Abstract: The present invention relates to a method of forming a transistor and a transistor structure. The invention comprises forming the transistor using a double silicide process which reduces resistance and reduces the floating-body-effect when employed in conjunction with SOI type device architecture.

Abstract: A SOI field effect transistor structure providing ESD protection. The structure has a source, a drain, a body, and a gate. The gate is formed from a thick oxide layer and a metal contact. The gate s formed during the BEOL process. The transistor may by a p-type transistor or an n-type transistor. The transistor may have its drain tied to either the gate, the body, or both the gate and body. When used as a protection device, the drain is tied to a signal pad and the source is tied to a potential reference.

Abstract: A SOI field effect transistor structure providing ESD protection. The structure has a source, a drain, a body, and a gate. The gate is formed from a thick oxide layer and a metal contact. The gate is formed during the BEOL process. The transistor may be a p-type transistor or an n-type transistor. The transistor may have its drain tied to either the gate, the body, or both the gate and body. When used as a protection device, the drain is tied to a signal pad and the source is tied to a potential reference.

Abstract: A SOI field effect transistor structure providing ESD protection. The structure has a source, a drain, a body, and a gate. The gate is formed from a thick oxide layer and a metal contact. The gate is formed during the BEOL process. The transistor may be a p-type transistor or an n-type transistor. The transistor may have its drain tied to either the gate, the body, or both the gate and body. When used as a protection device, the drain is tied to a signal pad and the source is tied to a potential reference.

Abstract: A method for reducing a hysteresis effect in silicon-on-insulator CMOS circuits includes the steps of providing a circuit having CMOS objects, defining a beta ratio; resizing the CMOS objects based on the beta ratio, determining if the objects are a minimum size based on predetermined size criteria, if the objects are larger than the minimum size, defining a scaling factor based on a performance level of the object and resizing the object based on the scaling factor such that delay variations of the resized circuit are substantially constant. Also, a computer program product is provided for reducing the hysteresis effect.

Abstract: Modifications of a digital logic device, such as a static or dynamic random access memory (SRAM or DRAM) or pass gate logic circuit or the like, implemented with complementary metal-oxide-semiconductor (CMOS) structures formed with silicon-on-insulator (SOI or, more specifically, SOICMOS) technology effectively suppress transient parasitic bipolar current disturbances (e.g. transient half select write disturb instabilities) caused by a discharge current through a parasitic lateral bipolar transistor formed under the transfer gate field effect transistors. Level shifting of the "off" voltage applied to the gate electrode of the transfer gate transistor dynamically changes the gain of the cell transfer gate to increase memory cell stability without compromising the memory capacity per chip or read/write memory cycle time even though level shifting can greatly increase majority carrier density in the floating body (gate) of a SOICMOS transistor at a particular level shifted voltage range.

Abstract: Producing a gap between a source and/or drain region of a silicon-on-insulator (SOI) field effect transistor which is less than the thickness of a depletion region normally surrounding the source and/or drain region, preferably at zero volts bias, permits gain of a parasitic bipolar transistor formed therewith to be transiently reduced and the effective base-emitter junction capacitance to be transiently increased during only modes of operation in which the parasitic bipolar conduction dominates normal operation of the field effect transistor. Such transient reduction of gain coupled with a transient reduction of high frequency response reduces the parasitic bipolar current spike to a degree greater than previously achievable and is fully compatible with other techniques of reducing such current spike.

Abstract: A thick-oxide ESD transistor for a BiCMOS integrated circuit has its source/drain contacts formed of the BiCMOS base or emitter polysilicon and its source/drain formed by an outdiffusion of the respective polysilicon contact. In one embodiment the BiCMOS resistor doping deepens the ESD source/drains, and in another embodiment the BiCMOS collector reach through doping deepens the ESD source/drains. The entire ESD transistor is fabricated from a standard BiCMOS process without any additional steps, has an area of about 100 square microns, can shunt up to 6000 volts, and has a turn-on time of about 10 picoseconds.

Abstract: A MOS device having protection against electrostatic discharge includes a protection diode formed below the MOS device so that excess charge buildup in the MOS device is conducted away from the MOS device by the protection diode.

Abstract: A lateral bipolar transistor and method of making which is compatible with making BICMOS circuits are disclosed. The method includes: Forming on a substrate of one conductivity type at least one layer of a semiconductor material of opposite conductivity type. Forming a first region of opposite conductivity type into one portion of the layer and a highly conductive contact region to the layer in another portion, forming a layer of an insulating material over the layer and providing an aperture therethrough to the first region. Depositing a layer of polycrystalline silicon over the insulating layer and in the aperture so that it is in the aperture and extends a short distance beyond the aperture but not beyond the edge of the first region.

Abstract: A lateral bipolar transistor and method of making the transistor which is compatible with a method of making MOS transistors to be used in making BICMOS circuits are disclosed. The method includes the following steps: Forming on the surface of a substrate of one conductivity type at least one layer of a semiconductor material of the opposite conductivity type. Forming a first region of the opposite conductivity type into one portion of the layer in one of the portions of the layer and a highly conductive contact region to the layer in another portion, forming a layer of an insulating material over the layer and providing an aperture therethrough to the first region. Depositing a layer of polycrystalline silicon over the insulating layer and in the aperture and defining the polycrystalline silicon layer so that it is in the aperture and extends a short distance beyond the aperture but not beyond the edge of the first region.

Abstract: A method of forming a complementary bipolar transistor device includes the steps of: providing a substrate of semiconductor material including at least two electrically isolated N-type device regions having a generally planar common surface; forming a P-type buried subcollar region in a first of the device regions; forming an N-type buried subcollector region in a second of the device regions; forming an N-type base region in the common surface of the first device region; forming a layer of P-doped polysilicon over the base region in the first device region and over the second device region; patterning the layer of P-doped polysilicon to form an emitter contact generally centered on the base region of the first device region and a generally annular base contact on the second device region; forming a layer of insulating material over the patterned layer of P-doped polysilicon; forming a layer of N-doped polysilicon generally conformally over the device; patterning the layer of N-doped polysilicon to form a bas