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 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 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 memory cell for storing data having at least three logic states includes a pair of storage devices and third-level storage and refresh circuitry coupled to a pair of storage nodes. The storage devices maintain multi-level signals representative of first and second logic states at the pair of storage nodes. To store a third logic state, the third-level storage and refresh circuitry maintain the multi-level signals at both storage nodes at substantially equal intermediate levels.

Abstract: A static random access memory (SRAM) cell having increased cell capacitance at the storage nodes utilizes a capacitive structure. The capacitive structure includes a dielectric material between polysilicon conductive lines and tungsten local interconnects. The polysilicon plates are each connected to drains of lateral transistors associated with the SRAM cell. A dielectric material such as silicon dioxide may be deposited between the local interconnect and polysilicon conductive lines. The capacitor structures are provided between first and second N-channel pull down transistors associated with the SRAM cell.

Abstract: A low resistance interconnect structure for integrated circuits formed by a composite layer of aluminum below and an amorphous compound of refractory metal and silicon above. In the process of manufacturing the interconnect structure, care must be taken so that an aluminum oxide layer is not formed between the aluminum and compound layers.

Abstract: A method is disclosed for making a highly planarized integrated circuit structure having deposited oxide portions planarized to the level of adjacent portions of the integrated circuit structure which comprises: deposition, over an integrated circuit structure having first portions at a height higher than the remainder of the integrated circuit structure, a conformal oxide layer; depositing a layer of a planarizing material such as polysilicon over the conformal oxide layer; polishing the structure a first time to expose the highest portions of the underlying conformal oxide layer; etching the structure a first time with an etchant system capable of removing the conformal oxide preferentially to the planarizing material; further polishing the structure a second time to remove planarizing material left from the first etching step; and then optionally etching the remainder of the structure to remove any remaining planarizing material and the remaining conformal oxide over the raised portions of the underlying i

Abstract: A stable, low resistance contact is formed in a contact hole (16) through an insulating layer (14), e.g., silicon dioxide, formed on a surface of a semiconductor substrate (12), e.g., silicon, to a portion of a doped region (10) in said semiconductor surface. The contact comprises (a) an adhesion and contacting layer (18) of titanium formed along the walls of the insulating layer and in contact with the portion of the doped region; (b) a barrier layer (20) formed over the adhesion and contacting layer; and (c) a conductive material (22) formed over the barrier layer and at least substantially filling said contact hole. A patterned metal layer (26) forms an ohmic contact interconnect to other devices and external circuitry.The adhesion and contacting layer and barrier layer are either physically or chemically vapor deposited onto the oxide surface. The conductive layer comprises one of CVD or bias sputtered tungsten, molybdenum or in situ doped CVD polysilicon.

Abstract: A 4T static RAM cell (10) comprising a flip-flop with two pull-down transistors (18, 20) and two pass-gate transistors (12, 14) is fabaricated employing two separate gate oxide formations (74, 76) and associated separate polysilicon depositions (52a -b, 56). Two reduced area contacts (58, 60) connect to the nodes (26, 30) of the circuit (10). The reduced area butting contacts comprise vertically-disposed, doped polysilicon plugs (94), which intersect and electrically interconnect buried polysilicon layers (load poly 88, gate poly 52a) with doped silicon regions (80) in a bottom layer. Adding the processing steps of forming separate gate oxides for the pull-down and pass-gate transistors results in a smaller cell area and reduces the requirements of the contacts from three to two. Further, the separate gate oxidations permit independent optimization of the pull-down and pass-gate transistors.

Abstract: A reduced area butting contact structure (10') is provided, which is especially suited for four-transistor static RAM cells. A structure is formed which includes a doped silicon region and one or more layers of polysilicon and oxide situated thereabove, one of which layers of polysilicon may be a gate polysilicon. An anisotropic etch is then performed through all upper layers including any upper polysilicon layers which may be present, but stopping at the doped silicon region and any gate polysilicon layers present, to form a contact hole (26'). The contact hole is filled with a conductive plug (32) of a material such as tungsten or polysilicon and etched back. In either case, contact with all polysilicon layers present and the doped silicon region is made. In the anisotropic etching process, a two-step etch is employed.

Abstract: A stable, low resistance contact is formed in a contact hole (16) through an insulating layer (14), e.g., silicon dioxide, formed on a surface of a semiconductor substrate (12), e.g., silicon, to a portion of a doped region (10) in said semiconductor surface. The contact comprises (a) an adhesion and contacting layer (18) of titanium formed along the walls of the insulating layer and in contact with the portion of the doped region; (b) a barrier layer (20) formed over the adhesion and contacting layer; and (c) a conductive material (22) formed over the barrier layer and at least substantially filling said contact hole. A patterned metal layer (26) forms an ohmic contact interconnect to other devices and external circuitry. The adhesion and contacting layer and barrier layer are either physically or chemically vapor deposited onto the oxide surface. The conductive layer comprises one of CVD or bias sputtered tungsten, molybdenum or in situ doped CVD polysilicon.

Abstract: A seal structure for a semiconductor integrated circuit is disclosed. Contacts within and outside the region encircled by the seal structure are coupled by running a doped semiconductor region under the encircling seal. A reverse biased junction is formed at the interface of the seal and underlying doped semiconductor region. The best mode disclosed is related to sealing fuse components from the remainder of the circuit components while providing electrical coupling ability.

Abstract: A method for forming doped, conductive plugs to fill and planarize contact windows in integrated circuits is disclosed. The process is applicable to CMOS, NMOS and bipolar technologies. Discrete, sized, contact apertures formed superposing junction regions of a substrate are filled with semiconductor material and the semiconductor material is doped to match the conductivity type of the underlying junction regions. Thus, the integrated circuit structure is substantially planarized for formation of interconnect layers.

Abstract: An improved dynamic random access memory (DRAM) cell circuit (46) having a charge amplifier is presented. The improvement comprises a bipolar amplification means (64) for amplifying a charge as it is read out of the memory cell (46). According to one embodiment of the present invention, in addition to a standard charge storage capacitor (50) and MOS transistor (48), the memory cell (46) also includes a write control line (60) and a second MOS transistor (62) for writing a "1" bit of information into the memory cell (46). These improvements require little or no additional space when used in a DRAM circuit and allow a reduction in the required capacitor area.