Abstract: A contact structure is provided incorporating an amorphous titanium nitride barrier layer formed via low-pressure chemical vapor deposition (LPCVD) utilizing tetrakis-dialkylamido-titanium, Ti(NMe2)4, as the precursor. The contact structure is fabricated by etching a contact opening through a dielectric layer down to a diffusion region to which electrical contact is to be made. Titanium metal is deposited over the surface of the wafer so that the exposed surface of the diffusion region is completely covered by a layer of the metal. At least a portion of the titanium metal layer is eventually converted to titanium silicide, thus providing an excellent conductive interface at the surface of the diffusion region. A titanium nitride barrier layer is then deposited using the LPCVD process, coating the walls and floor of the contact opening. Chemical vapor deposition of polycrystalline silicon or of a metal follows.

Abstract: An improved semiconductor device fabrication method comprises insertion of a semiconductor wafer into a high-pressure heated chamber and deposition of a low melting-point aluminum material into a contact hole or via and over an insulating layer overlying a substrate of the wafer. The wafer is heated up to the melting point of the aluminum material and the chamber is pressurized to force the aluminum material into the contact holes or vias and eliminate voids present therein. A second layer of material, comprising a different metal or alloy, which is used as a dopant source, is deposited over an outer surface of the deposited aluminum material layer and allowed to diffuse into the aluminum material layer in order to form a homogenous aluminum alloy within the contact hole or via. A semiconductor device structure made according to the method is also disclosed.

Abstract: A contact structure is provided incorporating an amorphous titanium nitride barrier layer formed via low-pressure chemical vapor deposition (LPCVD) utilizing tetrakis-dialkylamido-titanium, Ti(NMe2)4, as the precursor. The contact structure is fabricated by etching a contact opening through a dielectric layer down to a diffusion region to which electrical contact is to be made. Titanium metal is deposited over the surface of the wafer so that the exposed surface of the diffusion region is completely covered by a layer of the metal. At least a portion of the titanium metal layer is eventually converted to titanium silicide, thus providing an excellent conductive interface at the surface of the diffusion region. A titanium nitride barrier layer is then deposited using the LPCVD process, coating the walls and floor of the contact opening. Chemical vapor deposition of polycrystalline silicon or of a metal follows.

Abstract: An ovonic phase-change semiconductor memory device having a reduced area of contact between electrodes of chalcogenide memories, and methods of forming the same, are disclosed. Such memory devices are formed by forming a tip protruding from a lower surface of a lower electrode element. An insulative material is applied over the lower electrode such that an upper surface of the tip is exposed. A chalcogenide material and an upper electrode are either formed atop the tip, or the tip is etched into the insulative material and the chalcogenide material and upper electrode are deposited within the recess. This allows the memory cells to be made smaller and allows the overall power requirements for the memory cell to be minimized.

Abstract: The present invention is related to methods and apparatus that allow a chalcogenide glass such as germanium selenide (GexSe1-x) to be doped with a metal such as silver, copper, or zinc without utilizing an ultraviolet (UV) photodoping step to dope the chalcogenide glass with the metal. The chalcogenide glass doped with the metal can be used to store data in a memory device. Advantageously, the systems and methods co-sputter the metal and the chalcogenide glass and allow for relatively precise and efficient control of a constituent ratio between the doping metal and the chalcogenide glass. Further advantageously, the systems and methods enable the doping of the chalcogenide glass with a relatively high degree of uniformity over the depth of the formed layer of chalcogenide glass and the metal. Also, the systems and methods allow a metal concentration to be varied in a controlled manner along the thin film depth.

Abstract: A method of forming minimally spaced apart MRAM structures is disclosed. A photolithography technique is employed to define patterns an integrated circuit, the width of which is further reduced by etching to allow formation of patterns used to etch digit line regions with optimum critical dimension between any of the two digit line regions. Subsequent pinned and sense layers of MRAM structures are formed over the minimally spaced digit regions.

Abstract: A contact structure is provided incorporating an amorphous titanium nitride barrier layer formed via low-pressure chemical vapor deposition (LPCVD) utilizing tetrakis-dialkylamido-titanium, Ti(NMe2)4, as the precursor. The contact structure is fabricated by etching a contact opening through a dielectric layer down to a diffusion region to which electrical contact is to be made. Titanium metal is deposited over the surface of the wafer so that the exposed surface of the diffusion region is completely covered by a layer of the metal. At least a portion of the titanium metal layer is eventually converted to titanium silicide, thus providing an excellent conductive interface at the surface of the diffusion region. A titanium nitride barrier layer is then deposited using the LPCVD process, coating the walls and floor of the contact opening. Chemical vapor deposition of polycrystalline silicon or of a metal follows.

Abstract: Various aspects of the invention provide methods of manufacturing probe cards and test systems which may test microelectronic components using such probe cards. In one specific example, a probe card may be manufactured by forming a plurality of blind holes in a substrate, with each hole having a closed bottom spaced from a back of the substrate by a back thickness. An electrically conductive metal may be deposited on the substrate to fill the holes and define an overburden on the substrate. The metal in each hole may define a conductor. At least a portion of the overburden may be removed to electrically isolate each of the conductors from one another. A portion of the substrate including the back thickness is removed to define an array of pins extending outwardly from a remaining thickness of the substrate, with each pin being an exposed length of one of the conductors.

Abstract: An apparatus and method for attaching a semiconductor die to a lead frame wherein the electric contact points of the semiconductor die are relocated to the periphery of the semiconductor die through a plurality of conductive traces. A plurality of leads extends from the lead frame over the conductive traces proximate the semiconductor die periphery and directly attaches to and makes electrical contact with the conductive traces in a LOC arrangement. Alternately, a connector may contact a portion of the conductive trace to make contact therewith.

