Abstract: Semiconductor device has a substrate (50), a buried layer (55), an active area extending from a surface contact to the buried layer, an insulator (130) in a first trench extending towards the buried layer, to isolate the active area, and a second insulator (130) in a second deep trench and extending through the buried layer to isolate the buried layer and the active area from other pails of the substrate. This double trench can help reduce the area needed for the electrical isolation between the active device and the other devices. Such reduction in area can enable greater integration or more cells in a multi cell super-MOS device, and so improve performance parameters such as Ron. The double trench can be manufactured using a first mask to etch both trenches at the same time, and subsequently using a second mask to etch the second deep trench deeper.

Abstract: Semiconductor device has a substrate (50), a buried layer (55), an active area extending from a surface contact to the buried layer, an insulator (130) in a first trench extending towards the buried layer, to isolate the active area, and a second insulator (130) in a second deep trench and extending through the buried layer to isolate the buried layer and the active area from other pails of the substrate. This double trench can help reduce the area needed for the electrical isolation between the active device and the other devices. Such reduction in area can enable greater integration or more cells in a multi cell super-MOS device, and so improve performance parameters such as Ron. The double trench can be manufactured using a first mask to etch both trenches at the same time, and subsequently using a second mask to etch the second deep trench deeper.

Abstract: A semiconductor device has a substrate (50), a buried layer (55), an active area extending from a surface contact to the buried layer, an insulator (130) in a first trench extending towards the buried layer, to isolate the active area, and a second insulator (130) in a second deep trench and extending through the buried layer to isolate the buried layer and the active area from other parts of the substrate. This double trench can help reduce the area needed for the electrical isolation between the active device and the other devices. Such reduction in area can enable greater integration or more cells in a multi cell super-MOS device, and so improve performance parameters such as Ron. The double trench can be manufactured using a first mask to etch both trenches at the same time, and subsequently using a second mask to etch the second deep trench deeper.

Abstract: A semiconductor device has a substrate (50), a buried layer (55), an active area extending from a surface contact to the buried layer, an insulator (130) in a first trench extending towards the buried layer, to isolate the active area, and a second insulator (130) in a second deep trench and extending through the buried layer to isolate the buried layer and the active area from other parts of the substrate. This double trench can help reduce the area needed for the electrical isolation between the active device and the other devices. Such reduction in area can enable greater integration or more cells in a multi cell super-MOS device, and so improve performance parameters such as Ron. The double trench can be manufactured using a first mask to etch both trenches at the same time, and subsequently using a second mask to etch the second deep trench deeper.

Abstract: A method for processing a low ohmic contact structure to a buried conductive layer in or below a device layer forming part of a semiconductor component is presented, whereby first a highly doped region within said device layer reaching said buried conductive layer is realised, this being followed by a step of etching a trench through said highly doped region to a final depth which extends at least to the semiconductor substrate underneath said buried conductive layer. In a variant method this trench is first pre-etched until a predetermined depth, before the highly doped region is provided. A semiconductor structure which is realised by these methods is described as well.

Abstract: A method for processing a low ohmic contact structure to a buried conductive layer in or below a device layer forming part of a semiconductor component is presented, whereby first a highly doped region within said device layer reaching said buried conductive layer is realised, this being followed by a step of etching a trench through said highly doped region to a final depth which extends at least to the semiconductor substrate underneath said buried conductive layer. In a variant method this trench is first pre-etched until a predetermined depth, before the highly doped region is provided.