Abstract: A low dielectric constant insulating film on a substrate is formed by introducing a process gas comprising a silicon source, a fluorine source, and oxygen into a chamber. The process gas is formed into a plasma to deposit at least a first portion of the insulating film over the substrate. The wafer and the first portion of the insulating film are then heated to a temperature of about 100-500° C. for a period of time. The film may include several separate portions, the deposition of each of which is followed by a heating step. The film has a low dielectric constant and good gas-fill and stability due to the lack of free fluorine in the film.

Abstract: A low dielectric constant insulating film on a substrate is formed by introducing a process gas comprising a silicon source, a fluorine source, and oxygen into a chamber. The process gas is formed into a plasma to deposit at least a first portion of the insulating film over the substrate. The wafer and the first portion of the insulating film are then heated to a temperature of about 100-500° C. for a period of time. The film may include several separate portions, the deposition of each of which is followed by a heating step. The film has a low dielectric constant and good gap-fill and stability due to the lack of free fluorine in the film.

Abstract: A low dielectric constant insulating film on a substrate is formed by introducing a process gas comprising a silicon source, a fluorine source, and oxygen into a chamber. The process gas is formed into a plasma to deposit at least a first portion of the insulating film over the substrate. The wafer and the first portion of the insulating film are then heated to a temperature of about 100-500° C. for a period of time. The film may include several separate portions, the deposition of each of which is followed by a heating step. The film has a low dielectric constant and good gap-fill and stability due to the lack of free fluorine in the film.

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: 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 method and apparatus for depositing a halogen-doped oxide film having a low dielectric constant that is resistant to moisture absorption and outgassing of the halogen dopant, and that retains these qualities despite subsequent processing steps. The method begins by introducing process gases (including a halogen-containing source gas) into a processing chamber. A halogen-doped layer is then deposited. The combination of process gases is then changed and a sealing layer deposited which seals the dopant into the halogen-doped layer. The sealing layer may, for example, be a carbon-rich layer or an undoped layer. These steps are repeated until the film reaches a selected thickness.

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: A method and apparatus for depositing a halogen-doped oxide film having a low dielectric constant that is resistant to moisture absorption and outgassing of the halogen dopant, and that retains these qualities despite subsequent processing steps. The method begins by introducing process gases (including a halogen-containing source gas) into a processing chamber. A halogen-doped layer is then deposited. The combination of process gases is then changed and a sealing layer deposited which seals the dopant into the halogen-doped layer. The sealing layer may, for example, be a carbon-rich layer or an undoped layer. These steps are repeated until the film reaches a selected thickness.