Abstract: A semiconductor device with high breakdown voltage and low on-resistance is provided. An embodiment comprises a substrate having a buried layer in a portion of the top region of the substrate in order to extend the drift region. A layer is formed over the buried layer and the substrate, and high-voltage N-well and P-well regions are formed adjacent to each other. Field dielectrics are located over portions of the high-voltage N-wells and P-wells, and a gate dielectric and a gate conductor are formed over the channel region between the high-voltage P-well and the high-voltage N-well. Source and drain regions for the transistor are located in the high-voltage P-well and high-voltage N-well. Optionally, a P field ring is formed in the N-well region under the field dielectric. In another embodiment, a lateral power superjunction MOSFET with partition regions located in the high-voltage N-well is manufactured with an extended drift region.

Abstract: A semiconductor structure with high-voltage sustaining capability. A semiconductor structure with high-voltage sustaining capability includes a first well region of a first conductivity type. A pair of second well regions of a second conductivity type opposite to the first conductivity type are respectively disposed adjacent to the first well region and an anti-punch through region of the first conductivity type is disposed in at least the lower portion of the first well region to increase the doping concentration therein. Due to the ion supplementation of the anti-punch through region, the size of a semiconductor structure can be further reduced without affecting the HV sustaining capability and undesired effects such as punch-through effects can be prevented.

Abstract: A high-voltage MOS device includes a first high-voltage well (HVW) region overlying a substrate, a second HVW region overlying the substrate, a third HVW region of an opposite conductivity type as that of the first and the second HVW regions overlying the substrate, wherein the HVPW region has at least a portion between the first HVNW region and the second HVNW region, an insulation region in the first HVNW region, the second HVNW region, and the HVPW region, a gate dielectric over and extending from the first HVNW region to the second HVNW region, a gate electrode on the gate dielectric, and a shielding pattern electrically insulated from the gate electrode over the insulation region. Preferably, the gate electrode and the shielding pattern have a spacing of less than about 0.4 ?m. The shielding pattern is preferably connected to a voltage lower than a stress voltage applied on the gate electrode.

Abstract: A semiconductor structure with high-voltage sustaining capability. A semiconductor structure with high-voltage sustaining capability includes a first well region of a first conductivity type. A pair of second well regions of a second conductivity type opposite to the first conductivity type are respectively disposed adjacent to the first well region and an anti-punch through region of the first conductivity type is disposed in at least the lower portion of the first well region to increase the doping concentration therein. Due to the ion supplementation of the anti-punch through region, the size of a semiconductor structure can be further reduced without affecting the HV sustaining capability and undesired effects such as punch-through effects can be prevented.

Abstract: A semiconductor device includes a substrate having a source, a drain, and a gate between the source and the drain. Both the source and the drain include a first edge, and the gate includes a first portion. A first deep trench structure is situated under the first portion of the gate and proximate to the first edge of the source and the first edge of the drain.

Abstract: A transistor suitable for high-voltage applications is provided. The transistor is formed on a substrate having a deep well of a first conductivity type. A first well of the first conductivity type and a second well of a second conductivity type are formed such that they are not immediately adjacent each other. The well of the first conductivity type and the second conductivity type may be formed simultaneously as respective wells for low-voltage devices. In this manner, the high-voltage devices may be formed on the same wafer as low-voltage devices with fewer process steps, thereby reducing costs and process time. A doped isolation well may be formed adjacent the first well on an opposing side from the second well to provide further device isolation.

Abstract: A high voltage device with retrograde well is disclosed. The device comprises a substrate, a gate region formed on the substrate, and a retrograde well placed in the substrate next to the gate region, wherein the retrograde well reduces a dopant concentration on the surface of the substrate, thereby minimizing damages to the gate region.

Abstract: A transistor of an integrated circuit is provided. A first doped well region is formed in a well layer at a first active region. At least part of the first doped well region is adjacent to a gate electrode of the transistor. A recess is formed in the first doped well region, and the recess preferably has a depth of at least about 500 angstroms. A first isolation portion is formed on an upper surface of the well layer at least partially over an isolation region. A second isolation portion is formed at least partially in the recess of the first doped well region. At least part of the second isolation portion is lower than the first isolation portion. A drain doped region is formed in the recess of the first doped well region. The second isolation portion is located between the gate electrode and the drain doped region.

Abstract: A semiconductor device includes a substrate having a source, a drain, and a gate between the source and the drain. Both the source and the drain include a first edge, and the gate includes a first portion. A first deep trench structure is situated under the first portion of the gate and proximate to the first edge of the source and the first edge of the drain.

