Patent application number | Description | Published |
20080206986 | METHOD OF FORMING A COPPER-BASED METALLIZATION LAYER INCLUDING A CONDUCTIVE CAP LAYER BY AN ADVANCED INTEGRATION REGIME - By appropriately designing a plurality of deposition steps and intermediate sputter processes, the formation of a barrier material within a via opening may be accomplished on the basis of a highly efficient process strategy that readily integrates conductive cap layers formed above metal-containing regions into well-approved process sequences. | 08-28-2008 |
20090061621 | METHOD OF FORMING A METAL DIRECTLY ON A CONDUCTIVE BARRIER LAYER BY ELECTROCHEMICAL DEPOSITION USING AN OXYGEN-DEPLETED AMBIENT - By suppressing the presence of free oxygen during a cleaning process and a subsequent electrochemical deposition of a seed layer, the quality of a corresponding interface between the barrier material and the seed layer may be enhanced, thereby also improving performance and the characteristics of the finally obtained metal region. Thus, by identifying free oxygen as a main source for negatively affecting the characteristics of metals during a “direct on barrier” plating process, efficient strategies have been developed and are disclosed herein to provide a reliable technique for volume production of sophisticated semiconductor devices. | 03-05-2009 |
20090061629 | METHOD OF FORMING A METAL DIRECTLY ON A CONDUCTIVE BARRIER LAYER BY ELECTROCHEMICAL DEPOSITION USING AN OXYGEN-DEPLETED AMBIENT - By suppressing the presence of free oxygen during a cleaning process and a subsequent electrochemical deposition of a seed layer, the quality of a corresponding interface between the barrier material and the seed layer may be enhanced, thereby also improving performance and the characteristics of the finally obtained metal region. Thus, by identifying free oxygen as a main source for negatively affecting the characteristics of metals during a “direct on barrier” plating process, efficient strategies have been developed and are disclosed herein to provide a reliable technique for volume production of sophisticated semiconductor devices. | 03-05-2009 |
20090243109 | METAL CAP LAYER OF INCREASED ELECTRODE POTENTIAL FOR COPPER-BASED METAL REGIONS IN SEMICONDUCTOR DEVICES - A conductive cap material for a copper region may be provided with enhanced etch resistivity by taking into consideration the standard electrode potential of one or more of the species contained therein. For example, instead of a conventionally used CoWP alloy, a modified alloy may be used, by substituting the cobalt species by a metallic species having a less negative standard electrode potential, such as nickel. Consequently, device performance may be enhanced, while at the same time the overall process complexity may be reduced. | 10-01-2009 |
20090325375 | REDUCING LEAKAGE IN DIELECTRIC MATERIALS INCLUDING METAL REGIONS INCLUDING A METAL CAP LAYER IN SEMICONDUCTOR DEVICES - By introducing an additional heat treatment prior to and/or after contacting a sensitive dielectric material with wet chemical agents, such as an electrolyte solution, enhanced performance with respect to leakage currents or dielectric strength may be accomplished during the fabrication of advanced semiconductor devices. For example, metal cap layers for metal lines may be provided on the basis of electroless deposition techniques, wherein the additional heat treatment(s) may provide the required electrical performance. | 12-31-2009 |
20100024724 | APPARATUS AND METHOD FOR REMOVING BUBBLES FROM A PROCESS LIQUID - The present invention is directed to methods and apparatuses for removing bubbles from a process liquid. The process liquid can comprise a plating solution used in a plating tool. The process liquid is supplied to a tank. A plurality of streams of the process liquid are directed towards a surface of the process liquid from below. This can be done by feeding the process liquid to a flow distributor comprising a plurality of openings providing flow communication between an inner volume of the flow distributor and a main volume of the tank. Before leaving the tank through an outlet, the process liquid flows through a flow barrier. | 02-04-2010 |
20100133648 | MICROSTRUCTURE DEVICE INCLUDING A METALLIZATION STRUCTURE WITH SELF-ALIGNED AIR GAPS BETWEEN CLOSELY SPACED METAL LINES - In sophisticated metallization systems, air gaps may be formed on the basis of a self-aligned patterning regime during which the conductive cap material of metal lines may be protected by providing one or more materials, which may subsequently be removed. Consequently, the etch behavior and the electrical characteristics of metal lines during the self-aligned patterning regime may be individually adjusted. | 06-03-2010 |
