Abstract: A simple, effective and economical method to improved the yield of CMOS devices using contact etching stopper liner, including, single neutral stressed liner, single stressed liner and dual stress liner (DSL), technology is provided. In order to improve the chip yield, the present invention provides a method in which a sputter etching process is employed to smooth/flatten (i.e., thin) the top surface of the contact etch stopper liners. When DSL technology is used, the inventive sputter etching process is used to reduce the complexity caused by DSL boundaries to smooth/flatten top surface of the DSL, which results in significant yield increase. The present invention also provides a semiconductor structure including at least one etched liner.

Abstract: A CMOS structure and methods for fabricating the CMOS structure provide that a first stressed layer located over a first transistor and a second stressed layer located over a second transistor abut but do not overlap. Such an abutment absent overlap provides for enhanced manufacturing flexibility when forming a contact to a silicide layer upon a source/drain region within one of the first transistor and the second transistor.

Abstract: A stress nitride structure is formed on an integrated circuit field effect transistor by high density plasma (HDP) depositing a first stress nitride layer on the integrated circuit field effect transistor and then plasma enhanced chemical vapor depositing (PECVD) a second stress nitride layer on the first stress nitride layer. The first stress nitride layer is non-conformial and the second stress nitride layer is conformal. Related structures also are described.

Abstract: An interconnect structure and method of making the same are provided. The interconnect structure includes a dielectric layer having a patterned opening, a metal feature disposed in the patterned opening, and a dielectric cap overlying the metal feature. The dielectric cap has an internal tensile stress, the stress helping to avoid electromigration from occurring in a direction away from the metal line, especially when the metal line has tensile stress.

Abstract: The present invention relates to a bilayer cap structure for interconnect structures that comprise copper metallization or other conductive metallization. Such bilayer cap structure includes a first cap layer formed by an unbiased high density plasma (HDP) chemical vapor deposition process, and a second cap layer over the first cap layer, where the second cap layer is formed by a biased high density plasma (bHDP) chemical vapor deposition process. During the bHDP chemical vapor deposition process, a low AC bias power is applied to the substrate to increase the ion bombardment on the substrate surface and to induce resputtering of the capping material, thereby forming a seamless second cap layer with excellent reactive ion etching (RIE) selectivity.

Abstract: A method is provided for making a FET device in which a nitride layer overlies the PFET gate structure, where the nitride layer has a compressive stress with a magnitude greater than about 2.8 GPa. This compressive stress permits improved device performance in the PFET. The nitride layer is deposited using a high-density plasma (HDP) process, wherein the substrate is disposed on an electrode to which a bias power in the range of about 50 W to about 500 W is supplied. The bias power is characterized as high-frequency power (supplied by an RF generator at 13.56 MHz). The FET device may also include NFET gate structures. A blocking layer is deposited over the NFET gate structures so that the nitride layer overlies the blocking layer; after the blocking layer is removed, the nitride layer is not in contact with the NFET gate structures. The nitride layer has a thickness in the range of about 300-2000 ?.

Abstract: The present invention relates to a bilayer cap structure for interconnect structures that comprise copper metallization or other conductive metallization. Such bilayer cap structure includes a first cap layer formed by an unbiased high density plasma (HDP) chemical vapor deposition process, and a second cap layer over the first cap layer, where the second cap layer is formed by a biased high density plasma (bHDP) chemical vapor deposition process. During the bHDP chemical vapor deposition process, a low AC bias power is applied to the substrate to increase the ion bombardment on the substrate surface and to induce resputtering of the capping material, thereby forming a seamless second cap layer with excellent reactive ion etching (RIE) selectivity.

Abstract: An HDP process for high aspect ratio gap filling comprises contacting a semiconductor substrate with an oxide precursor under high density plasma conditions at a first pressure less than about 10 millitorr, wherein said gaps are partially filled with oxide; and further contacting the substrate with an oxide precursor under high density plasma conditions at a second pressure greater than about 10 millitorr, wherein said gaps are further filled with oxide.

Abstract: A process for providing regions of substantially lower fluorine content in a fluorine-containing dielectric comprises exposing the fluorine-containing dielectric to a reactive species to form volatile byproducts.

Abstract: An HDP process for high aspect ratio gap filling comprises contacting a semiconductor substrate with an oxide precursor under high density plasma conditions at a first pressure less than about 10 millitorr, wherein said gaps are partially filled with oxide; and further contacting the substrate with an oxide precursor under high density plasma conditions at a second pressure greater than about 10 millitorr, wherein said gaps are further filled with oxide.

Abstract: A process for providing regions of substantially lower fluorine content in a fluorine-containing dielectric comprises exposing the fluorine-containing dielectric to a reactive species to form volatile byproducts.