Abstract: A substrate processing method performed in a chamber of a substrate processing apparatus is provided. The chamber includes a substrate support, an upper electrode, and a gas supply port. The substrate processing method includes (a) providing the substrate on the substrate support; (b) supplying a first processing gas into the chamber; (c) continuously supplying an RF signal into the chamber while continuously supplying a negative DC voltage to the upper electrode, to generate plasma from the first processing gas in the chamber; and (d) supplying a pulsed RF signal while continuously supplying the negative DC voltage to the upper electrode, to generate plasma from the first processing gas in the chamber. The process further includes repeating alternately repeating the steps (c) and (d), and a time for performing the step (c) once is 30 second or shorter.

Abstract: A substrate processing method performed in a chamber of a substrate processing apparatus is provided. The chamber includes a substrate support, an upper electrode, and a gas supply port. The substrate processing method includes (a) providing the substrate on the substrate support; (b) supplying a first processing gas into the chamber; (c) continuously supplying an RF signal into the chamber while continuously supplying a negative DC voltage to the upper electrode, to generate plasma from the first processing gas in the chamber; and (d) supplying a pulsed RF signal while continuously supplying the negative DC voltage to the upper electrode, to generate plasma from the first processing gas in the chamber. The process further includes repeating alternately repeating the steps (c) and (d), and a time for performing the step (c) once is 30 second or shorter.

Abstract: Methods of forming integrated circuits are provided herein. In an embodiment, a method of forming an integrated circuit includes providing a semiconductor substrate. The semiconductor substrate includes a plurality of gate structures that have sidewalls spacers disposed adjacent to the gate structures. A gap is defined between sidewall spacers of adjacent gate structures. The method proceeds with decreasing an aspect ratio between a width of the gap at an opening thereto and a depth of the gap, wherein an aspect ratio between a width of the gap at a base of the sidewall spacers and the depth of the gap remains substantially unchanged after decreasing the aspect ratio between the width of the gap at the opening thereto.

Abstract: Methods of forming integrated circuits are provided herein. In an embodiment, a method of forming an integrated circuit includes providing a semiconductor substrate. The semiconductor substrate includes a plurality of gate structures that have sidewalls spacers disposed adjacent to the gate structures. A gap is defined between sidewall spacers of adjacent gate structures. The method proceeds with decreasing an aspect ratio between a width of the gap at an opening thereto and a depth of the gap, wherein an aspect ratio between a width of the gap at a base of the sidewall spacers and the depth of the gap remains substantially unchanged after decreasing the aspect ratio between the width of the gap at the opening thereto.

Abstract: Methods for fabricating integrated circuits are provided. An exemplary method for fabricating an integrated circuit includes forming a stack gate structure overlying a semiconductor substrate. The method forms a select gate material overlying the stack gate structure and the semiconductor substrate and having a planar surface overlying the stack gate structure. The method includes anisotropically etching the select gate material to define a select gate adjacent the stack gate structure, wherein the select gate is formed with a planar upper surface.

Abstract: An integrated circuit method for manufacturing an integrated circuit system including loading a wafer into a processing chamber and pre-purging the processing chamber with a first ammonia gas. Depositing a first nitride layer over the wafer and purging the processing chamber with a second ammonia gas. Depositing a second nitride layer over the first nitride layer that is misaligned with the first nitride layer. Post-purging the processing chamber with a third ammonia gas and purging the processing chamber with a nitrogen gas.

Abstract: An integrated circuit method for manufacturing an integrated circuit system including loading a wafer into a processing chamber and pre-purging the processing chamber with a first ammonia gas. Depositing a first nitride layer over the wafer and purging the processing chamber with a second ammonia gas. Depositing a second nitride layer over the first nitride layer that is misaligned with the first nitride layer. Post-purging the processing chamber with a third ammonia gas and purging the processing chamber with a nitrogen gas.

Abstract: An integrated circuit system including loading a wafer into a processing chamber and pre-purging the processing chamber with a first ammonia gas. Depositing a first nitride layer over the wafer and purging the processing chamber with a second ammonia gas. Depositing a second nitride layer over the first nitride layer that is misaligned with the first nitride layer. Post-purging the processing chamber with a third ammonia gas and purging the processing chamber with a nitrogen gas.

Abstract: A patterned and etched layer of gate electrode material is formed over the active surface of a substrate, a layer of liner oxide is created, gate spacers are created. Under the first embodiment of the invention, a layer of TEOS is deposited over the created structure over which a layer of nitride is deposited, The layer of nitride is etched, this etch is extended into an overetch creating openings through the layer of TEOS where this layer overlies the gate spacers. The gate spacers are then further etched. Under the second embodiment of the invention, a layer of TEOS is deposited over the created structure. The layer of TEOS is etched, stopping on the silicon nitride of the gate spacers. The gate spacers are then further etched.

Abstract: A method for forming a patterned microelectronic layer. There is first provided a substrate. There is then formed over the substrate a multi-layer stack layer comprising: (1) a first lower microelectronic layer; (2) a second intermediate patterned microelectronic layer formed over the first lower microelectronic layer; and (3) a third upper patterned microelectronic layer formed over the second intermediate patterned microelectronic layer, where the first lower microelectronic layer and the third upper patterned microelectronic layer are susceptible to etching within a first etchant. There is then formed encapsulating the first lower microelectronic layer and at least portion of the second intermediate patterned microelectronic layer while leaving exposed at least a portion of the third upper patterned microelectronic layer an encapsulating layer.

Abstract: A method for forming an L-shaped spacer using a sacrificial organic top coating. A semiconductor structure is provided having a gate structure thereon. A liner oxide layer is formed on the gate structure. A dielectric spacer layer is formed on the liner oxide layer. In the preferred embodiment, the dielectric spacer layer comprises a silicon nitride layer or a silicon oxynitride layer. A sacrificial organic layer is formed on the dielectric spacer layer. The sacrificial organic layer and the dielectric spacer layer are anisotropically etched to form spacers comprising a triangle-shaped sacrificial organic structure and an L-shaped dielectric spacer. The triangle-shaped sacrificial organic structure is removed leaving an L-shaped dielectric spacer.