Abstract: An insulating material interposed between two conductive materials can experience plasma process induced damage (PPID) when a plasma process is used to deposit a dielectric onto one of the conductive materials. This PPID can be reduced by reducing electric charge accumulation on the one conductive material during the plasma process dielectric deposition.

Abstract: A PMOS device can be designed and manufactured in accordance with the invention to locate its drain junction breakdown point and maximum impact ionization point to reduce or eliminate drain breakdown voltage walk-in. In some embodiments, the drain junction breakdown point and maximum impact ionization point are located sufficiently far from the gate that the device exhibits no significant drain breakdown voltage walk-in. The device can be a high voltage power transistor having an extended drain region including a P-type lightly doped drain (P-LDD) implant, with drain junction breakdown and maximum impact ionization points appropriately located by controlling the implant dose employed to produce the P-LDD implant.

Abstract: A number of modified lateral DMOS (LDMOS) transistor arrays are formed and tested to determine if a measured value, such as a series on-resistance, substrate current, breakdown voltage, and reliability, satisfies process alignment requirements. The modified LDMOS transistor arrays are similar to standard LDMOS transistor arrays such that the results of the modified LDMOS transistor arrays can be used to predict the results of the standard LDMOS transistor arrays.

Abstract: A MOS transistor is formed with a dual-layer silicon oxynitride (SiON) etch stop film that protects the transistor from plasma induced damage (PID) and hot carrier degradation, thereby improving the reliability of the transistors. The first SiON layer is formed with SiH4 at a first flow rate, and the second SiON layer is formed with SiH4 at a second higher flow rate.

Abstract: A PMOS device can be designed and manufactured in accordance with the invention to locate its drain junction breakdown point and maximum impact ionization point to reduce or eliminate drain breakdown voltage walk-in. In some embodiments, the drain junction breakdown point and maximum impact ionization point are located sufficiently far from the gate that the device exhibits no significant drain breakdown voltage walk-in. The device can be a high voltage power transistor having an extended drain region including a P-type lightly doped drain (P-LDD) implant, with drain junction breakdown and maximum impact ionization points appropriately located by controlling the implant dose employed to produce the P-LDD implant.

Abstract: A PMOS device can be designed and manufactured in accordance with the invention to locate its drain junction breakdown point and maximum impact ionization point to reduce or eliminate drain breakdown voltage walk-in. In some embodiments, the drain junction breakdown point and maximum impact ionization point are located sufficiently far from the gate that the device exhibits no significant drain breakdown voltage walk-in. The device can be a high voltage power transistor having an extended drain region including a P-type lightly doped drain (P-LDD) implant, with drain junction breakdown and maximum impact ionization points appropriately located by controlling the implant dose employed to produce the P-LDD implant.

Abstract: A MOS transistor is formed with a dual-layer silicon oxynitride (SiON) etch stop film that protects the transistor from plasma induced damage (PID) and hot carrier degradation, thereby improving the reliability of the transistors. The first SiON layer is formed with SiH4 at a first flow rate, and the second SiON layer is formed with SiH4 at a second higher flow rate.

Abstract: A PMOS device can be designed and manufactured in accordance with the invention to locate its drain junction breakdown point and maximum impact ionization point to reduce or eliminate drain breakdown voltage walk-in. In some embodiments, the drain junction breakdown point and maximum impact ionization point are located sufficiently far from the gate that the device exhibits no significant drain breakdown voltage walk-in. The device can be a high voltage power transistor having an extended drain region including a P-type lightly doped drain (P-LDD) implant, with drain junction breakdown and maximum impact ionization points appropriately located by controlling the implant dose employed to produce the P-LDD implant.

Abstract: The drain breakdown voltage walk-in of a dual-source, dual-gate PMOS transistor is significantly reduced by utilizing source regions which have a width that is equal to or less than a width of the drain region. By utilizing source regions with widths that are equal to or less than the width of the drain region, the current density in the drain region is significantly reduced which reduces the number of hot charge carriers that are trapped at the silicon-to-silicon dioxide interface which, turn in, reduces the drain breakdown voltage walk-in rate.

Abstract: A PMOS device can be designed and manufactured in accordance with the invention to locate its drain junction breakdown point and maximum impact ionization point to reduce or eliminate drain breakdown voltage walk-in. In some embodiments, the drain junction breakdown point and maximum impact ionization point are located sufficiently far from the gate that the device exhibits no significant drain breakdown voltage walk-in. The device can be a high voltage power transistor having an extended drain region including a P-type lightly doped drain (P-LDD) implant, with drain junction breakdown and maximum impact ionization points appropriately located by controlling the implant dose employed to produce the P-LDD implant.

Abstract: An LDMOS structure which provides for reduced hot carrier effects. The reduction in hot carrier effects is achieved by increasing the size of the drain region of the LDMOS relative to the size of the source region. The larger size of the drain region reduces the concentration of electrons entering the drain region. This reduction in the concentration of electrons reduces the number of impact ionizations, which in turn reduces the hot carrier effects. The overall performance of the LDMOS is improved by reducing the hot carrier effects.

Abstract: In a LDMOS transistor or matrix of transistors, hot carrier degradation effects are reduced by providing a ring drain and providing the ring drain with an overvoltage bias relative to the internal drain(s) of the LDMOS transistors.

Abstract: The safe operating area of a high-voltage MOSFET, such as a lateral double-diffused MOS (LDMOS) transistor, is increased by using transistor cells with an X-shaped body contact region and four smaller source regions that adjoin the body contact region. The X-shaped body contact region lowers the parasitic base resistance of the transistor, thereby increasing the safe operating area of the transistor.

Abstract: An LDMOS array includes an array of alternating source regions and drain regions formed in a semiconductor substrate to define a checkerboard pattern of source and drain regions. A source contact is formed in electrical contact with each of the source regions in the array to connect the source regions in parallel. A drain contact is formed in electrical contact with each of the drain regions in the array to connect the drain regions in parallel. A drain ring is formed around the periphery of the checkerboard pattern and in electrical contact with the drain contact, providing redistribution of the current flow within the LDMOS array and thereby allowing safer hot carrier operation at higher biases than with the conventional layout.