Abstract: A method to form a LDMOS transistor includes forming a gate/source/body opening and a drain opening in a field oxide on a substrate structure, forming a gate oxide in the gate/source/body opening, and forming a polysilicon layer over the substrate structure. The polysilicon layer is anisotropically etched to form polysilicon spacer gates separated by a space in the gate/source/body opening and a polysilicon drain contact in the drain opening. A body region is formed self-aligned about outer edges of the polysilicon spacer gates, a source region is formed self-aligned about inner edges of the polysilicon spacer gates, and a drain region is formed under the polysilicon drain contact and self-aligned with respect to the polysilicon spacer gates. A drift region forms in the substrate structure between the body region and the drain region, and a channel region forms in the body region between the source region and the drift region.

Abstract: A method to form a LDMOS transistor includes forming a gate/source/body opening and a drain opening in a field oxide on a substrate structure, forming a gate oxide in the gate/source/body opening, and forming a polysilicon layer over the substrate structure. The polysilicon layer is anisotropically etched to form polysilicon spacer gates separated by a space in the gate/source/body opening and a polysilicon drain contact in the drain opening. A body region is formed self-aligned about outer edges of the polysilicon spacer gates, a source region is formed self-aligned about inner edges of the polysilicon spacer gates, and a drain region is formed under the polysilicon drain contact and self-aligned with respect to the polysilicon spacer gates. A drift region forms in the substrate structure between the body region and the drain region, and a channel region forms in the body region between the source region and the drift region.

Abstract: A method to form a LDMOS transistor includes forming a gate/source/body opening and a drain opening in a field oxide on a substrate structure, forming a gate oxide in the gate/source/body opening, and forming a polysilicon layer over the substrate structure. The polysilicon layer is anisotropically etched to form polysilicon spacer gates separated by a space in the gate/source/body opening and a polysilicon drain contact in the drain opening. A body region is formed self-aligned about outer edges of the polysilicon spacer gates, a source region is formed self-aligned about inner edges of the polysilicon spacer gates, and a drain region is formed under the polysilicon drain contact and self-aligned with respect to the polysilicon spacer gates. A drift region forms in the substrate structure between the body region and the drain region, and a channel region forms in the body region between the source region and the drift region.

Abstract: A method to form a LDMOS transistor includes forming a gate/source/body opening and a drain opening in a field oxide on a substrate structure, forming a gate oxide in the gate/source/body opening, and forming a polysilicon layer over the substrate structure. The polysilicon layer is anisotropically etched to form polysilicon spacer gates separated by a space in the gate/source/body opening and a polysilicon drain contact in the drain opening. A body region is formed self-aligned about outer edges of the polysilicon spacer gates, a source region is formed self-aligned about inner edges of the polysilicon spacer gates, and a drain region is formed under the polysilicon drain contact and self-aligned with respect to the polysilicon spacer gates. A drift region forms in the substrate structure between the body region and the drain region, and a channel region forms in the body region between the source region and the drift region.

Abstract: A method of forming a lateral DMOS transistor includes performing a low energy implantation using a first dopant type and being applied to the entire device area. The dopants of the low energy implantation are blocked by the conductive gate. The method further includes performing a high energy implantation using a third dopant type and being applied to the entire device area. The dopants of the high energy implantation penetrate the conductive gate and is introduced into the entire device active area including underneath the conductive gate. After annealing, a double-diffused lightly doped drain (DLDD) region is formed from the high and low energy implantations and is used as a drift region of the lateral DMOS transistor. The DLDD region overlaps with the body region at a channel region and interacts with the dopants of the body region to adjust a threshold voltage of the lateral DMOS transistor.

Abstract: A MOS transistor includes a body region of a first conductivity type, a conductive gate and a first dielectric layer, a source region of a second conductivity type formed in the body region, a heavily doped source contact diffusion region formed in the source region, a lightly doped drain region of the second conductivity type formed in the body region where the lightly doped drain region is a drift region of the MOS transistor, a heavily doped drain contact diffusion region of the second conductivity type formed in the lightly doped drain region; and an insulating trench formed in the lightly doped drain region adjacent the drain contact diffusion region. The insulating trench blocks a surface current path in the drift region thereby forming vertical current paths in the drift region around the bottom surface of the trench.

Abstract: A MOS transistor includes a body region of a first conductivity type, a conductive gate and a first dielectric layer, a source region of a second conductivity type formed in the body region, a heavily doped source contact diffusion region formed in the source region, a lightly doped drain region of the second conductivity type formed in the body region where the lightly doped drain region is a drift region of the MOS transistor, a heavily doped drain contact diffusion region of the second conductivity type formed in the lightly doped drain region; and an insulating trench formed in the lightly doped drain region adjacent the drain contact diffusion region. The insulating trench blocks a surface current path in the drift region thereby forming vertical current paths in the drift region around the bottom surface of the trench.

Abstract: A method of forming a lateral DMOS transistor includes performing a low energy implantation using a first dopant type and being applied to the entire device area. The dopants of the low energy implantation are blocked by the conductive gate. The method further includes performing a high energy implantation using a third dopant type and being applied to the entire device area. The dopants of the high energy implantation penetrate the conductive gate and is introduced into the entire device active area including underneath the conductive gate. After annealing, a double-diffused lightly doped drain (DLDD) region is formed from the high and low energy implantations and is used as a drift region of the lateral DMOS transistor. The DLDD region overlaps with the body region at a channel region and interacts with the dopants of the body region to adjust a threshold voltage of the lateral DMOS transistor.