Abstract: An example of a system includes a host interface, a set of non-volatile memory cells, and one or more control circuits coupled to the host interface and coupled to the set of non-volatile memory cells. The one or more control circuits include a portion of a Random Access Memory (RAM) configured as an overlay RAM. The one or more control circuits are configured to transfer overlay code to the overlay RAM via the host interface.

Abstract: An example of a system includes a host interface, a set of non-volatile memory cells, and one or more control circuits coupled to the host interface and coupled to the set of non-volatile memory cells. The one or more control circuits include a portion of a Random Access Memory (RAM) configured as an overlay RAM. The one or more control circuits are configured to transfer overlay code to the overlay RAM via the host interface.

Abstract: An exemplary CAD design flow modifies an existing large scale chip layout to reinforce the redundant via design rules to improve the yield and reliability. The flow operates on each metal-via pair from bottom up to locate and correct isolated via rule violations by adding metal features and vias in a respective patch cell associated with each cluster cell. A large complex design is thus divided into cells so that multiple processes can work concurrently as if every process were working on the top level of the design layout.

Abstract: An integrated circuit has a plurality of metal layers separated by a plurality of insulating layers. The integrated circuit comprises a pair of conductors on a first metal layer; at least one conductive fill element disposed between the conductors; and a via connecting the fill element to a ground contact on a metal layer adjacent to said first metal layer, where the via is formed of a conductive material.

Abstract: For an integrated circuit having multiple metal layers, a computer-aided design (CAD) method for designing grounded fill in the integrated circuit includes: (a) finding the eligible fill areas for each metal layer; (b) storing the eligible fill area data for each metal layer in an overflow memory; (c) finding ground contact areas for each metal layer; (d) storing the ground contact area data for each metal layer in an overflow memory; (e) temporarily storing the eligible fill area data for a selected metal layer and the ground contact area data for the metal layers adjacent to the selected metal layer in active memory; (f) fitting a fill pattern to an eligible fill area in the selected metal layer, where the fill pattern is composed of at least one element; (g) checking the adjacent metal layers for a ground contact where the element of the fill pattern may be grounded; (h) locating a conductive via between the element of the fill pattern and a ground contact in an adjacent layer; and (i) repeating steps (e)

Abstract: An integrated circuit has a plurality of metal layers separated by a plurality of insulating layers. The integrated circuit comprises a pair of conductors on a first metal layer; at least one conductive fill element disposed between the conductors; and a via connecting the fill element to a ground contact on a metal layer adjacent to said first metal layer, where the via is formed of a conductive material.

Abstract: Various improvements in the fabrication of an antifuse having silicon-amorphous silicon-metal layer structure are presented. Included are improved deposition techniques for the amorphous silicon layer. The improvements include steps for the fabrication of such an antifuse without the use of platinum and the resulting antifuse and contact structures.

Abstract: Various improvements in the fabrication of an antifuse having silicon-amorphous silicon-metal layer structure are presented. Included are improved deposition techniques for the amorphous silicon layer. The improvements include steps for the fabrication of such an antifuse without the use of platinum and the resulting antifuse and contact structures.

Abstract: An antifuse structure particularly suitable for field programmable gate arrays is presented. In most present day processes the antifuse structure is formed with a refractory metal layer, amorphous silicon layer and refractory metal layer sandwiched between two metal interconnection lines. Unprogrammed resistances of very high values, programmed resistances of very low values, short programming times and desirable programming voltages are among the advantages realized.

Abstract: An antifuse structure particularly suitable for field programmable gate arrays is presented. In most present day processes the antifuse structure is formed with a refractory metal layer, amorphous silicon layer and refractory metal layer sandwiched between two metal interconnection lines. Unprogrammed resistances of very high values, programmed resistances of very low values, short programming times and desirable programming voltages are among the advantages realized.

Abstract: An antifuse in an integrated circuit which has first and second conducting lines, a semiconductor layer of amorphous silicon between the first and second conducting lines, and a barrier metal layer of TiN between the semiconductor layer and the first conducting layer is disclosed. The TiN layer is nonstoichiometric composition to enhance the probability of said antifuse having a desired resistance when said antifuse is programmed. More specifically, the TiN layer has a composition of Ti.sub.1.0 N.sub.0.5-0.8.

