Abstract: An electrically erasable and programmable memory cell is provided. The memory cell includes a floating gate MOS transistor and a bipolar transistor for injecting an electric charge into the floating gate. The floating gate transistor has a source region and a drain region formed in a first well with a channel defined between the drain and source regions, a control gate region, and a floating gate extending over the channel and the control gate region. The bipolar transistor has an emitter region formed in the first well, a base region consisting of the first well, and a collector region consisting of the channel. The memory cell includes a second well that is insulated from the first well, and the control gate region is formed in the second well. Further embodiments of the present invention provide a memory including at least one such memory cell, an electronic device including such a memory, and methods of integrating a memory cell and erasing a memory cell.

Abstract: Matrix of memory cells formed using a method allowing for a self-alignment of the respective source region with the respective field oxide layer and the respective overlying polysilicon layer of each single cell of the matrix, the matrix including at least one first ROM memory cell suitable for permanently storing a first logic level, associated with a respective row and a respective column of the matrix, the first cell including a silicon substrate of a first conductivity type over which a first isolation region and a second isolation region are formed delimiting therebetween a longitudinal stripe, a gate element extending transversally through the stripe from at least one side of the first isolation region to at least one side of the second isolation region, a third region of a second conductivity type and a fourth region of a second conductivity type formed in the substrate along the stripe, and a field oxide region adapted to prevent the formation of a conductive channel in the substrate, and at least a s

Abstract: An electrically erasable and programmable memory cell is provided. The memory cell includes a floating gate MOS transistor and a bipolar transistor for injecting an electric charge into the floating gate. The floating gate transistor has a source region and a drain region formed in a first well with a channel defined between the drain and source regions, a control gate region, and a floating gate extending over the channel and the control gate region. The bipolar transistor has an emitter region formed in the first well, a base region consisting of the first well, and a collector region consisting of the channel. The memory cell includes a second well that is insulated from the first well, and the control gate region is formed in the second well. Further embodiments of the present invention provide a memory including at least one such memory cell, an electronic device including such a memory, and methods of integrating a memory cell and erasing a memory cell.

Abstract: A bipolar transistor is produced by processes employed in the manufacture of CMOS nonvolatile memory devices, and is part of an integrated circuit. The integrated circuit includes a semiconductor substrate having a first type of conductivity, a PMOS transistor formed in said substrate, an NMOS transistor formed in said substrate, and the bipolar transistor.

Abstract: A bipolar transistor is produced by processes employed in the manufacture of CMOS nonvolatile memory devices, and is part of an integrated circuit. The integrated circuit includes a semiconductor substrate having a first type of conductivity, a PMOS transistor formed in said substrate, an NMOS transistor formed in said substrate, and the bipolar transistor.

Abstract: A high voltage capacitor, integratable monolithically on a semiconductor substrate which accommodates a field oxide region overlaid by a first layer of polycrystalline silicon isolated from a second layer of polycrystalline silicon by an interpoly dielectric layer, comprises two elementary capacitors having a first common conductive plate which is formed in the first layer of polycrystalline silicon. Each of these elementary capacitors has a second conductive plate formed in the second layer of polycrystalline silicon above the first plate, and includes said interpoly dielectric layer as an isolation dielectric between the two plates.

Abstract: A process for the manufacture of an integrated voltage limiter and stabilizer component in a flash EEPROM memory device comprises a step of formation of an N type lightly doped well on a single-crystal silicon substrate; a step of formation of an active area on the surface of said N type well; a step of growth of a thin gate oxide layer over said active area; a step of implantation of a first heavy dose of N type dopant into said N type well to obtain an N type region; a step of implantation of a second heavy dose, higher than said first heavy dose, of N type dopant into said N type region to obtain an N+contact region to both the N type well and said N type region; a step of implantation of a third heavy dose, higher than said first heavy dose, of P type dopant into said N type region to form a P+ region.

Abstract: A method for producing electrically erasable and programmable read-only memory cells with a single polysilicon level, including the use of a sacrificial layer of silicon oxide to produce a high-thickness silicon oxide layer on the active area. The active area of the cell is protected from heavy source and drain implantation in order to improve reliability.

Abstract: A method for forming thin oxide portions in electrically erasable and programmable read-only memory cells, including the use of the enhanced oxidation effect and the lateral diffusion of heavy doping, for obtaining a tunnel portion whose dimensions are smaller than the resolution of the photolithographic method used.

Abstract: A process for the manufacture of an integrated voltage limiter and stabilizer component in a flash EEPROM memory device comprises a step of formation of an N type lightly doped well on a single-crystal silicon substrate; a step of formation of an active area on the surface of said N type well; a step of growth of a thin gate oxide layer over said active area; a step of implantation of a first heavy dose of N type dopant into said N type well to obtain an N type region; a step of implantation of a second heavy dose, higher than said first heavy dose, of N type dopant into said N type region to obtain an N+ contact region to both the N type well and said N type region; a step of implantation of a third heavy dose, higher than said first heavy dose, of P type dopant into said N type region to form a P+ region.

Abstract: A method for forming thin oxide portions in electrically erasable and programmable read-only memory cells, including the use of the enhanced oxidation effect and the lateral diffusion of heavy doping, for obtaining a tunnel portion whose dimensions are smaller than the resolution of the photolithographic method used.

Abstract: A method for producing electrically erasable and programmable read-only memory cells with a single polysilicon level, including the use of a sacrificial layer of silicon oxide to produce a high-thickness silicon oxide layer on the active area. The active area of the cell is protected from heavy source and drain implantation in order to improve reliability.

Abstract: The manufacturing process comprises a first step of formation of an N type sink on a single-crystal silicon substrate, a second step of formation of an active area on the surface of said sink, a third step of implantation of N- dopant in a surface region of the sink inside said active area, a fourth step of growth of a layer of gate oxide over said region with N- dopant, a fifth step of N+ implantation inside said N- region, a sixth step of P+ implantation in a laterally displaced position with respect to said N+ region and a seventh step of formation of external contacts for said N+ and P+ regions. There is thus obtained a zener diode limiter, having a cut-off voltage which is stable over time and not much dependent on temperature and which does not require the addition of process steps with respect to those usually necessary for the accomplishment of EEPROM memory cells.

Abstract: Blood to be purified is passed through a haemofiltration element and a haemodialysis element in cascade and the ultrafiltrate output from the haemofiltration element is passed through a filter such as an activated carbon filter, preferably with uncoated activated carbon. The ultrafiltrate thus purified can then be used as a reinfusion solution to be readministered to the patient.

Abstract: The process for manufacturing EEPROM memory cells having a single level of polysilicon and thin oxide with selection transistor, sensing transistor having a floating gate, control gate with a capacitive coupling to the floating gate and a tunnel area with thin oxide, comprises a first step involving the definition of active areas free of field oxide, a second step involving an ionic implantation at a coupling area between the control gate and the floating gate, a third step involving the creation of gate oxide at the active areas, a fourth step involving an additional ionic implantation at said coupling area between the control gate and the floating gate and at said tunnel area, a fifth step involving the removal of the gate oxide superimposed over said areas, a sixth step involving the differentiated growth of coupling oxide and tunnel oxide at said coupling areas and tunnel areas and a seventh step involving the deposition of a layer of polysilicon constituting the floating gate.