Abstract: A transistor of an integrated circuit is provided. A first doped well region is formed in a well layer at a first active region. At least part of the first doped well region is adjacent to a gate electrode of the transistor. A recess is formed in the first doped well region, and the recess preferably has a depth of at least about 500 angstroms. A first isolation portion is formed on an upper surface of the well layer at least partially over an isolation region. A second isolation portion is formed at least partially in the recess of the first doped well region. At least part of the second isolation portion is lower than the first isolation portion. A drain doped region is formed in the recess of the first doped well region. The second isolation portion is located between the gate electrode and the drain doped region.

Abstract: A semiconductor structure with high-voltage sustaining capability. A semiconductor structure with high-voltage sustaining capability includes a first well region of a first conductivity type. A pair of second well regions of a second conductivity type opposite to the first conductivity type are respectively disposed adjacent to the first well region and an anti-punch through region of the first conductivity type is disposed in at least the lower portion of the first well region to increase the doping concentration therein. Due to the ion supplementation of the anti-punch through region, the size of a semiconductor structure can be further reduced without affecting the HV sustaining capability and undesired effects such as punch-through effects can be prevented.

Abstract: A semiconductor device. The semiconductor device comprises an isolation structure and two heavily doped regions of a second conductivity type spaced apart from each other by the isolation structure. The isolation structure comprises an isolation region in a semiconductor substrate and a heavily doped region of the first conductivity type. The isolation region has an opening and the heavily doped region of the first conductivity type is substantially surrounded by the opening of the isolation region.

Abstract: A programmable memory circuit and a method for programming the same are disclosed. A polycrystalline silicon resistor pair are used in a programmable memory cell. The pair includes a first polycrystalline silicon resistor stressable by a predetermined current thereacross, and a second polycrystalline silicon resistor similarly structured as the first polycrystalline silicon resistor stressable by the predetermined current, wherein when only the first resistor is stressed by the predetermined current, a resistance of the first resistor is lowered as compared to the unstressed second resistor, thereby programming the memory cell.

Abstract: In one embodiment, the disclosure relates to a method and apparatus for surface recovery of a polymer insulation layer through implantation. The method includes providing a substrate having thereon a conductive pad and an insulation layer, optionally processing the conductive pad to remove oxide layer formed on the conductive pad and conducting ion implantation to recover dielectric properties of the insulation layer.

Abstract: A transistor of an integrated circuit is provided. A first doped well region is formed in a well layer at a first active region. At least part of the first doped well region is adjacent to a gate electrode of the transistor. A recess is formed in the first doped well region, and the recess preferably has a depth of at least about 500 angstroms. A first isolation portion is formed on an upper surface of the well layer at least partially over an isolation region. A second isolation portion is formed at least partially in the recess of the first doped well region. At least part of the second isolation portion is lower than the first isolation portion. A drain doped region is formed in the recess of the first doped well region. The second isolation portion is located between the gate electrode and the drain doped region.

Abstract: A high voltage device with retrograde well is disclosed. The device comprises a substrate, a gate region formed on the substrate, and a retrograde well placed in the substrate next to the gate region, wherein the retrograde well reduces a dopant concentration on the surface of the substrate, thereby minimizing damages to the gate region.

Abstract: A semiconductor device includes a substrate having a source, a drain, and a gate between the source and the drain. Both the source and the drain include a first edge, and the gate includes a first portion. A first deep trench structure is situated under the first portion of the gate and proximate to the first edge of the source and the first edge of the drain.

Abstract: A programmable memory circuit and a method for programming the same are disclosed. A polycrystalline silicon resistor pair are used in a programmable memory cell. The pair includes a first polycrystalline silicon resistor stressable by a predetermined current thereacross, and a second polycrystalline silicon resistor similarly structured as the first polycrystalline silicon resistor stressable by the predetermined current, wherein when only the first resistor is stressed by the predetermined current, a resistance of the first resistor is lowered as compared to the unstressed second resistor, thereby programming the memory cell.

Abstract: A method of forming gate dielectric layers with various thicknesses on a substrate. At least a first active region and a second active region are provided on the substrate. A first thermal oxide layer is formed on the substrate. A blanket dielectric layer with a first thickness is deposited overlying the substrate. The dielectric layer and the underlying first thermal oxide layer on the second active region are removed to expose the substrate. A second thermal oxide layer with a second thickness less than the first thickness is formed on the second active region. A first gate is formed on the dielectric layer on the first active region and a second gate is formed on the second thermal oxide layer on the second active region.

Abstract: A new method is provided for the creation of a solder bump. Conventional methods are initially followed, creating a patterned layer of Under Bump Metal over the surface of a contact pad. A layer of photoresist is next deposited, this layer of photoresist is patterned and developed creating a resist mask having a T-shape opening aligned with the contact pad. This T-shaped opening is filled with a solder compound, creating a T-shaped layer of solder compound on the surface of the layer of UBM. The layer of photoresist is removed, exposing the created T-shaped layer of solder compound, further exposing the layer of UBM. The layer of UBM is etched using the T-shaped layer of solder compound as a mask. Reflow of the solder compound results in creating a solder ball.