Abstract: Provided are novel methods of filling gaps with a flowable dielectric material. According to various embodiments, the methods involve performing a surface treatment on the gap to enhance subsequent bottom up fill of the gap. In certain embodiments, the treatment involves exposing the surface to activated species, such as activated species of one or more of nitrogen, oxygen, and hydrogen. In certain embodiments, the treatment involves exposing the surface to a plasma generated from a mixture of nitrogen and oxygen. The treatment may enable uniform nucleation of the flowable dielectric film, reduce nucleation delay, increase deposition rate and enhance feature-to-feature fill height uniformity.

Abstract: Methods of forming low resistivity tungsten films with good uniformity and good adhesion to the underlying layer are provided. The methods involve forming a tungsten nucleation layer using a pulsed nucleation layer process at low temperature and then treating the deposited nucleation layer prior to depositing the bulk tungsten fill. The treatment operation lowers resistivity of the deposited tungsten film. In certain embodiments, the depositing the nucleation layer involves a boron-based chemistry in the absence of hydrogen. Also in certain embodiments, the treatment operations involve exposing the nucleation layer to alternating cycles of a reducing agent and a tungsten-containing precursor. The methods are useful for depositing films in high aspect ratio and/or narrow features. The films exhibit low resistivity at narrow line widths and excellent step coverage.

Abstract: Methods of forming low resistivity tungsten films with good uniformity and good adhesion to the underlying layer are provided. The methods involve forming a tungsten nucleation layer using a pulsed nucleation layer process at low temperature and then treating the deposited nucleation layer prior to depositing the bulk tungsten fill. The treatment operation lowers resistivity of the deposited tungsten film. In certain embodiments, the depositing the nucleation layer involves a boron-based chemistry in the absence of hydrogen. Also in certain embodiments, the treatment operations involve exposing the nucleation layer to alternating cycles of a reducing agent and a tungsten-containing precursor. The methods are useful for depositing films in high aspect ratio and/or narrow features. The films exhibit low resistivity at narrow line widths and excellent step coverage.

Abstract: Methods of forming low resistivity tungsten films with good uniformity and good adhesion to the underlying layer are provided. The methods involve forming a tungsten nucleation layer using a pulsed nucleation layer process at low temperature and then treating the deposited nucleation layer prior to depositing the bulk tungsten fill. The treatment operation lowers resistivity of the deposited tungsten film. In certain embodiments, the depositing the nucleation layer involves a boron-based chemistry in the absence of hydrogen. Also in certain embodiments, the treatment operations involve exposing the nucleation layer to alternating cycles of a reducing agent and a tungsten-containing precursor. The methods are useful for depositing films in high aspect ratio and/or narrow features. The films exhibit low resistivity at narrow line widths and excellent step coverage.

Abstract: A structure is formed in an integrated circuit to provide for the coupling of elements in the integrated circuit. The structure extends from a conductive surface through a channel extending above the conductive surface. The structure includes a layer of a refractory metal, a layer of a metal nitride, and a layer of a metal. The layer of the refractory metal is deposited on the conductive surface and inner walls of the channel. The layer of the metal nitride is formed on the layer of the refractory metal. The layer of the metal nitride has a thickness extending from the layer of the refractory metal of less than 130 Å. The layer of the metal is deposited on the layer of the metal nitride.

Abstract: The construction of a film on a wafer, which is placed in a processing chamber, may be carried out through the following steps. A layer of material is formed on the wafer, while the wafer is in the processing chamber. Next, the layer of material is oxidized, while the wafer is in the processing chamber. A semiconductor wafer processing chamber for carrying out such a construction in-situ may include a processing chamber, a showerhead, a wafer support and a rf signal means. The showerhead supplies gases into the processing chamber, while the wafer support supports a wafer in the processing chamber. The rf signal means is coupled to the showerhead and the wafer support for providing a first rf signal to the showerhead and a second rf signal to the wafer support.

Abstract: A pressure controlled activating switch for a hand held tool comprises an elongated flexible barrel having an axial support member carried within the barrel and protruding from one end thereof. A plurality of gliding elements surround the axial support member and are mounted in the barrel for axial movement with respect to the barrel axis. A plurality of inserting elements are carried between the gliding elements and are moveable radially in the barrel. A connecting element is provided axially moveable within the barrel and is operatively disposed to activate a switch element. A spring or magnet maintains the gliding elements in a resting position and positioned with respect to the connecting element so that radial movement inwardly of the flexible barrel causes radial movement of the inserting elements which in turn causes axial movement of the gliding elements and connecting element to activate the switch element.