Abstract: A method for fabricating one or more conductive lines in an integrated circuit includes providing a layer of copper containing conductive metal in a multi-layer structure fabricated upon a wafer, providing a first hard mask layer over the layer of copper containing conductive metal, performing a first sputter etch of first hard mask layer using a chlorine-based plasma or a sulfur fluoride-based plasma, and performing a second sputter etch of first hard mask layer using a second plasma, wherein a portion of the layer of copper containing conductive metal residing below a portion of the first hard mask layer that remains after the second sputter etch forms the one or more conductive lines. In one embodiment, the second plasma is a fluorocarbon-based plasma.

Abstract: A method for fabricating a plurality of conductive lines in an integrated circuit includes providing a layer of conductive metal in a multi-layer structure fabricated upon a wafer, forming a spacer in a layer of the multi-layer structure residing above the layer of conductive metal, wherein the spacer is formed from a metal-containing atomic layer deposition material, and transferring a pattern from the spacer to the layer of conductive metal using a sidewall image transfer technique, wherein the transferring results in a formation of the plurality of conductive lines in the layer of conductive material.

Abstract: A method for fabricating one or more conductive lines in an integrated circuit includes providing a layer of copper containing conductive metal in a multi-layer structure fabricated upon a wafer, providing a first hard mask layer over the layer of copper containing conductive metal, performing a first sputter etch of first hard mask layer using a chlorine-based plasma or a sulfur fluoride-based plasma, and performing a second sputter etch of first hard mask layer using a second plasma, wherein a portion of the layer of copper containing conductive metal residing below a portion of the first hard mask layer that remains after the second sputter etch forms the one or more conductive lines. In one embodiment, the second plasma is a fluorocarbon-based plasma.

Abstract: In a semiconductor integrated circuit device, thermo-mechanical stresses on the vias can be reduced by introducing a stress relief layer between the vias and a hard dielectric layer that overlies the vias.

Abstract: Thermo-mechanical stress on vias is reduced, thereby reducing related failures. This can be done by maintaining a via-to-metal area ratio at least as large as a predetermined value below which the additional stress on the vias does not significantly increase.

Abstract: A satisfactory conductive fill of a vertical trench of aspect ratio of at least 20 to 1 in a silicon substrate is obtained by heating the substrate to a temperature of about 375° C. or less in a chamber for chemical vapor deposition along with a mixture of WF6, H2, and SiH4 for filling the trench with tungsten. Also, W(CO)6 may be substituted for the WF6.

Abstract: An improved fill of high aspect ratio trenches by copper is obtained by first sputtering a thin nucleating film of copper deposited by physical vapor deposition, then depositing a thin seed layer of copper by chemical vapor deposition, and then completing the fill by electroplating. Stress migration of the fill is improved if the copper deposition is preceded by the deposition by CVD of a layer of titanium nitride either alone or preceded and/or followed by the deposition of tantalum by an ionized PVD source.