Abstract: A method and apparatus for modifying the profile of narrow, high-aspect-ratio gaps on a semiconductor substrate are used to fill the gaps in a void-free manner. Differential heating characteristics of a substrate in a high-density plasma chemical vapor deposition (HDP-CVD) system helps to prevent the gaps from being pinched off before they are filled. The power distribution between coils forming the plasma varies the angular dependence of the sputter etch component of the plasma, and thus may be used to modify the gap profile, independently or in conjunction with differential heating. A heat source may be applied to the backside of a substrate during the concurrent deposition/etch process to further enhance the profile modification characteristics of differential heating.

Abstract: A method and apparatus for modifying the profile of narrow, high-aspect-ratio gaps on a semiconductor substrate are used to fill the gaps in a void-free manner. Differential heating characteristics of a substrate in a high-density plasma chemical vapor deposition (HDP-CVD) system helps to prevent the gaps from being pinched off before they are filled. The power distribution between coils forming the plasma varies the angular dependence of the sputter etch component of the plasma, and thus may be used to modify the gap profile, independently or in conjunction with differential heating. A heat source may be applied to the backside of a substrate during the concurrent deposition/etch process to further enhance the profile modification characteristics of differential heating.

Abstract: Provided is a method of integrating Ta2O5 into an MIS stack capacitor for a semiconductor device by forming a thin SiON layer at the Si/TaO interface using low temperature remote plasma oxidation anneal. Also provided is a method of forming an MIS stack capacitor with improved electrical performance by treating SiO2 with remote plasma nitridation or SiN layer with rapid thermal oxidation or RPO to form a SiON layer prior to Ta2O5 deposition with TAT-DMAE, TAETO or any other Ta-containing precursor.

Abstract: Processes which use the same precursor material for forming a metal electrode deposition as for forming a dielectric layer deposition. The layers may be successively formed in the same chamber, or may be formed in like chambers located in a processing system.

Abstract: The present invention describes a method of processing a substrate. According to the present invention a dielectric layer is formed on the substrate. The dielectric layer is then exposed in a first chamber to activated nitrogen atoms formed in a second chamber to form a nitrogen passivated dielectric layer. A metal nitride film is then formed on the nitrogen passivated dielectric layer.

Abstract: The formation of a barrier layer over a high k dielectric layer and deposition of a conducting layer over the barrier layer prevents intermigration between the species of the high k dielectric layer and the conducting layer and prevents oxygen scavenging of the high k dielectric layer. One example of a capacitor stack device provided includes a high k dielectric layer of Ta2O5, a barrier layer of TaON or TiON formed at least in part by a remote plasma process, and a top electrode of TiN. The processes may be conducted at about 300 to 700° C. and are thus useful for low thermal budget applications. Also provided are MIM capacitor constructions and methods in which an insulator layer is formed by remote plasma oxidation of a bottom electrode.

Abstract: The present invention provides a means for obtaining dielectric thin films on a substrate, e.g., silicon, by 1) low temperature (500° C. or less) deposition of a dielectric material onto a surface, followed by 2) high temperature post-deposition annealing. The deposition can take place in an oxidative environment, followed by annealing, or alternatively the deposition can take place in a non-oxidative environment (e.g., N2), followed by oxidation and annealing.

Abstract: A method of providing a stable interface between a metallic layer and a dielectric layer in a semiconductor device is provided. The method includes generating a remote nitrogen containing plasma and flowing activated nitrogen species, from the remote site to the location of the metallic layer. The activated nitrogen species are flowed over at least the surface of the metallic layer, where they react with the metallic surface to form a metal nitride. The treated layer can be used to provide a stable bottom electrode in a capacitor stack formation.

Abstract: Processes which use the same precursor material for forming a metal electrode deposition as for forming a dielectric layer deposition. The layers may be successively formed in the same chamber, or may be formed in like chambers located in a processing system.

Abstract: The present invention describes a method of processing a substrate. According to the present invention a dielectric layer is formed on the substrate. The dielectric layer is then exposed in a first chamber to activated nitrogen atoms formed in a second chamber to form a nitrogen passivated dielectric layer. A metal nitride film is then formed on the nitrogen passivated dielectric layer.

