Abstract: In a microcircuit device such as a memory chip, where a bank of state devices such as fuses and anti-fuses determines the enabling and disabling of redundant circuitry, a scheme for blowing one or more state devices by applying a programming voltage through a switching circuit comprising thin film transistors (TFTs) which are not damaged by the device blowing programming voltage. The TFTs can be activated by a low voltage enable signal provided by a state device designator logic module.

Abstract: A method is disclosed for providing a self-aligned silicide strap for connecting thin polysilicon layers (poly-1 and poly-2, etc.) separated by non-conducting gaps. A butting contact opening to the layers is formed in an overlying insulating layer. The contact exposes the poly-1 and poly-2 layers. A thin polysilicon layer (poly-3) is then deposited over the insulating layer and into the contact. This is followed by deposition of a refractory metal layer. The poly-3 layer should be thin enough that, alone, it cannot supply enough silicon to support full silicidation of the refractory metal layer. The structure is next sintered so that a silicide strap is formed in the contact opening and across exposed portions of the poly-1 and poly-2 layers. The ratio of silicon to titanium in regions over the insulating layer is lower than that in the strap, such that these more metallic regions may be selectively removed.

Abstract: A method of forming BiCMOS circuitry includes, i) conducting a first common second conductivity type implant into, a) a first substrate area to comprise a second conductivity type well for a first area first conductivity type FET, and b) a third substrate area to comprise one of a bipolar transistor second conductivity type collector or emitter region; ii) providing field oxide regions and active area regions within first, second and third areas of the substrate; iii) conducting a first common first conductivity type implant into, a) the second substrate area to comprise a first conductivity type channel stop region beneath field oxide in the second area, and b) the third substrate area to comprise the bipolar transistor base; and iv) conducting a second common second conductivity type implant into, a) at least one of the first or the second substrate areas to comprise at least one of a source/drain implant or a graded junction implant for at least one of the first or second conductivity type FETs, and b) the

Abstract: A semiconductor processing method of forming a plurality of conductive lines includes, a) providing a substrate; b) providing a first conductive material layer over the substrate; c) providing a first insulating material layer over the first conductive layer; d) etching through the first insulating layer and the first conductive layer to the substrate to both form a plurality of first conductive lines from the first conductive layer and provide a plurality of grooves between the first lines, the first lines being capped by first insulating layer material, the first lines having respective sidewalls; e) electrically insulating the first line sidewalls; and f) after insulating the sidewalls, providing the grooves with a second conductive material to form a plurality of second lines within the grooves which alternate with the first lines. Integrated circuitry formed according to the method, and other methods, is also disclosed.

Abstract: Disclosed are methods of forming resistors and diodes from semiconductive material, and static random access memory (SRAM) cells incorporating resistors, and to integrated circuitry incorporating resistors and diodes. A node to which electrical connection is to be made is provided. An electrically insulative layer is provided outwardly of the node. An opening is provided in the electrically insulative layer over the node. The opening is filled with semiconductive material which depending on configuration serves as one or both of a vertically elongated diode and resistor.

Abstract: A semiconductor processing method of forming a conductive gate line includes forming a field oxide mask over a portion of a semiconductor substrate. Field oxide regions are formed adjacent the field oxide mask. A portion of the field oxide mask is removed to form a buried contact mask. The buried contact mask defines an underlying masked buried contact area. The buried contact area is then unmasked. A conductive gate line is then formed over and in electrical communication with the unmasked buried contact area. A semiconductor processing method of making ohmic contact between a transistor gate line and a substrate diffusion region includes providing a gate dielectric layer over a substrate on exposed active area while a buried contact mask is in place. The buried contact was formed from a patterned portion of a field oxide mask.

Abstract: A method for forming a field effect transistor which includes providing a substrate having thin film source and drain regions formed thereon; forming a thin film channel region intermediate the thin film source and drain regions, the thin film channel region comprising a first layer of semiconductor material, an etch stop layer formed over the first layer semiconductor material, and a second layer of material formed over the etch stop layer; forming a masking layer over the source and drain regions while leaving the thin film channel region effectively exposed; and removing a portion of the second layer of material selectively relative to the etch stop layer in the exposed thin film channel region.