Abstract: A contact structure is provided incorporating an amorphous titanium nitride barrier layer formed via low-pressure chemical vapor deposition (LPCVD) utilizing tetrakis-dialkylamido-titanium, Ti(NMe2)4, as the precursor. The contact structure is fabricated by etching a contact opening through a dielectric layer down to a diffusion region to which electrical contact is to be made. Titanium metal is deposited over the surface of the wafer so that the exposed surface of the diffusion region is completely covered by a layer of the metal. At least a portion of the titanium metal layer is eventually converted to titanium silicide, thus providing an excellent conductive interface at the surface of the diffusion region. A titanium nitride barrier layer is then deposited using the LPCVD process, coating the walls and floor of the contact opening. Chemical vapor deposition of polycrystalline silicon or of a metal follows.

Abstract: An inventive process is disclosed for creating a barrier layer on a silicon substrate of an in-process integrated circuit. The process uses MOCVD to form a metal oxide film. The source gas is preferably an organometallic compound. Ozone is used as an oxidizing agent in order to react with the source gas at a low temperature and fully volatilize carbon from the source gas. The high reactivity of ozone at a low temperature provides a more uniform step coverage on contact openings. The process is used to create etch stop layers and diffusion barriers.

Abstract: A removable memory card and an associated read/write device and its method of operation are disclosed. The memory card may be formed of a sheet of chalcogenide glass material which has memory storage locations therein defined by the locations of conductive read/write elements of the read/write device.

Abstract: A method for depositing a rough polysilicon film on a substrate is disclosed. The method includes introducing the reactant gases argon and silane into a deposition chamber and enabling and disabling a plasma at various times during the deposition process.

Abstract: A die contacting substrate establishes ohmic contact with the die by means of raised portions on contact members. The raised portions are dimensioned so that a compression force applied to the die against the substrate results in a limited penetration of the contact member into the bondpads. The arrangement may be used for establishing electrical contact with a burn-in oven and with a discrete die tester. This permits the die to be characterized prior to assembly, so that the die may then be transferred in an unpackaged form. A Z-axis anisotropic conductive interconnect material may be interposed between the die attachment surface and the die.

Abstract: An ovonic phase-change semiconductor memory device having a reduced area of contact between electrodes of chalcogenide memories, and methods of forming the same. Such memory devices are formed by forming a tip protruding from a lower surface of a lower electrode element. An insulative material is applied over the lower electrode such that an upper surface of the tip is exposed. A chalcogenide material and an upper electrode are either formed atop the tip, or the tip is etched into the insulative material and the chalcogenide material and upper electrode are deposited within the recess. This allows the memory cells to be made smaller and allows the overall power requirements for the memory cell to be minimized.

Abstract: The present invention is related to methods and apparatus that allow a chalcogenide glass such as germanium selenide (GexSe1-x) to be doped with a metal such as silver, copper, or zinc without utilizing an ultraviolet (UV) photodoping step to dope the chalcogenide glass with the metal. The chalcogenide glass doped with the metal can be used to store data in a memory device. Advantageously, the systems and methods co-sputter the metal and the chalcogenide glass and allow for relatively precise and efficient control of a constituent ratio between the doping metal and the chalcogenide glass. Further advantageously, the systems and methods enable the doping of the chalcogenide glass with a relatively high degree of uniformity over the depth of the formed layer of chalcogenide glass and the metal. Also, the systems and methods allow a metal concentration to be varied in a controlled manner along the thin film depth.

Abstract: A method of manufacturing semiconductor devices using an improved chemical mechanical planarization process for the planarization of the surfaces of the wafer on which the semiconductor devices are formed. The improved chemical mechanical planarization process includes the formation of a flat planar surface from a deformable coating on the surface of the wafer filling in between the surface irregularities prior to the planarization of the surface through a chemical mechanical planarization process.

Abstract: A method of forming minimally spaced apart MRAM structures is disclosed. A photolithography technique is employed to define patterns an integrated circuit, the width of which is further reduced by etching to allow formation of patterns used to etch digit line regions with optimum critical dimension between any of the two digit line regions. Subsequent pinned and sense layers of MRAM structures are formed over the minimally spaced digit regions.

Abstract: A method is disclosed for reducing the effects of buckling, also referred to as cracking or wrinkling in multilayer heterostructures. The present method involves forming a planarization layer superjacent a semiconductor substrate. A barrier film having a structural integrity is formed superjacent the planarization layer. A second layer is formed superjacent the barrier film. The substrate is heated sufficiently to cause the planarization layer to expand according to a first thermal coefficient of expansion, the second layer to expand according to a second thermal coefficient of expansion, and the structural integrity of the barrier film to be maintained. This results in the barrier film isolating the planarization layer from the second layer, thereby preventing the planarization layer and the second layer from interacting during the heating step.

Abstract: A method for dispensing a chemical, such as an edge bead removal solvent, onto a semiconductor wafer comprising the steps of dispensing the chemical selectively onto the wafer and applying a suction to the area immediately surrounding the location at which the chemical is dispensed onto the wafer. Preferably, the suction is applied substantially simultaneously with the dispensing of the chemical. One specific version of the invention provides an edge bead removal system wherein suction is applied to the area immediately surrounding the solvent dispensing nozzle to remove dissolved coating material and excess solvent from the wafer. In one aspect of this system, an apparatus for removing the edge bead includes a mechanism for dispensing a solvent selectively onto the edge of the wafer, and a mechanism surrounding the dispensing mechanism for vacuuming excess solvent and dissolved coating material from the edge of the wafer.