Abstract: A method for fabricating a field effect transistor (FET) in and on a semiconductor substrate with local interconnects to permit the formation of minimal space between gate and the local interconnects by fabricating the source and drain of the FET and the local interconnects prior to forming the gate of the FET.

Abstract: A test circuit includes a wafer, an insulative layer formed on the wafer, and a plurality of test structures formed in the insulative layer. Each of the test structures comprises a first comb having a first plurality of fingers and a second comb having a second plurality of fingers. The first and second pluralities of fingers are interleaved to define a finger spacing between the first and second pluralities of fingers. The finger spacing in a first one of the test structures being different than the finger spacing in a second one of the test structures. A method for characterizing damage in a semiconductor device includes providing a wafer having an insulative layer and a plurality of test structures formed in the insulative layer. The test structures have different geometries. An electrical characteristic of first and second test structures of the plurality of test structures is determined. The electrical characteristics of the first and second test structures is compared.

Abstract: The present invention is directed to a method of forming semiconductor devices. In one illustrative embodiment, the method comprises forming a layer of dielectric material, forming a hard mask layer above the layer of dielectric material, and forming an opening in the hard mask layer. The method further comprises forming a sidewall spacer in the opening in the hard mask layer that defines a reduced opening, forming an opening in the layer of dielectric material below the reduced opening, and forming a conductive interconnection in the opening in the dielectric layer.

Abstract: A semiconductor device includes a first dielectric layer, a plurality of conductive interconnections formed in the first dielectric layer, a patterned passivation layer formed above the conductive interconnections, and a second dielectric layer formed above and in contact with the passivation layer and the first dielectric layer. A method for forming a semiconductor device includes providing a base layer, forming a first dielectric layer over the base layer, forming a plurality of conductive interconnections in the first dielectric layer, forming a patterned passivation layer above the conductive interconnections, and forming a second dielectric layer above and in contact with the passivation layer and the first dielectric layer.

Abstract: A method for fabricating a field effect transistor (FET) in and on a semiconductor substrate with local interconnects to permit the formation of minimal space between gate and the local interconnects by fabricating the source and drain of the FET and the local interconnects prior to forming the gate of the FET.

Abstract: The present invention is directed to a method of making a semiconductor device. In one illustrative embodiment, the method comprises forming a first layer comprised of polysilicon, forming a second layer comprised of a refractory metal above the layer of polysilicon and converting at least a portion of the second layer to a first metal silicide. The method further comprises forming an anti-reflective coating layer above the layer of refractory metal or the first metal silicide layer, and patterning the first metal silicide layer and the layer of polysilicon to define a gate stack comprised of a first metal silicide region and a layer of polysilicon, forming a plurality of source/drain regions in the substrate, forming a third layer comprised of a refractory metal above at least the gate stack and the source/drain regions, and converting at least a portion of the third layer to a second metal silicide region.

Abstract: A method of forming minimal gaps or spaces in conductive lines pattern for increasing the density of integrated circuits by first forming an opening in an insulating layer overlying the conductive line by conventional optical lithography, followed by forming sidewalls in the opening to create a reduced opening, and using the sidewalls as a mask to remove, preferably by etching, a portion of the conductive line pattern substantially equal in size to the reduced opening.

Abstract: A method for fabricating a field effect transistor (FET) in and on a semiconductor substrate with local interconnects to permit the formation of minimal insulating space between polysilicon gate and the local interconnects by fabricating the source and drain of the FET and the local interconnects prior to forming the gate of the FET. A portion of an insulating layer between the source and drain is removed prior to forming the gate. Preferably, an etch stop layer on the semiconductor substrate underlying the insulating layer is used in the method.

Abstract: A method and the resulting device to permit the formation of minimal insulating space between polysilicon gates by forming an insulating layer over the polysilicon gates and protecting selected ones of the gates and the insulating layer with an etch barrier so that the opening for local interconnect metallization can be misaligned and the selected gates will be protected by its etch barrier and not be exposed to the opening. Further, local interconnect conductive material can pass over a gate or unrelated resistor without shorting the gate/resistor.

Abstract: A method of forming field isolation in a semiconductor substrate, such as shallow oxide trenches, for isolation of FET transistors, including complementary FETs such as CMOS, with selected sections of said trenches extending above the substrate and being coplanar with the upper surface of subsequently formed polysilicon gates. An etch protective layer is used during the formation and the filling of the trench openings so that the top of the trenches are coplanar with upper surface of the etch protective layer. Selected sections of the trenches are masked and protected prior to planarization of the non-masked trenches to the bottom edge of the etch protective layer. After deposition and planarization of the poly, the upper surface of a deposited polysilicon layer for forming polysilicon gates of FET transistors is coplanar and self-aligned with the upwardly extending selected sections of the field isolation trenches.

Abstract: A method of forming minimal gaps or spaces in a polysilicon conductive lines pattern for increasing the density of integrated circuits by converting an area of the size of the desired gap or space in the polysilicon to silicon oxide, followed by removing the silicon oxide. The preferred method is to selectively ion implant oxygen into the polysilicon and annealing to convert the oxygen implanted polysilicon to silicon oxide. As an alternative method, an opening in an insulating layer overlying the conductive line is first formed by conventional optical lithography, followed by forming sidewalls in the opening to create a reduced opening and using the sidewalls as a mask to blanket implant oxygen through the reduced opening and into the exposed polysilicon conductive line. After annealing, the implanted polysilicon converted to silicon oxide and removed to form a gap or space in the polysilicon conductive line pattern substantially equal in size to the reduced opening.