Abstract: The present invention describes a method of processing a substrate. According to the present invention a dielectric layer is formed on the substrate. The dielectric layer is then exposed in a first chamber to activated nitrogen atoms formed in a second chamber to form a nitrogen passivated dielectric layer. A metal nitride film is then formed on the nitrogen passivated dielectric layer.

Abstract: A method and apparatus for modifying the profile of narrow, high-aspect-ratio gaps on a semiconductor substrate are used to fill the gaps in a void-free manner. Differential heating characteristics of a substrate in a high-density plasma chemical vapor deposition (HDP-CVD) system helps to prevent the gaps from being pinched off before they are filled. The power distribution between coils forming the plasma varies the angular dependence of the sputter etch component of the plasma, and thus may be used to modify the gap profile, independently or in conjunction with differential heating. A heat source may be applied to the backside of a substrate during the concurrent deposition/etch process to further enhance the profile modification characteristics of differential heating.

Abstract: A sequence of process steps forms a fluorinated silicon glass (FSG) layer on a substrate. This layer is much less likely to form a haze or bubbles in the layer, and is less likely to desorb water vapor during subsequent processing steps than other FSG layers. An undoped silicon glass (USG) liner protects the substrate from corrosive attack. The USG liner and FSG layers are deposited on a relatively hot wafer surface and can fill trenches on the substrate as narrow as 0.8 &mgr;m with an aspect ratio of up to 4.5:1.

Abstract: A method and apparatus for modifying the profile of narrow, high-aspect-ratio gaps on a semiconductor substrate are used to fill the gaps in a void-free manner. Differential heating characteristics of a substrate in a high-density plasma chemical vapor deposition (HDP-CVD) system helps to prevent the gaps from being pinched off before they are filled. The power distribution between coils forming the plasma varies the angular dependence of the sputter etch component of the plasma, and thus may be used to modify the gap profile, independently or in conjunction with differential heating. A heat source may be applied to the backside of a substrate during the concurrent deposition/etch process to further enhance the profile modification characteristics of differential heating.

Abstract: An insulating film with a low dielectric constant is more quickly formed on a substrate by reducing the co-etch rate as the film is deposited. The process gas is formed into a plasma from silicon-containing and fluorine-containing gases. The plasma is biased with an RF field to enhance deposition of the film. Deposition and etching occur simultaneously. The relative rate of deposition to etching is increased in the latter portion of the deposition process by decreasing the bias RF power, which decreases the surface temperature of the substrate and decreases sputtering and etching activities. Processing time is reduced compared to processes with fixed RF power levels. Film stability, retention of water by the film, and corrosion of structures on the substrate are all improved. The film has a relatively uniform and low dielectric constant and may fill trenches with aspect ratios of at least 4:1 and gaps less than 0.5 .mu.m.

Abstract: A layer of reduced stress is formed on a substrate using an HDP-CVD system by delaying or interrupting the application of capacitively coupled RF energy. The layer is formed by introducing a process gas into the HDP system chamber and forming a plasma from the process gas by the application of RF power to an inductive coil. After a selected period, a second layer of the film is deposited by maintaining the inductively-coupled plasma and biasing the plasma toward the substrate to enhance the sputtering effect of the plasma. In a preferred embodiment, the deposited film is a silicon oxide film, and biasing is performed by application of capacitively coupled RF power from RF generators to a ceiling plate electrode and wafer support electrode.

Abstract: A sequence of process steps forms a fluorinated silicon glass (FSG) layer on a substrate. This layer is much less likely to form a haze or bubbles in the layer, and is less likely to desorb water vapor during subsequent processing steps than other FSG layers. An undoped silicon glass (USG) liner protects the substrate from corrosive attack. The USG liner and FSG layers are deposited on a relatively hot wafer surface and can fill trenches on the substrate as narrow as 0.8 .mu.m with an aspect ratio of up to 4.5:1.

Abstract: The present invention provides a method and apparatus for reducing the concentration of mobile ion and metal contaminants in a processing chamber by increasing the bias RF power density to greater than 0.051 W/mm.sup.2 and increasing the season time to greater than 30 seconds, during a chamber seasoning step. The method of performing a season step in a chamber by depositing a deposition material under the combined conditions of a bias RF power density of about 0.095 W/mm.sup.2 and a season time of from about 50 to about 70 seconds, reduces the mobile ion and metal contaminant concentrations within the chamber by about one order of magnitude.