Patent application number | Description | Published |
20130143401 | METAL AND SILICON CONTAINING CAPPING LAYERS FOR INTERCONNECTS - Disclosed methods cap exposed surfaces of copper lines with a layer of metal or metal-containing compound combined with silicon. In some cases, the metal or metal-containing compound forms an atomic layer. In certain embodiments, the methods involve exposing the copper surface first to a metal containing precursor to form an atomic layer of adsorbed precursor or metal atoms, which may optionally be converted to an oxide, nitride, carbide, or the like by, e.g., a pinning treatment. Subsequent exposure to a silicon-containing precursor may proceed with or without metallic atoms being converted. | 06-06-2013 |
20140216336 | METAL AND SILICON CONTAINING CAPPING LAYERS FOR INTERCONNECTS - Disclosed methods cap exposed surfaces of copper lines with a layer of metal or metal-containing compound combined with silicon. In some cases, the metal or metal-containing compound forms an atomic layer. In certain embodiments, the methods involve exposing the copper surface first to a metal containing precursor to form an atomic layer of adsorbed precursor or metal atoms, which may optionally be converted to an oxide, nitride, carbide, or the like by, e.g., a pinning treatment. Subsequent exposure to a silicon-containing precursor may proceed with or without metallic atoms being converted. | 08-07-2014 |
20140217193 | METHOD AND APPARATUS FOR PURGING AND PLASMA SUPPRESSION IN A PROCESS CHAMBER - A substrate processing system includes a showerhead that comprises a head portion and a stem portion and that delivers precursor gas to a processing chamber. A baffle includes a base portion having an outer diameter that is greater than an outer diameter of the head portion of the showerhead, that comprises a dielectric material and that is arranged between the head portion of the showerhead and an upper surface of the processing chamber. | 08-07-2014 |
20150221542 | METHODS AND APPARATUS FOR SELECTIVE DEPOSITION OF COBALT IN SEMICONDUCTOR PROCESSING - Methods and apparatus for selective deposition of cobalt on copper lines in the presence of exposed dielectric in semiconductor processing are provided. Cobalt in its metallic form is selectively deposited onto copper in the presence of dielectric by contacting a prepared surface of the substrate with an organometallic cobalt compound in a presence of a reducing agent. Surface preparation involves H | 08-06-2015 |
20150235835 | HIGH GROWTH RATE PROCESS FOR CONFORMAL ALUMINUM NITRIDE - Methods of depositing conformal aluminum nitride films on semiconductor substrates are provided. Disclosed methods involve (a) exposing a substrate to an aluminum-containing precursor, (b) purging the aluminum-containing precursor for a duration insufficient to remove substantially all of the aluminum-containing precursor in gas phase, (c) exposing the substrate to a nitrogen-containing precursor to form aluminum nitride, (d) purging the nitrogen-containing precursor, and (e) repeating (a) through (d). Increased growth rate and 100% step coverage and conformality are attained. | 08-20-2015 |
20150380272 | LINER AND BARRIER APPLICATIONS FOR SUBTRACTIVE METAL INTEGRATION - Methods and techniques for fabricating metal interconnects, lines, or vias by subtractive etching and liner deposition methods are provided. Methods involve depositing a blanket copper layer, removing regions of the blanket copper layer to form a pattern, treating the patterned metal, depositing a copper-dielectric interface material such that the copper-dielectric interface material adheres only to the patterned copper, depositing a dielectric barrier layer on the substrate, and depositing a dielectric bulk layer on the substrate. | 12-31-2015 |
20150380302 | SELECTIVE FORMATION OF DIELECTRIC BARRIERS FOR METAL INTERCONNECTS IN SEMICONDUCTOR DEVICES - A dielectric diffusion barrier is deposited on a substrate that has a via and an overlying trench etched into an exposed layer of inter-layer dielectric, wherein there is exposed metal from the underlying interconnect at the bottom of the via. In order to provide a conductive path from the underlying metallization layer to the metallization layer that is being formed over it, the dielectric diffusion barrier is formed selectively on the inter-layer dielectric and not on the exposed metal at the bottom of the via. In one example a dielectric SiNC diffusion barrier layer is selectively deposited on the inter-layer dielectric using a remote plasma deposition and a precursor that contains both silicon and nitrogen atoms. Generally, a variety of dielectric diffusion barrier materials with dielectric constants of between about 3.0-20.0 can be selectively formed on inter-layer dielectric. | 12-31-2015 |
20160064211 | HIGH GROWTH RATE PROCESS FOR CONFORMAL ALUMINUM NITRIDE - Methods of depositing conformal aluminum nitride films on semiconductor substrates are provided. Disclosed methods involve (a) exposing a substrate to an aluminum-containing precursor, (b) purging the aluminum-containing precursor for a duration insufficient to remove substantially all of the aluminum-containing precursor in gas phase, (c) exposing the substrate to a nitrogen-containing precursor to form aluminum nitride, (d) purging the nitrogen-containing precursor, and (e) repeating (a) through (d). Increased growth rate and 100% step coverage and conformality are attained. | 03-03-2016 |
20160071953 | SACRIFICIAL PRE-METAL DIELECTRIC FOR SELF-ALIGNED CONTACT SCHEME - Various embodiments herein relate to formation of contact etch stop layers in the context of forming gates and contacts. In certain embodiments, a novel process flow is used, which may involve the deposition and removal of a sacrificial pre-metal dielectric material before a particular contact etch stop layer is formed. An auxiliary contact etch stop layer may be used in addition to a primary etch stop layer that is deposited previously. In certain cases the contact etch stop layer is a metal-containing material such as a nitride or an oxide. The contact etch stop layer may be deposited through a cyclic vapor deposition in some embodiments. The process flows disclosed herein provide improved protection against over-etching gate stacks, thereby minimizing gate-to-contact leakage. Further, the disclosed process flows result in wider flexibility in terms of materials and deposition conditions used for forming various dielectric materials, thereby minimizing parasitic capacitance. | 03-10-2016 |