Methods and apparatus are provided. A first dielectric plug is formed in a portion of a trench that extends into a substrate of a memory device so that an upper surface of the first dielectric plug is recessed below an upper surface of the substrate. The first dielectric plug has a layer of a first dielectric material and a layer of a second dielectric material formed on the layer of the first dielectric material. A second dielectric plug of a third dielectric material is formed on the upper surface of the first dielectric plug.

The invention includes methods in which oxide is formed within openings in a three-step process. A first step is deposition of oxide under a pressure of greater than 15 mTorr. A second step is removal of a portion of the oxide with an etch. A third step is an oxide deposition under a pressure of less than or equal to 10 mTorr. Methodology of the present invention can be utilized for forming trenched isolation regions, such as, for example, shallow trench isolation regions.

A semiconductor structure and a related method for fabrication thereof include an isolation region located within an isolation trench within a semiconductor substrate. The isolation region comprises; (1) a lower lying dielectric plug layer recessed within the isolation trench; (2) a U shaped dielectric liner layer located upon the lower lying dielectric plug layer and partially filling the recess; and (3) an upper lying dielectric plug layer located upon the U shaped dielectric liner layer and completely filling the recess. The isolation region provides for sidewall coverage of the isolation trench, thus eliminating some types of leakage paths.

The invention includes an electrically conductive line, methods of forming electrically conductive lines, and methods of reducing titanium silicide agglomeration in the fabrication of titanium silicide over polysilicon transistor gate lines. In one implementation, a method of forming an electrically conductive line includes providing a silicon-comprising layer over a substrate. An electrically conductive layer is formed over the silicon-comprising layer. An MSi.sub.xN.sub.y-comprising layer is formed over the electrically conductive layer, where "x" is from 0 to 3.0, "y" is from 0.5 to 10, and "M" is at least one of Ta, Hf, Mo, and W. An MSi.sub.z-comprising layer is formed over the MSi.sub.xN.sub.y-comprising layer, where "z" is from 1 to 3.0. A TiSi.sub.a-comprising layer is formed over the MSi.sub.z-comprising layer, where "a" is from 1 to 3.0. The silicon-comprising layer, the electrically conductive layer, the MSi.sub.xN.sub.y-comprising layer, the MSi.sub.z-comprising layer, and the TiSi.sub.a-comprising layer are patterned into a stack comprising an electrically conductive line. Other aspects and implementations are contemplated.

This invention includes methods of depositing a silicon dioxide comprising layer in the fabrication of integrated circuitry, and to methods of forming trench isolation in the fabrication of integrated circuitry. In one implementation, a method of depositing a silicon dioxide comprising layer in the fabrication of integrated circuitry includes flowing an aluminum containing organic precursor to a chamber containing a semiconductor substrate effective to deposit an aluminum comprising layer over the substrate. An alkoxysilanol is flowed to the substrate comprising the aluminum comprising layer within the chamber effective to deposit a silicon dioxide comprising layer over the substrate. At least one halogen is provided within the chamber during at least one of the aluminum containing organic precursor flowing and the alkoxysilanol flowing under conditions effective to reduce rate of the deposit of the silicon dioxide comprising layer over the substrate than would otherwise occur under identical conditions but for providing the halogen. Other implementations are contemplated.