Abstract: The disclosure provides a semiconductor structure and a method of forming the same. The semiconductor structure includes a base pattern including a channel region and a drain region, a first semiconductor layer on the channel region of the base pattern, and a gate structure on the first semiconductor layer. The gate structure includes a first stack disposed on the first semiconductor layer and a second stack disposed on the first stack. The first stack includes a first sidewall adjacent to the drain region and a second sidewall opposite to the first sidewall in a first direction parallel to a top surface of the base pattern. The first sidewall is at a first distance from the second stack in the first direction, and the second sidewall is at a second distance from the second stack in the first direction. The first distance is greater than the second distance.

Abstract: An integrated circuit layout comprises a through silicon via (TSV) configured to couple positive operational voltage VDD (VDD TSV), a through silicon via (TSV) configured to couple operational signals (signal TSV), a plurality of through silicon vias (TSVs) configured to couple operational voltage VSS (VSS TSVs) around the VDD TSV and the signal TSV and one or more backside redistribution lines (RDLs) connecting the VSS TSVs together to form a web-like heat dissipating structure at least surrounding the VDD TSV and the signal TSV.

Abstract: A semiconductor device comprises a substrate, a through-silicon via (TSV) penetrating the substrate, a plurality of first interconnect structures, right above the TSV, configured for electrically coupling the TSV to a higher-level interconnect, a second interconnect structure traversing the TSV from the top and being configured for interconnect routing of an active device and a plurality of dummy metal patterns, right above the TSV, electrically isolated from the TSV, the first interconnect structures and the second interconnect structure.

Abstract: A stacked chip system is provided to comprise a first chip, a second chip, a first group of through silicon vias (TSVs) connecting the first chip and second chip and comprising at least one first VSS TSV, at least one first VDD TSV, a plurality of first signal TSVs and at least one first redundant TSV and a second group of through silicon vias (TSVs) connecting the first chip and second chip and comprising at least one second VSS TSV, at least one second VDD TSV, a plurality of second signal TSVs and at least one second redundant TSV, wherein all the first group of TSVs are coupled by a first selection circuitry configured to select the at least one first redundant TSV and bypass at least one of the rest of the first group of TSVs, and wherein the at least one first redundant TSV and the at least second redundant TSV are coupled by a second selection circuitry configured to allow one of them to replace the other.

Abstract: A method for fabricating a through-silicon via comprises the following steps. Provide a substrate. Form a through silicon hole in the substrate having a diameter of at least 1 ?m and a depth of at least 5 ?m. Perform a first chemical vapor deposition process with a first etching/deposition ratio to form a dielectric layer lining the bottom and sidewall of the through silicon hole and the top surface of the substrate. Perform a shape redressing treatment with a second etching/deposition ratio to change the profile of the dielectric layer. Repeat the first chemical vapor deposition process and the shape redressing treatment at least once until the thickness of the dielectric layer reaches to a predetermined value.

Abstract: An integrated circuit layout comprises a through silicon via (TSV) configured to couple positive operational voltage VDD (VDD TSV), a through silicon via (TSV) configured to couple operational signals (signal TSV), a plurality of through silicon vias (TSVs) configured to couple operational voltage VSS (VSS TSVs) around the VDD TSV and the signal TSV and one or more backside redistribution lines (RDLs) connecting the VSS TSVs together to form a web-like heat dissipating structure at least surrounding the VDD TSV and the signal TSV.

Abstract: A stacked integrated circuit system comprises a first chip with first average pattern density comprising memory cells, a second chip with second average pattern density comprising logic circuitries for the memory cells and a functioning unit and a plurality of through-silicon vias within one of the first chip and second chip to electrically connect the first chip and the second chip, wherein the memory cells of the first chip and the logic circuitries of the second chip are designed to be used collectively in order to perform complete memory functions, and wherein the first average pattern density is higher than the second average pattern density.

Abstract: A semiconductor device comprises a substrate having a first side with a first surface and a second side with a second surface, a recessed through silicon via (TSV) penetrating the substrate and forming a first step height with respect to the first surface of the first side, a first extruded backside redistribution line (RDL) filling in the first step height and engaging with the recessed through silicon via.

Abstract: A stacked chip system is provided to comprise a first chip, a second chip, a first group of through silicon vias (TSVs) connecting the first chip and second chip and comprising at least one first VSS TSV, at least one first VDD TSV, a plurality of first signal TSVs and at least one first redundant TSV and a second group of through silicon vias (TSVs) connecting the first chip and second chip and comprising at least one second VSS TSV, at least one second VDD TSV, a plurality of second signal TSVs and at least one second redundant TSV, wherein all the first group of TSVs are coupled by a first selection circuitry configured to select the at least one first redundant TSV and bypass at least one of the rest of the first group of TSVs, and wherein the at least one first redundant TSV and the at least second redundant TSV are coupled by a second selection circuitry configured to allow one of them to replace the other.

