Abstract: A high hole mobility transistor includes a substrate, a back-barrier layer, a conducting layer, a doping layer, a gate electrode, source/drain electrodes, and a band adjustment layer. The back-barrier layer is disposed on the substrate. The conducting layer is disposed on the back-barrier layer. A channel region is disposed in the conducting layer and is adjacent to the interface between the conducting layer and the back-barrier layer. The doping layer is disposed on the conducting layer. The gate electrode is disposed on the doping layer. The source/drain electrodes are disposed on opposite sides of the gate electrode. The band adjustment layer is disposed on the doping layer and electrically connected to the gate electrode. The band adjustment layer is an N-type doped III-V semiconductor.

Abstract: The present disclosure provides a weighting-type data relocation control device for controlling data relocation of a non-volatile memory which includes used blocks and unused blocks. Each used block is associated with a first parameter and a second parameter. The control device executes the following steps: multiplying the first and second parameters by a first and a second weightings respectively to obtain a priority index, in which at least one of the parameters and/or at least one of the weightings relate(s) to a thermal detection result; comparing the priority index with at least a threshold to obtain a comparison result; and if the comparison result corresponding to a used storage block of the used blocks reaches a predetermined threshold, transferring valid data of the used storage block to one of the unused blocks.

Abstract: A high-voltage semiconductor device including a semiconductor layer formed on a substrate is provided. A first well region having a first conductivity type and a second well region having a second conductivity type are formed in the semiconductor layer. Source and drain regions are respectively formed in the first and second well regions. A gate structure is disposed on the semiconductor layer. A first isolation trench structure is disposed in the semiconductor layer and surrounds the first and second well regions. The first isolation trench structure includes a first polysilicon layer filling a first trench and having the second conductivity type, a first heavy doping region formed in an upper portion of the first polysilicon layer and having the second conductivity type, and a first insulating liner disposed on sidewalls of the first trench and surrounding the first polysilicon layer.

Abstract: The present disclosure provides a weighting-type data relocation control device for controlling data relocation of a non-volatile memory which includes used blocks and unused blocks. Each used block is associated with a first parameter and a second parameter. The control device executes the following steps: multiplying the first and second parameters by a first and a second weightings respectively to obtain a priority index, in which at least one of the parameters and/or at least one of the weightings relate(s) to a thermal detection result; comparing the priority index with at least a threshold to obtain a comparison result; and if the comparison result corresponding to a used storage block of the used blocks reaches a predetermined threshold, transferring valid data of the used storage block to one of the unused blocks.

Abstract: A semiconductor structure includes a semiconductor substrate of a first conductivity type; a pre-high-voltage well (pre-HVW) in the semiconductor substrate, wherein the pre-HVW is of a second conductivity type opposite the first conductivity type; a high-voltage well (HVW) over the pre-HVW, wherein the HVW is of the second conductivity type; a field ring in the HVW and occupying a top portion of the HVW, wherein the field ring is of the first conductivity type; an insulation region over and in contact with the field ring and a portion of the HVW; a gate electrode partially over the insulation region; a drain region in the HVW, wherein the drain region is of the second conductivity type; and wherein the HVW horizontally extends further toward the drain region than the pre-HVW; and a source region adjacent to, and on an opposite side of the gate electrode than the drain region.

Abstract: A semiconductor device and its method of manufacture are provided. Embodiments forming an active region in a semiconductor substrate, wherein the active region is bounded by an isolation region; forming a first doped region within the active region; forming a gate electrode over the active region, wherein the gate electrode overlies a portion of the first doped region; forming at least one dielectric layer over sidewalls of the gate electrode; forming a pair of spacers on the dielectric layer; and forming a second doped region substantially within the portion of the first doped region adjacent the one of the spacers and spaced apart from the one of the spacers. The first and second doped regions may form a double diffused drain structure as in an HVMOS transistor.