Abstract: A semiconductor processing method of forming a buried contact to a substrate region includes, a) providing a stress relief layer over a bulk semiconductor substrate; b) etching the stress relief layer to expose a desired buried contact area of the substrate; c) masking over the stress relief layer and over the desired buried contact area; d) with the masking in place, exposing the substrate to oxidation conditions effective to grow field oxide regions in unmasked areas of the substrate; e) after forming the field oxide regions, removing the masking from the substrate and effectively leaving the buried contact area exposed; f) providing a layer of electrically conductive material over field oxide and exposed buried contact area; and g) patterning the conductive material layer into a conductive line which overlies both field oxide and the buried contact area.

Abstract: A semiconductor processing method of providing a polysilicon layer atop a semiconductor wafer comprises the following sequential steps: a) depositing a first layer of arsenic atop a semiconductor wafer; b) depositing a second layer of silicon over the arsenic layer, the second layer having an outer surface; c) first annealing the wafer at a temperature of at least about 600.degree. C. for a time period sufficient to impart growth of polycrystalline silicon grains in the second layer and providing a predominately polysilicon second layer, the first annealing step imparting diffusion of arsenic within the second layer to promote growth of large polysilicon grains; and d) with the second layer outer surface being outwardly exposed, second annealing the wafer at a temperature effectively higher than the first annealing temperature for a time period sufficient to outgas arsenic from the polysilicon layer.

Abstract: A method of forming an SRAM cell includes, a) providing a pair of pull-down gates having associated transistor diffusion regions operatively adjacent thereto, one of the diffusion regions of each pull-down gate being electrically connected to the other pull-down gate; b) providing a pair of pull-up resistor nodes for electrical connection with a pair of respective pull-up resistors, the pull-up nodes being in respective electrical connection with one of the pull-down gate diffusion regions and the other pull-down gate; c) providing a first electrical insulating layer outwardly of the resistor nodes; d) providing a pair of contact openings, with respective widths, through the first insulating layer to the pair of resistor nodes; e) providing a second electrical insulating layer over the first layer and to within the pair of contact openings to a thickness which is less than one-half the open widths; f) anisotropically etching the second electrical insulating layer to define respective electrical insulating ann

Abstract: A thin film effect transistor includes: a) a thin film channel region; b) a pair of opposing electrically conductive first and second source/drain regions adjacent the thin film channel region; (c) a gate insulator and a gate positioned adjacent the thin film channel region for electrically energizing the channel region to switch on the thin film field effect transistor; (d) the first source/drain region having a first thickness, the second source/drain region having a second thickness, the channel region having a third thickness; at least one of the first and second thicknesses being greater than the third thickness. Methods are disclosed for making thin field effect transistors.

Abstract: A semiconductor processing method of forming a field effect transistor gate over a semiconductor substrate includes forming a gate dielectric layer over substrate active area while a buried contact mask to said active area is in place. A field effect transistor gate is formed over the gate dielectric layer. A semiconductor processing method of forming a conductive line over a substrate active area includes forming a buried contact mask within a substrate active area from only a portion of a prior used field oxide mask. With the buried contact mask in place, a conductive line is formed that overlies the substrate active area. A semiconductor processing method of forming an electrical connection to a buried contact area of a substrate includes forming a buried contact mask in a substrate active area from a prior used field oxide mask. With the buried contact mask in place, a first conductive line is formed over at least some of the active area adjacent the buried contact mask.

Abstract: A thin film field effect transistor includes: a) a thin film channel region; b) a pair of opposing electrically conductive first and second source/drain regions adjacent the thin film channel region; c) a gate insulator and a gate positioned adjacent the thin film channel region for electrically energizing the channel region to switch on the thin film field effect transistor; d) the first source/drain region having a first thickness, the second source/drain region having a second thickness, the channel region having a third thickness; at least one of the first and second thicknesses being greater than the third thickness. Methods are disclosed for making thin field effect transistors.

