Abstract: An LDMOS includes a semiconductor substrate. A well is disposed within the semiconductor substrate. A body region is disposed within the well. A first gate electrode is disposed on the semiconductor substrate. A source electrode is disposed at one side of the first gate electrode. The source electrode includes a source contact area and numerous vias. The vias connect to the source contact area. The vias extend into the semiconductor substrate. A first drain electrode is disposed at another side of the first gate electrode and is opposed to the source electrode.

Abstract: An LDMOS includes a semiconductor substrate. A well is disposed within the semiconductor substrate. A body region is disposed within the well. A first gate electrode is disposed on the semiconductor substrate. A source electrode is disposed at one side of the first gate electrode. The source electrode includes a source contact area and numerous vias. The vias connect to the source contact area. The vias extend into the semiconductor substrate. A first drain electrode is disposed at another side of the first gate electrode and is opposed to the source electrode.

Abstract: An LDMOS includes a semiconductor substrate. A well is disposed within the semiconductor substrate. A body region is disposed within the well. A first gate electrode is disposed on the semiconductor substrate. A source electrode is disposed at one side of the first gate electrode. The source electrode includes a source contact area and numerous vias. The vias connect to the source contact area. The vias extend into the semiconductor substrate. A first drain electrode is disposed at another side of the first gate electrode and is opposed to the source electrode.

Abstract: An LDMOS includes a semiconductor substrate. A well is disposed within the semiconductor substrate. A body region is disposed within the well. A first gate electrode is disposed on the semiconductor substrate. A source electrode is disposed at one side of the first gate electrode. The source electrode includes a source contact area and numerous vias. The vias connect to the source contact area. The vias extend into the semiconductor substrate. A first drain electrode is disposed at another side of the first gate electrode and is opposed to the source electrode.

Abstract: A method for forming gate structures for a HV device and a MV device is provided. The method includes forming a HV oxide layer on the substrate, covering a first region predetermined for forming the HV device. Further in the method, a dielectric mask is formed on a central portion of the HV oxide layer. A thermal oxidation process is performed to form a MV oxide layer on the substrate at a second region predetermined for forming the MV device, wherein peripheral portions of the HV oxide layer not covered by the dielectric mask grow thicker. The dielectric mask is removed. A conductive layer is formed over the substrate. The conductive layer, the HV oxide layer, the MV oxide layer are patterned to form the gate structures.

Abstract: A method for fabricating a high voltage semiconductor device is provided. Firstly, a substrate is provided, wherein the substrate has a first active zone and a second active zone. Then, a first ion implantation process is performed to dope the substrate by a first mask layer, thereby forming a first-polarity doped region at the two ends of the first active zone and a periphery of the second active zone. After the first mask layer is removed, a second ion implantation process is performed to dope the substrate by a second mask layer, thereby forming a second-polarity doped region at the two ends of the second active zone and a periphery of the first active zone. After the second mask layer is removed, a first gate conductor structure and a second gate conductor structure are formed over the middle segments of the first active zone and the second active zone, respectively.

Abstract: A method for fabricating a high voltage semiconductor device is provided. Firstly, a substrate is provided, wherein the substrate has a first active zone and a second active zone. Then, a first ion implantation process is performed to dope the substrate by a first mask layer, thereby forming a first-polarity doped region at the two ends of the first active zone and a periphery of the second active zone. After the first mask layer is removed, a second ion implantation process is performed to dope the substrate by a second mask layer, thereby forming a second-polarity doped region at the two ends of the second active zone and a periphery of the first active zone. After the second mask layer is removed, a first gate conductor structure and a second gate conductor structure are formed over the middle segments of the first active zone and the second active zone, respectively.