Abstract: One embodiment of the present invention is a method of simultaneously forming high-voltage (12) and low-voltage (10) devices on a single substrate (14), the method comprising: forming a thin oxide layer (18) on the substrate, the thin oxide layer having a desired thickness for a gate oxide for the low-voltage device; selectively forming a gate structure (30) for the high-voltage device, the thin oxide is situated between the gate structure and the substrate; and selectively thickening the thin oxide under the gate structure while keeping the thin oxide layer utilized for the low-voltage device at the desired thickness.

Abstract: A semiconductor device having high and low voltage transistors on the same chip. High voltage NMOS transistor 76 comprises a polysilicon gate 40 doped at a first dopant level. Low voltage NMOS transistor comprises a polysilicon gate 44 doped at a second dopant level. The second dopant level is higher than the first. High voltage PMOS transistor 84 comprises a polysilicon gate 48 doped at a third dopant level. Low voltage PMOS transistor comprises a polysilicon gate 52 doped at a fourth dopant level. The fourth dopant level is higher than the third.

Abstract: A process for forming N-channel MOS sources and drains, by implanting both phosphorus and arsenic. The high diffusivity of phosphorus causes it to diffuse in advance of the bulk of the arsenic, so that, after annealing, the source/drain regions have graded regions of gradually decreasing conductivity adjacent to the end of the channels. Thus the electric potential gradient at the ends of the channels is reduced, and impact ionization and hot carrier effects are avoided. The effective radius of the source (or drain) junction is increased, providing increased breakdown voltage. The implantation of both phosphorus and arsenic with the resultant phosphorus peripheral band after annealing is used with self-aligned silicided source/drain regions to prevent silicide spiking through shallow arsenic regions to the P substrate and to prevent source/drain junction consumption during silicidation.

Abstract: The disclosure relates to a MOSFET-protected nonvolatile capacitor cell which has a storage gate and a nonvolatile stack thereunder, the cell having a heavily doped n+ ring surrounding the storage gate and an n-type tank disposed beneath the stack and electrically connected to the n+ type ring.

Abstract: The invention is an improved layout for integrated circuits employing local interconnect pads, particularly six-transistor SRAM circuits, comprising a local interconnect pad which electrically bridges two segments of a conducting line and an active device, and a method for employing the layout.

Abstract: An elevated transistor is provided having minimized junctions (33) and a polysilicon pad (27) over the transistor insulating regions (12) and partially over the moat (14). A conductive layer (32) overlays the polysilicon pad (27) and partially overlays the moat (14) in the interim areas (29).

Abstract: A raised source/drain transistor is provided having thin sidewall spacing insulators (54) adjacent the transistor gate (48). A first sidewall spacer (64) is disposed adjacent thin sidewall spacing insulator (54) and raised source/drain region (60). A second sidewall spacer (66) is formed at the interface between field insulating region (44) and raised source/drain region (60).

Abstract: A process for making CMOS device wherein the N-channel devices have n+ gates, and the P-channel devices have p+ gates. A TiN local interconnect system is used to connect the two types of gates, as well as providing connections to moat. A titanium nitride layer may be formed by depositing titanium metal everywhere, and then heating the integrated circuit structure in a nitrogen atmosphere. This process may also be used with other refractory metal nitride interconnect layers. In addition to titanium based thin film compositions, other metals can be substituted and used for direct-react silicidation and simultaneous formation of a conductive nitride to form local interconnects, including molybdenum, tungsten, vanadium, cobalt, and others.

Abstract: A method for treating cough in a mammal comprising administering to said mammal an anti-tussive effective amount of a GABA-B selective agonist such as ##STR1## is described.

Abstract: A raised source/drain transistor is provided having thin sidewall spacing insulators (54) adjacent the transistor gate (48). A first sidewall spacer (64) is disposed adjacent thin sidewall spacing insulator (54) and raised source/drain region (60). A second sidewall spacer (66) is formed at the interface between field insulating region (44) and raised source/drain region (60).

Abstract: The disclosure relates to a MOSFET-protected nonvolatile capacitor cell which has a storage gate and a nonvolatile stack thereunder, the cell having a heavily doped n+ ring surrounding the storage gate and an n-type tank disposed beneath the stack and electrically connected to the n+ type ring.