Abstract: An integrated structure comprises a substrate with a first dielectric layer and a second dielectric cap layer disposed thereon in sequence, a metal gate transistor with a high-k gate dielectric layer on the substrate, a gate electrode embedded within the first dielectric layer and a source/drain within the substrate, a first metal contact penetrating the first dielectric layer and being in direct contact with the source/drain and a through-silicon via penetrating the second dielectric cap layer, the first dielectric layer and the substrate.

Abstract: A semiconductor device with a through-silicon via comprises a substrate with a front side and a backside and a through-silicon via penetrating the substrate with a circular shape on the front side and a corner-rounded rectangular shape on the back side.

Abstract: A semiconductor device comprises a substrate, a through-silicon via (TSV) penetrating the substrate, at least one first interconnect structure traversing the TSV from the top and dividing a region right above the TSV into several sub-regions and being configured for interconnect routing of an active device and a plurality of second interconnect structures occupying the sub-regions right above the TSV and being configured for electrically coupling the TSV to a higher-level interconnect.

Abstract: A semiconductor device comprises a substrate, a through-silicon via (TSV) penetrating the substrate, a plurality of first interconnect structures, right above the TSV, configured for electrically coupling the TSV to a higher-level interconnect, a second interconnect structure traversing the TSV from the top and being configured for interconnect routing of an active device and a plurality of dummy metal patterns, right above the TSV, electrically isolated from the TSV, the first interconnect structures and the second interconnect structure.

Abstract: A method for fabricating a through-silicon via comprises the following steps. Provide a substrate. Form a through silicon hole in the substrate having a diameter of at least 1 ?m and a depth of at least 5 ?m. Perform a first chemical vapor deposition process with a first etching/deposition ratio to form a dielectric layer lining the bottom and sidewall of the through silicon hole and the top surface of the substrate. Perform a shape redressing treatment with a second etching/deposition ratio to change the profile of the dielectric layer. Repeat the first chemical vapor deposition process and the shape redressing treatment at least once until the thickness of the dielectric layer reaches to a predetermined value.

Abstract: A high voltage device is provided. The high voltage device includes a gate on a substrate, two source/drain regions in the substrate beside the gate, and a composite gate dielectric layer that includes at least two stacked continuous layers, extending from one side to another side of the gate. Wherein, the at least two stacked continuous layers is a combination of at least one thermal oxide layer and at least one chemical vapor deposited layer.

Abstract: A silicon-oxide-nitride-oxide-silicon (SONOS) memory and the corresponding forming method are disclosed. The memory includes a plurality of select gate structures arranged in an array, a plurality of charge trap spacers that do not contact each other, and a plurality of word lines. The word lines can directly contact the select gates' surfaces of the select gate structures. All of the select gate structures disposed in one line can share two charge trap spacers, and the two charge trap spacers are disposed on the opposed sidewalls of these select gate structures.

Abstract: A high voltage device is provided. The high voltage device includes a gate on a substrate, two source/drain regions in the substrate beside the gate, and a composite gate dielectric layer that includes at least two stacked continuous layers, extending from one side to another side of the gate. Wherein, the at least two stacked continuous layers is a combination of at least one thermal oxide layer and at least one chemical vapor deposited layer.

Abstract: A high voltage MOS transistor including a substrate, a well, a gate insulation layer, a gate, two drift regions, a channel region, a source/drain region and an isolation structure is provided. The well is disposed in the substrate and the gate insulation layer is disposed over the substrate. The gate is disposed over the gate insulation layer. The two drift regions are in the well at two sides of the gate and the width of the gate is smaller than or equal to that of the drift regions. The channel region is disposed between the drift regions and the width of the channel region is greater than that of the drift regions. The source/drain regions are formed within the drift regions. The isolation structure is disposed inside the drift regions between the source/drain region and the channel region. The drift regions enclose the source/drain regions and the isolation structure.

Abstract: A high-voltage device structure includes a high-voltage device disposed on a semiconductor substrate. The semiconductor includes an active region and an isolation region, and the high-voltage device is disposed in the active region. The high-voltage device structure includes a source diffusion region of a first conductive type, a drain region of the first conductive type, and a gate longer than the source diffusion region and the drain diffusion region so as to form spare regions on both sides of the gate. The isolation region is outside the active region and surrounds the active region. In the isolation region, an isolation ion implantation region of a second conductive type and an extended ion implantation region are disposed to prevent parasitic current from being generating between the source diffusion region and the drain diffusion region.

Abstract: A high voltage MOS transistor including a substrate, a well, a gate insulation layer, a gate, two drift regions, a channel region, a source/drain region and an isolation structure is provided. The well is disposed in the substrate and the gate insulation layer is disposed over the substrate. The gate is disposed over the gate insulation layer. The two drift regions are in the well at two sides of the gate and the width of the gate is greater than or equal to that of the drift regions. The channel region is disposed between the drift regions and the width of the channel region is greater than that of the drift regions. The source/drain regions are formed within the drift regions. The isolation structure is disposed inside the drift regions between the source/drain region and the channel region. The drift regions enclose the source/drain regions and the isolation structure.