20100221911 | PROVIDING SUPERIOR ELECTROMIGRATION PERFORMANCE AND REDUCING DETERIORATION OF SENSITIVE LOW-K DIELECTRICS IN METALLIZATION SYSTEMS OF SEMICONDUCTOR DEVICES - During the formation of complex metallization systems, a conductive cap layer may be formed on a copper-containing metal region in order to enhance the electromigration behavior without negatively affecting the overall conductivity. At the same time, a thermo chemical treatment may be performed to provide superior surface conditions of the sensitive dielectric material and also to suppress carbon depletion, which may conventionally result in a significant variability of material characteristics of sensitive ULK materials. | 09-02-2010 |
20100289125 | ENHANCED ELECTROMIGRATION PERFORMANCE OF COPPER LINES IN METALLIZATION SYSTEMS OF SEMICONDUCTOR DEVICES BY SURFACE ALLOYING - In sophisticated semiconductor devices, the electromigration performance of copper metal lines at the top interface thereof may be enhanced by forming a copper alloy that is locally restricted to the interface. To this end, an appropriate alloy-forming species, such as aluminum, may be provided on the basis of a non-masked deposition process and may be subsequently removed by a non-masked etch process, wherein the characteristic of the resulting alloy may be adjusted during an intermediate heat treatment. | 11-18-2010 |
20110156270 | CONTACT ELEMENTS OF SEMICONDUCTOR DEVICES FORMED ON THE BASIS OF A PARTIALLY APPLIED ACTIVATION LAYER - When forming contact levels of sophisticated semiconductor devices, a superior bottom to top fill behavior may be accomplished by applying an activation material selectively in the lower part of the contact openings and using a selective deposition technique. Consequently, deposition-related irregularities, such as voids, may be efficiently suppressed even for high aspect ratio contact openings. | 06-30-2011 |
20110244679 | Contact Elements of a Semiconductor Device Formed by Electroless Plating and Excess Material Removal with Reduced Sheer Forces - Contact elements in the contact level of a semiconductor device may be formed on the basis of a selective deposition technique, such as electroless plating, wherein an efficient planarization of the contact level is achieved without subjecting the contact elements to undue mechanical stress. In some illustrative embodiments, an overfilling of the contact openings may be reliably avoided and the planarization of the surface topography is accomplished on the basis of a non-critical polishing process. In other cases, electrochemical etch techniques are applied in combination with a conductive sacrificial current distribution layer in order to remove any excess material of the contact elements without inducing undue mechanical stress. | 10-06-2011 |
20130237057 | CONTACT ELEMENTS OF A SEMICONDUCTOR DEVICE FORMED BY ELECTROLESS PLATING AND EXCESS MATERIAL REMOVAL WITH REDUCED SHEER FORCES - The present disclosure is directed to, among other things, an illustrative method that includes forming an opening in a dielectric material of a contact level of a semiconductor device, and selectively depositing a conductive material in the opening to form a contact element therein, the contact element extending to a contact area of a circuit element and having a laterally restricted excess portion formed outside of the opening and above the dielectric material. The disclosed method further includes forming a sacrificial material layer above the dielectric material and the contact element, the sacrificial material layer surrounding the laterally restricted excess portion. Additionally, the method includes planarizing a surface topography of the contact level in the presence of the sacrificial material so as to remove the laterally restricted excess portion from above the dielectric material. | 09-12-2013 |
20140239503 | INTEGRATED CIRCUITS AND METHODS FOR FABRICATING INTEGRATED CIRCUITS WITH CAPPING LAYERS BETWEEN METAL CONTACTS AND INTERCONNECTS - Integrated circuits and methods for fabricating integrated circuits are provided. In an exemplary embodiment, a method for fabricating integrated circuits includes forming a metal contact structure that is electrically connected to a device. A capping layer is selectively formed on the metal contact structure, and an interlayer dielectric material is deposited over the capping layer. A metal hard mask is deposited and patterned over the interlayer dielectric material to define an exposed region of the interlayer dielectric material. The method etches the exposed region of the interlayer dielectric material to expose at least a portion of the capping layer. The method includes removing the metal hard mask with an etchant while the capping layer physically separates the metal contact structure from the etchant. A metal is deposited to form a conductive via electrically connected to the metal contact structure through the capping layer. | 08-28-2014 |