Abstract: An LDMOS transistor structure and methods of making the same are provided. The structure includes a gate electrode extended on an upper boundary of an extension dielectric region that separates the gate electrode from the drain region of the LDMOS transistor. Moreover, at an area close to an edge of the extended gate electrode portion, the gate electrode further projects downwards into a convex-shaped recess or groove in the upper boundary of the extension dielectric region, forming a tongue. LDMOS transistors with this structure may provide improved suppression of hot carrier effects.

Abstract: A high-voltage metal-oxide-semiconductor (HVMOS) device having increased breakdown voltage and methods for forming the same are provided. The HVMOS device includes a semiconductor substrate; a gate dielectric on a surface of the semiconductor substrate; a gate electrode on the gate dielectric; a source/drain region adjacent and horizontally spaced apart from the gate electrode; and a recess in the semiconductor substrate and filled with a dielectric material. The recess is between the gate electrode and the source/drain region, and is horizontally spaced apart from the gate electrode.

Abstract: A semiconductor structure includes a semiconductor substrate of a first conductivity type; a pre-high-voltage well (pre-HVW) in the semiconductor substrate, wherein the pre-HVW is of a second conductivity type opposite the first conductivity type; a high-voltage well (HVW) over the pre-HVW, wherein the HVW is of the second conductivity type; a field ring in the HVW and occupying a top portion of the HVW, wherein the field ring is of the first conductivity type; an insulation region over and in contact with the field ring and a portion of the HVW; a gate electrode partially over the insulation region; a drain region in the HVW, wherein the drain region is of the second conductivity type; and wherein the HVW horizontally extends further toward the drain region than the pre-HVW; and a source region adjacent to, and on an opposite side of the gate electrode than the drain region.

Abstract: A semiconductor device and its method of manufacture are provided. Embodiments forming an active region in a semiconductor substrate, wherein the active region is bounded by an isolation region; forming a first doped region within the active region; forming a gate electrode over the active region, wherein the gate electrode overlies a portion of the first doped region; forming at least one dielectric layer over sidewalls of the gate electrode; forming a pair of spacers on the dielectric layer; and forming a second doped region substantially within the portion of the first doped region adjacent the one of the spacers and spaced apart from the one of the spacers. The first and second doped regions may form a double diffused drain structure as in an HVMOS transistor.

Abstract: A semiconductor device and its method of manufacture are provided. Embodiments include forming a first doped region and a second doped region. The first and second doped regions may form a double diffused drain structure as in an HVMOS transistor. A gate-side boundary of the first doped region underlies part of the gate electrode. The second doped region is formed within the first doped region adjacent the gate electrode. A gate-side boundary of the second doped region is separated from a closest edge of a gate electrode spacer by a first distance. An isolation region-side boundary of the second doped region is separated from a closest edge of a nearest isolation region by a second distance.

Abstract: A semiconductor structure includes a semiconductor substrate of a first conductivity type; a pre-high-voltage well (pre-HVW) in the semiconductor substrate, wherein the pre-HVW is of a second conductivity type opposite the first conductivity type; a high-voltage well (HVW) over the pre-HVW, wherein the HVW is of the second conductivity type; a field ring in the HVW and occupying a top portion of the HVW, wherein the field ring is of the first conductivity type; an insulation region over and in contact with the field ring and a portion of the HVW; a gate electrode partially over the insulation region; a drain region in the HVW, wherein the drain region is of the second conductivity type; and wherein the HVW horizontally extends further toward the drain region than the pre-HVW; and a source region adjacent to, and on an opposite side of the gate electrode than the drain region.

Abstract: A semiconductor structure includes a semiconductor substrate of a first conductivity type; a pre-high-voltage well (pre-HVW) in the semiconductor substrate, wherein the pre-HVW is of a second conductivity type opposite the first conductivity type; a high-voltage well (HVW) over the pre-HVW, wherein the HVW is of the second conductivity type; a field ring of the first conductivity type occupying a top portion of the HVW, wherein at least one of the pre-HVW, the HVW, and the field ring comprises at least two tunnels; an insulation region over the field ring and a portion of the HVW; a drain region in the HVW and adjacent the insulation region; a gate electrode over a portion the insulation region; and a source region on an opposite side of the gate electrode than the drain region.