Abstract: Various improvements in the fabrication of an antifuse having silicon-amorphous silicon-metal layer structure are presented. Included are improved deposition techniques for the amorphous silicon layer. The improvements include steps for the fabrication of such an antifuse without the use of platinum and the resulting antifuse and contact structures.

Abstract: An antifuse particularly suitable for submicron geometries is presented. The antifuse is formed between a silicon layer, which could be a doped region of the semiconductor substrate, an epitaxial layer or a polysilicon layer, and an upper metal interconnection layer. In contact holes in a silicon dioxide layer insulating the silicon and metal interconnection layers from each other, the antifuses have a thick refractory metal layer having a top surface approximately at the same level as the top surface of the insulating layer. Depending upon the process used to deposit the refractory metal layer, a thin adhesion layer may be located immediately below the refractory metal layer. Between the underlying silicon layer and upper interconnection layer, a thin semiconductor material layer of amorphous silicon may be located either below the refractory metal layer or above it.

Abstract: Before spin-on-glass (SOG) is applied and soft-cured over metal traces (10) having a height/width aspect ratio (of the spaces) of at least 1, the aluminum metal traces are selectively coated with selective tungsten (16). After SOG (18) is spun on and soft-cured, it is etched back to expose the metal interconnects. A selective tungsten wet etch in H.sub.2 O.sub.2 detaches the SOG from the metal walls, leaving silt-like voids (20). Stress-free SOG hard curing may now proceed. A capping layer (22) of SOG may now be applied, soft-cured, then hard-cured. Alternatively, other dielectric materials may be applied as the capping layer. Further, interfacial lateral sidewall voids (24) may be deliberately left unfilled, by employing a capping layer (22') of vapor-deposited oxide. The unfilled voids have a dielectric constant of 1.0, which is useful in extremely high speed devices.

Abstract: Before spin-on-glass (SOG) is applied and soft-cured over metal traces (10) having a height/width aspect ratio (of the spaces) of at least 1, the aluminum metal traces are selectively coated with selective tungsten (16). After SOG (18) is spun on and soft-cured, it is etched back to expose the metal interconnects. A selective tungsten wet etch in H.sub.2 O.sub.2 detaches the SOG from the metal walls, leaving silt-like voids (20). Stress-free SOG hard curing may now proceed. A capping layer (22) of SOG may now be applied, soft-cured, then hard-cured. Alternatively, other dielectric materials may be applied as the capping layer. Further, interfacial lateral sidewall voids (24) may be deliberately left unfilled, by employing a capping layer (24') of vapor-deposited oxide. The unfilled voids have a dielectric constant of 1.0, which is useful in extremely high speed devices.

Abstract: An interconnect (16',18', 18"), whose interlevel contacts comprise refractory (10) to refractory or refractory to semiconductor substrate (13) interfaces, comprises patterned refractory core portions (10), consisting of tungsten or molybdenum, having top portions (10a) and opposed side portions (10b), provided with sidewall spacers (32a) of aluminum, gold or copper or alloys thereof and formed on surfaces (12a) of insulating layers (12). The sidewall spacers afford lateral low resistivity cladding of the refractory portions as well as suppression of the electromigration failure modes of voiding and whiskering, while leaving the top portion of the core portions available for refractory to refractory contacts and the bottom portion of the core portions available for refractory to refractory or refractory to silicon contacts.

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 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: An interconnect (16', 18', 18"), whose interlevel contacts comprise refractory (10) to refractory or refractory to semiconductor substrate (13) interfaces, comprises patterned refractory core portions (10), consisting of tungsten or molybdenum, having top portions (10a) and opposed side portions (10b), provided with sidewall spacers (32a) of aluminum, gold or copper or alloys thereof and formed on surface (12a) of insulating layers (12). The sidewall spacers afford lateral low resistivity cladding of the refractory portions as well as suppression of the electromigration failure modes of voiding and whiskering, while leaving the top portion of the core portions available for refractory to refractory contacts and the bottom portion of the core portions available for refractory to refractory or refractory to silicon contacts.