Abstract: A thin film transistor includes: a) a thin film transistor layer comprising a source region, a channel region and a drain region; the thin film transistor layer further comprising a drain offset region positioned between the drain region and the channel region; b) the channel region being substantially polycrystalline and having a first average crystalline grain size; and c) the drain offset region being substantially polycrystalline and having a second average crystalline grain size, the second average crystalline grain size being larger than the first average crystalline grain size. A method for forming such a construction using polycrystalline materials, preferably polysilicon, and an amorphizing silicon implant with subsequent recrystallization is also disclosed.

Abstract: A method of forming a thin film transistor of a first conductivity type includes, a) providing a thin film transistor layer of semiconductive material; b) first masking the thin film transistor layer to mask a desired drain offset region while leaving a desired channel region exposed; c) with the first masking in place, doping the exposed channel region with a conductivity enhancing impurity of a second type; d) second masking the thin film transistor layer to mask the channel region and the drain offset region and leave desired opposing source/drain regions exposed; and e) with the second masking in place, doping the exposed source/drain regions with a conductivity enhancing impurity of the first type.

Abstract: Disclosed are methods of forming resistors and diodes from semiconductive material, and static random access memory (SRAM) cells incorporating resistors, and to integrated circuitry incorporating resistors and diodes. A node to which electrical connection is to be made is provided. An electrically insulative layer is provided outwardly of the node. An opening is provided in the electrically insulative layer over the node. The opening is filled with semiconductive material which depending on configuration serves as one or both of a vertically elongated diode and resistor.

Abstract: A method of forming an SRAM cell includes, a) providing a pair of pull-down gates having associated transistor diffusiion regions operatively adjacent thereto, one of the diffusion regions of each pull-down gate being electrically connected to the other pull-down gate; b) providing a pair of pull-up resistor nodes for electrical connection with a pair of respective pull-up resistors, the pull-up nodes being in respective electrical connection with one of the pull-down diffusion regions and the other pull-down gate; c) providing a first electrical insulating layer outwardly of the reistor nodes; d) providing a pair of contact openings, with respective width, through the first insulating layer to the pair of resistor nodes; e) providing a second electrical insulating layer over the first layer and to within the pair of contact openings to a thickness which is less than one-half the open widths; f) anisotropically etching the second electrical insulating layer to define respective electrical insulating annulus s

Abstract: A semiconductor processing method of forming a conductive polysilicon line relative to a substrate includes, a) providing a line of silicon on a substrate, the line having an outer top surface and outwardly exposed opposing outer sidewall surfaces, the line ultimately comprising conductively doped polysilicon; b) masking the line outer top surface with a masking material; c) with the masking material in place, depositing a metal layer atop the substrate and over the masking material and the outwardly exposed line outer sidewall surfaces; d) annealing the line to impart a silicidation reaction between the metal and opposing silicon sidewalls to form opposing metal silicide runners extending along the line sidewalls, the masking material preventing a silicidation reaction from occurring between the metal and line outer top surface; and e) stripping the metal layer from atop the line. Such a line is preferably used as a bottom gate for a thin film transistor.

Abstract: A method of forming an SRAM cell includes, a) providing a pair of pull-down gates having associated transistor diffusion regions operatively adjacent thereto, one of the diffusion regions of each pull-down gate being electrically connected to the other pull-down gate; b) providing a pair of pull-up resistor nodes for electrical connection with a pair of respective pull-up resistors, the pull-up nodes being in respective electrical connection with one of the pull-down gate diffusion regions and the other pull-down gate; c) providing a first electrical insulating layer outwardly of the resistor nodes; d) providing a pair of contact openings, with respective widths, through the first insulating layer to the pair of resistor nodes; e) providing a second electrical insulating layer over the first layer and to within the pair of contact openings to a thickness which is less than one-half the open widths; f) anisotropically etching the second electrical insulating layer to define respective electrical insulating ann

Abstract: A buried contact is formed in a substrate implantation of phosphorous or arsenic through a window cut into the insulating silicon oxide layer and a superimposed thin silicon layer. The photoresist used to etch the window is cut back a limited amount prior to implantation. The peripheral margin of the buried contact implanted through the exposed part of the thin layer of silicon lowers the threshold voltage of any parasitic MOS device which may be created between the buried contact and the remote N+source or drain structure.