Abstract: A transistor suitable for high-voltage applications and a method of manufacture is provided. A first device is formed by depositing a dielectric layer and a conductive layer over a substrate. A hard mask is deposited over the conductive layer and patterned using photolithography techniques. The photoresist material is removed prior to etching the underlying conductive layer and dielectric layer. The hard mask is also used as an implant mask. Another mask may be deposited and formed over the conductive layer to form other devices in other regions of the substrate. The other mask is preferably removed from over the hard mask prior to etching the conductive layer and the dielectric layer.

Abstract: A high-voltage metal-oxide-semiconductor (HVMOS) device and methods for forming the same are provided. The HVMOS device includes a substrate; a first high-voltage n-well (HVNW) region buried in the substrate; a p-type buried layer (PBL) horizontally adjoining the first HVNW region; a second HVNW region on the first HVNW region; a high-voltage p-well (HVPW) region over the PBL; an insulating region at a top surface of the second HVNW region; a gate dielectric extending from over the HVPW region to over the second HVNW region, wherein the gate dielectric has a portion over the insulating region; and a gate electrode on the gate dielectric.

Abstract: A method of fabricating a semiconductor device includes forming in the substrate a well region comprising a first type of dopant; forming in the well region a base region comprising a second type of dopant different from the first type of dopant; and forming in the substrate source and drain regions comprising the first type of dopant. The method further includes forming on the substrate a gate electrode interposed laterally between the source and drain regions; and forming on the substrate a gate spacer disposed laterally between the source region and the gate electrode adjacent a side of the gate electrode and having a conductive feature embedded therein. The well region surrounds the drain region and the base region, and the base region is disposed partially underlying the gate electrode surrounding the source region defining a channel under the gate electrode of having a length substantially less than half the length of the gate electrode.

Abstract: The present invention discloses a semiconductor structure. A buried layer of a first polarity type is constructed on a semiconductor substrate. A first epitaxial layer of a second polarity type is formed on the buried layer. A second epitaxial layer of the second polarity type is formed on the buried layer. An isolation structure of the first polarity type is formed between the first and second epitaxial layers on the buried layer. A first well of the second polarity type is formed on the first epitaxial layer. A second well of the second polarity type is formed on the second epitaxial layer. A third well of the first polarity type is formed between the first and second wells, on the isolation structure. The isolation structure interfaces with the buried layer and the third well, thereby substantially blocking a leakage current path between the first and the second wells.

Abstract: A method of fabricating a semiconductor device includes forming in the substrate a well region comprising a first type of dopant; forming in the well region a base region comprising a second type of dopant different from the first type of dopant; and forming in the substrate source and drain regions comprising the first type of dopant. The method further includes forming on the substrate a gate electrode interposed laterally between the source and drain regions; and forming on the substrate a gate spacer disposed laterally between the source region and the gate electrode adjacent a side of the gate electrode and having a conductive feature embedded therein. The well region surrounds the drain region and the base region, and the base region is disposed partially underlying the gate electrode surrounding the source region defining a channel under the gate electrode of having a length substantially less than half the length of the gate electrode.

Abstract: A semiconductor structure includes a semiconductor substrate of a first conductivity type; a pre-high-voltage well (pre-HVW) in the semiconductor substrate, wherein the pre-HVW is of a second conductivity type opposite the first conductivity type; a high-voltage well (HVW) over the pre-HVW, wherein the HVW is of the second conductivity type; a field ring of the first conductivity type occupying a top portion of the HVW; and a tunnel of the first conductivity type in the pre-HVW and the HVW, and electrically connecting the field ring and the semiconductor substrate.

Abstract: A semiconductor device includes a source region and a drain region disposed in a substrate wherein the source and drain regions have a first type of dopant; a gate electrode formed on the substrate interposed laterally between the source and drain regions; a gate spacer disposed on the substrate and laterally between the source region and the gate electrode, adjacent a side of the gate electrode; and a conductive feature embedded in the gate spacer.