Abstract: A PCM cell structure comprises a first electrode, a phase change element, and a second electrode, wherein the phase change element is inserted in between the first electrode and the second electrode and only the peripheral edge of the first electrode contacts the phase change element thereby reducing the contact area between the phase change element and the first electrode and thereby increasing the current density through the phase change element and effectively inducing the phase change at lower levels of current and reduced programming power.

Abstract: A PCM cell structure comprises a first electrode, a phase change element, and a second electrode, wherein the phase change element is inserted in between the first electrode and the second electrode and only the peripheral edge of the first electrode contacts the phase change element thereby reducing the contact area between the phase change element and the first electrode and thereby increasing the current density through the phase change element and effectively inducing the phase change at lower levels of current and reduced programming power.

Abstract: A dual damascene process capable of reliably producing aluminum interconnects that exhibit improved electromigration characteristics over aluminum interconnects produced by conventional RIE techniques. In particular, the dual damascene process relies on a PVD-Ti/CVD-TiN barrier layer to produce aluminum lines that exhibit significantly reduced saturation resistance levels and/or suppressed electromigration, particularly in lines longer than 100 micrometers. The electromigration lifetime of the dual damascene aluminum line is strongly dependent on the materials and material fill process conditions. Significantly, deviations in materials and processing can result in electromigration lifetimes inferior to that achieved with aluminum RIE interconnects. In one example, current densities as high as 2.5 MA/cm2 are necessary to induce a statistically relevant number of fails due to electromigration.

Abstract: A gate structure for a semiconductor device, and particularly a MOSFET for such applications as CMOS technology. The gate structure entails an electrical insulating layer on a semiconductor substrate, over which a polysilicon gate electrode is formed. The gate structure further includes a gate conductor that is electrically connected with the gate electrode through a diffusion barrier layer having semi-insulating properties. The composition and thickness of the diffusion barrier layer are tailored so that the barrier layer is effective to block diffusion and intermixing between the gate conductor and polysilicon gate electrode, yet provides sufficient capacitive coupling and/or current leakage so as not to significantly increase the gate propagation delay of the gate structure.

Abstract: Low resistivity titanium silicide, and semiconductor devices incorporating the same, may be formed by titanium alloy comprising titanium and 1-20 atomic percent refractory metal deposited in a layer overlying a silicon substrate, the substrate is then heated to a temperature sufficient to substantially form C54 phase titanium silicide. The titanium alloy may further comprise silicon and the refractory metal may be Mo, W, Ta, Nb, V, or Cr, and more preferably is Ta or Nb. The heating step used to form the low resistivity titanium silicide is performed at a temperature less than 900° C., and more preferably between about 600-700° C.

Abstract: A device having a thin film and/or a solder ball formed on a substrate. The thin film and the solder ball each include a metal and a compound that includes an oxide, nitride, or carbide precipitate of an expandable element or a contractible element. The compound is distributed in the metal to control the tensile and compressive stresses and mechanical properties of the thin film and the solder ball.

Abstract: A method for forming thin films and controlling the tensile and compressive stresses and mechanical properties of the thin film. The method includes forming an alloy on a substrate having a solvent metal and a solute, then annealing the substrate and the alloy in one of an oxidizing, nitriding and carborizing ambient so that the ambient reacts with the solute to form respectively one of an oxide, nitride and carbide precipitates of the solute in the solvent. The solute is selected so that the precipitates formed may be used to control the mechanical properties of the solvent.

Abstract: Low resistivity titanium silicide, and semiconductor devices incorporating the same, may be formed by titanium alloy comprising titanium and 1-20 atomic percent refractory metal deposited in a layer overlying a silicon substrate, the substrate is then heated to a temperature sufficient to substantially form C54 phase titanium silicide. The titanium alloy may further comprise silicon and the refractory metal may be Mo, W, Ta, Nb, V, or Cr, and more preferably is Ta or Nb. The heating step used to form the low resistivity titanium silicide is performed at a temperature less than 900.degree. C., and more preferably between about 600.degree.-700.degree. C.