and establishing relative motion between the belt pad and the conductive surface result in material removal from the conductive surface. Electrical contact to the surface is provided through either contacts embedded in the belt pad or contacts placed adjacent the belt pad.

Abstract: A process for enhancing the adhesion of directly plateable materials to an underlying dielectric is demonstrated, so as to withstand damascene processing. Using diffusion barriers onto which copper can be deposited facilitates conventional electrolytic processing. An ultra-thin adhesion layer is applied to a degassed, pre-cleaned substrate. The degassed and pre-cleaned substrate is exposed to a precursor gas containing the adhesion layer, optionally deposited by a plasma-assisted CVD process, resulting in the deposition of an adhesion layer inside the exposed feature. The treated wafer is then coated with a diffusion barrier material, such as ruthenium, so that the adhesion layer reacts with incoming diffusion barrier atoms. The adhesion layer may be selectively bias-sputter etched prior to the deposition of the diffusion barrier layer. A copper layer is then deposited on the diffusion barrier layer.

Abstract: Methods and compositions have been provided for removing barrier layer material from a work piece during an electrochemical mechanical polishing process while protecting a metallization layer of the work piece. The electrochemical planarization composition includes at least one complexing agent capable of complexing with the barrier layer material when exposed to a pH outside of a pH range of greater than about pH 2 and less than about pH 10, a corrosion inhibitor, abrasive particles, and a pH adjuster.

Abstract: Copper diffusion barrier films having a boron-doped silicon carbide layer with at least 25% boron by atomic weight of the layer composition have advantages for semiconductor device integration schemes. The films have an integration worthy etch selectivity to carbon doped oxide of at least 10 to 1, can adhere to copper with an adhesion energy of at least 20 J/m2, and can maintain an effective dielectric constant of less than 4.5 in the presence of atmospheric moisture. The films are suitable for use in a wide range of VLSI and ULSI structures and devices.

Abstract: A method is provided for manufacturing removable contact structures on the surface of a substrate to conduct electricity from a contact member to the surface during electroprocessing. The method comprises forming a conductive layer on the surface. A predetermined region of the conductive layer is selectively coated by a contact layer so that the contact member touches the contact layer as the electroprocessing is performed on the conductive layer.

Abstract: Methods for accurate and conformal removal of atomic layers of materials make use of the self-limiting nature of adsorption of at least one reactant on the substrate surface. In certain embodiments, a first reactant is introduced to the substrate in step (a) and is adsorbed on the substrate surface until the surface is partially or fully saturated. A second reactant is then added in step (b), reacting with the adsorbed layer of the first reactant to form an etchant. The amount of an etchant, and, consequently, the amount of etched material is limited by the amount of adsorbed first reactant. By repeating steps (a) and (b), controlled atomic-scale etching of material is achieved. These methods may be used in interconnect pre-clean applications, gate dielectric processing, manufacturing of memory devices, or any other applications where removal of one or multiple atomic layers of material is desired.

Abstract: An active rinse shield designed to protect electrofill chemical baths from excessive dilution during rinse sprays on the semiconductor wafer. The shield uses overlapping blades to cover the bath, making a physical barrier between the bath chemistry and the wafer rinse water. The blades are interconnecting ribs that actuate around a common pivot axis. A linear mechanical actuator controls the blade movement, moving the top-most blade, which in turn, moves an adjacent lower blade. Each upper blade is interconnected to an adjacent lower blade by upper and lower ledges, a pivot boss and interlocking cut, and a curved ledge on each blade's body surface. The interconnecting features allow the blades to move one another out for extension or in for retraction. The interlocking blades are inclined above one another, forming grooves to redirect the rinse water away from the chemical bath.

Abstract: The present invention relates to methods for plating a conductive material on a substrate surface in a highly desirable manner. The invention removes at least one additive adsorbed on the top portion of the workpiece more than at least one additive disposed on a cavity portion, thereby allowing plating of the conductive material take place before the additive fully re-adsorbs onto the top portion and causing greater plating of the cavity portion relative to the top portion.

Abstract: Methods are provided for electrochemically depositing copper on a work piece. One method includes the step of depositing overlying the work piece a barrier layer having a surface and subjecting the barrier layer surface to a surface treatment adapted to facilitate deposition of copper on the barrier layer. Copper then is electrochemically deposited overlying the barrier layer.

Abstract: An accelerator solution is globally applied to a workpiece to form an accelerator film, and then a portion of the accelerator film is selectively removed from the workpiece to form an acceleration region having a higher concentration of accelerator. The higher concentration of accelerator causes metal to deposit at a faster rate in the acceleration region than in a non-accelerated region for the duration of metal deposition. To make a metal feature, a resist layer is applied to a workpiece surface and patterned to form a recessed region and a field region. Then, a metal seed layer is deposited on the workpiece surface. An accelerator solution is applied so that an accelerator film forms on the metal seed layer. A portion of the accelerator film is selectively removed from the field region, leaving another portion of the accelerator film in the recessed region.