Abstract: A shallow trench isolation having an etching stop layer and its method of fabrication. The method utilizes a shield layer such as a silicon nitride layer to serve as an etching stop layer. The etching stop layer is formed in the top position of the shallow trench isolation.

Abstract: A shallow trench isolation having an etching stop layer and its method of fabrication. The method utilizes a shield layer such as a silicon nitride layer to serve as an etching stop layer. The etching stop layer is formed in the top position of the shallow trench isolation.

Abstract: A MOSFET integrated circuit device comprises a lightly doping a semiconductor substrate, with wells formed within the substrate doped with an opposite value dopant, forming a plurality of doped regions within the surface of the substrate and within the surface of the wells, the improvement comprising opening a trench about the periphery of the wells, and filling the trench with a relatively highly conductive material as a guard structure.

Abstract: An improved metal oxide field effect transistor (MOSFET) provides an electro-static protection device with a high resistance to electro-static discharge. The electro-static discharge protection device has pre-gate heavily doped regions adjacent to the source and drain regions, where the pre-gate regions extend at least partially under the gate electrode. A single heavily doped pre-gate region may be provided for the MOSFET of the electro-static discharge protection circuit.

Abstract: A triple-well structure for semiconductor IC devices such as an SRAM IC device and a process for its fabrication, that allows for improved data storage stability as well as improved immunity capability against interference from device I/O bouncing and alpha particles. The triple-well structure includes at least one P-well in a P-type substrate, a number of N-wells, and a retrograde P-well formed within one of the N-wells. The process for fabricating the triple-well structure includes first implanting boron ions in the P-type substrate. A photomask is subsequently formed for the implantation of phosphorous ions in the region where a P-type MOS transistor is to be fabricated. A high temperature drive-in procedure is then employed to form a P-well and a number of N-wells. A selected area of one of the N-wells where an N-type MOS transistor is defined is then subjected to boron ion implantation, which is followed by an annealing procedure to form the retrograde P-well.

Abstract: SRAMs conventionally formed on N-type substrates are instead formed on P-type substrates which have had the surface layer of the substrate converted to a blanket N-type well region. Preferably, the blanket N-type well region is formed by ion implantation of phosphorus ions to a dosage of between 5.times.10.sup.12 to 2.times.10.sup.13 /cm.sup.2 at an energy of 200-1000 KeV. Use of a P-type substrate having a blanket N-well region formed by ion implantation are less expensive than the N-type substrates conventionally used, and make the SRAM processing techniques compatible with the P-type substrates conventionally used in microprocessors and other logic devices.

Abstract: A method of manufacture of a semiconductor device comprises forming a silicon dioxide film upon the surface of said device, forming patterns of silicon nitride upon the surface of said silicon dioxide film, ion implanting ions into said substrate adjacent to at least some of said silicon nitride patterns for well regions of a first polarity, forming a mask over said device, and deeply ion implanting with ions of opposite polarity into well regions of opposite polarity.

Abstract: An electrostatic discharge (ESD) circuit for protecting a semiconductor integrated circuit (IC) device is disclosed. One ESD circuit is located between each I/O buffering pad that connects to one lead pin and the internal circuitry of IC. The ESD circuit is connected to both power terminals. The ESD circuit comprises first and second low-voltage-trigger SCRs (LVTSCRs), each having an anode, a cathode, an anode gate and a cathode gate. The anode and anode gate of the first SCR are connected to a first power terminal, the cathode of the first SCR is connected to its I/O buffering pad, and the cathode gate of the first SCR is connected to the second power terminal. The ESD circuit further comprises a PMOS transistor having drain, source, gate, and bulk terminals. The PMOS transistor's gate, source and bulk terminals are connected to the first power terminal, the PMOS transistor drain terminal is connected to the cathode gate of the first SCR.

Abstract: An improved structure and process of fabricating a metal oxide field effect (MOSFET) which has a high resistance to electro-static discharge. The device has pre-gate heavily doped source and drain regions which overlap the gate electrode and the source and drain regions. This improved MOSFET device with overlapping pre-gate source and drain regions is incorporated into an electro-static discharge (ESD) circuit to form a memory device which has a high resistance to electro-static discharge (ESD).The MOSFET device with pre-gate heavily doped source and drain regions can be formed as follows. Spaced pre-gate source and drain regions of a second conductivity type are formed in the substrate with a background doping of a first conductivity type. A gate oxide and a gate is formed in the regions between the pre-gate source and drain regions. The gate at least partially overhangs the pre-gate source and drain regions. Subsequently, spacers are formed on the vertical sidewalls of the gate.

Abstract: An electrostatic discharge (ESD) protection circuit for eliminating the stress of electrostatic discharge and preventing destruction of an internal semiconductor circuit. A first low-voltage gate trigger silicon controlled rectifier anode and anode gate, a second low-voltage gate trigger silicon controlled rectifier anode gate and a third low-voltage gate trigger silicon controlled rectifier anode gate are each coupled to a reference high potential. A second low-voltage gate trigger silicon controlled rectifier cathode and cathode gate and a third low-voltage gate trigger silicon controlled rectifier anode are each coupled to a reference low potential. A first low-voltage gate trigger silicon controlled rectifier cathode, a second low-voltage gate trigger silicon controlled rectifier anode and a third low-voltage gate trigger silicon controlled rectifier cathode are each coupled to a wire connected between a semiconductor pad and the semiconductor circuit.

Abstract: A complementary-SCR electrostatic discharge protection circuit in a silicon substrate, coupling to I/O pads for bypassing electrostatic current of positive or negative polarity respect to power supply voltages V.sub.DD and V.sub.SS. The circuit comprises a first SCR and a second SCR each having an anode, a cathode, an anode gate and a cathode gate. The circuit of the present invention preferably includes a finger type layout structure for providing a larger capacity to bypass electrostatic current. It is also characterized by a base-emitter shorting design to avoid a V.sub.DD -to-V.sub.SS latch-up effect.

Abstract: A circuit for protecting a CMOS chip against damage from electrostatic discharges (ESD) has four SCRs connected between the line to be protected and the two power supply terminals, V.sub.DD and V.sub.SS. The SCRs are poled to conduct ESD current of either polarity to each power supply terminal. The bipolar transistors for the SCRs and the associated components are arranged in the chip in an advantageous way that reduces the input/output parasitic capacitance and improves the protection capability of this proposed circuit with a low ESD trigger-on voltage.

Abstract: A circuit for protecting a CMOS chip against damage from electrostatic discharges (ESD) has four SCRs connected between the line to be protected and the two power supply termiamls, V.sub.DD and V.sub.SS. The SCRs are poled to conduct ESD current of either polarity to each power supply terminal. The bipolar transistors for the SCRs and the associated component are arranged in the chip in an advantageous way that reduces the input/output parasitic capacitance and improves the protection capability of this proposed circuit with a low ESD trigger-on voltage.