Abstract: P channel and N channel CMOS FETs (22, 24) and a process for their simultaneous fabrication with a minimal number of masking steps are disclosed. After formation of gates (30, 32) for both P channel FETs (24) and N channel FETs (22), a first N type dopant implanting step forms lightly doped drain extensions in both the P channel FETs (24) and the N channel FETs (22). A mask then protects the N channel FET area (22) while a P type dopant is implanted in source and drain regions (36) of the P channel FET (24) at a greater concentration than the prior implanted N type dopant. Another N type dopant implant occurs to both the P channel FET (24) and N channel FET (22). The N type dopant dosage used in this second N type dopant implantation step is greater than the dosage used in the first N type dopant implantation step.

Abstract: A multiple recess isolation technology avoids stress induced defects while providing a substantially planar surface. A silicon substrate (10) is patterned and etched, creating active moat regions (18) and recesses (20a-b and 21a-b). the recesses are filled with oxide by growing a field oxide (40) in wide recessed regions (21) using a LOCOS process, while depositing a planarization field oxide (44) in narrow recessed regions (20). After etching the structure to obtain a planar surface, standard procedures are used to fabricate the active devices. The process uses a single photolithographic masking step and results in only a very small loss of the width electrically active regions.

Abstract: A CMOS device wherein the N-channel devices have n+ gates, and the P-channel devices have p+ gates. A TiN local interconnect system is used to connect the two types of gates, as well as providing connections to moat.

Abstract: Polysilicon gate insulated gate field effect transistors with threshold adjustment implants made after the gate oxide (156) and a split of the polysilicon gate (158) have been formed provides a shallow, tight dopant profile.

Abstract: A multiple recess isolation technology avoids stress induced defects while providing a substantially planar surface. A silicon substrate (10) is patterned and etched, creating active moat regions (18) and recesses (20a-b and 21a-b). The recesses are filled with oxide by growing a field oxide (40) in wide recessed regions (21) using a LOCOS process, while depositing a planarization field oxide (44) in narrow recessed regions (20). After etching the structure to obtain a planar surface, standard procedures are used to fabricate the active devices. The process uses a single photolithographic masking step and results in only a very small loss of the width electrically active regions.

Abstract: Non-volatile JRAM cell having interelectrode non-volatile capacitance which is readable and varies with the electrical charge on elements of the device. To program the nonvolatile capacitance, the address lines (word line and bit line) are biased so that a charge is given to the nonvolatile multidielectric stack between the MIS gate and the JFET source of the cell. For a charge of one polarity, an inversion layer of electrons (for a P-type substrate) is formed on the surface of the JFET source, increasing the capacitance between the MIS gate electrode and the JFET gate electrode. For the opposite polarity, an accumulation layer forms at the JFET source surface, decreasing the interelectrode capacitance. The cell is read by presetting one address line, floating that line, then putting a pulse on the other line while reading the voltage output on the floating line.

Abstract: A non-volatile JRAM cell is constructed to require only positive voltage for programming and erasing of data in the cell. The "well" region of the cell JFET device may be implanted with an impurity concentration that will permit lower breakdown voltage or the non-volatile gate may overlap the JFET gate sufficiently to be able to have the same effect, or some combination of both may be used. This allows the cell to be erased using voltages of one polarity.

Abstract: An infrared random access imager system is disclosed which includes a scanning mechanism, a random access imager detector matrix, and a video signal processor. The scanning mechanism scans the infrared energy emanating from a scene in the field-of-view. The random access imager detector matrix stores charges as charge packets representative of the infrared energy impinging thereon and the video signal processor processes the charge packets into video signals. Each random access imager detector matrix element comprises a modified charge injection device, which has two electrodes per unit cell, and horizontal and vertical metal-lead address lines, to which is added a third electrode. The third electrode is a transfer gate which transfers the charge of the detector element into a read line and keeps the charge from one detector from spilling into the detector well of an adjoining unit cell. Thus, charge carriers are created by photoabsorption and collected in the detector well (storage well).

Abstract: A non-volatile memory storage cell utilizing a single vertical junction field-effect transistor is fabricated by a method, which is compatible with the fabrication of MOSFET interface and logic circuits on the same chip. Assembly of a multi-dielectric stack, which contains the non-volatile element, is accomplished late in the process to avoid degradation of the non-volatility characteristics.