An integrated circuit transistor device includes a semiconductor substrate providing a drain, a first doped region buried in the semiconductor substrate providing a body and a second doped region in the semiconductor substrate providing a source. A trench extends into the semiconductor substrate and passes through the first and second doped regions. An insulated polygate region within the trench surrounds a polyoxide region that may have void inclusion. The polygate region is formed by a first gate lobe and second gate lobe on opposite sides of the polyoxide region. A pair of gate contacts are provided at each trench. The pair of gate contacts includes: a first gate contact extending into the first gate lobe at a location laterally offset from the void and a second gate contact extending into the second gate lobe at a location laterally offset from the void.

A method for manufacturing a device may include providing an ultra-high voltage (UHV) component that includes a source region and a drain region, and forming an oxide layer on a top surface of the UHV component. The method may include connecting a low voltage terminal to the source region of the UHV component, and connecting a high voltage terminal to the drain region of the UHV component. The method may include forming a shielding structure on a surface of the oxide layer provided above the drain region of the UHV component, forming a high voltage interconnection that connects to the shielding structure and to the high voltage terminal, and forming a metal routing that connects the shielding structure and the low voltage terminal.

A method for manufacturing a device may include providing an ultra-high voltage (UHV) component that includes a source region and a drain region, and forming an oxide layer on a top surface of the UHV component. The method may include connecting a low voltage terminal to the source region of the UHV component, and connecting a high voltage terminal to the drain region of the UHV component. The method may include forming a shielding structure on a surface of the oxide layer provided above the drain region of the UHV component, forming a high voltage interconnection that connects to the shielding structure and to the high voltage terminal, and forming a metal routing that connects the shielding structure and the low voltage terminal.

A transistor device includes a semiconductor substrate and a gate structure at the upper surface of the substrate. The gate structure is non-planar and includes a metal gate electrode with first and second sidewalls. A first dielectric layer is present over the gate structure. The first dielectric layer includes a first portion that overlies the first sidewall and a second portion that overlies the second sidewall. A portion of a conductive layer over the first dielectric layer forms a field plate with a first portion proximate to the second sidewall of the gate structure. A dielectric sidewall spacer on the first portion of the field plate is formed from a portion of a second dielectric layer, and the dielectric sidewall spacer does not contact the first dielectric layer.

A transistor device includes a semiconductor substrate and a gate structure at the upper surface of the substrate. The gate structure is non-planar and includes a metal gate electrode with first and second sidewalls. A first dielectric layer is present over the gate structure. The first dielectric layer includes a first portion that overlies the first sidewall and a second portion that overlies the second sidewall. A portion of a conductive layer over the first dielectric layer forms a field plate with a first portion proximate to the second sidewall of the gate structure. A dielectric sidewall spacer on the first portion of the field plate is formed from a portion of a second dielectric layer, and the dielectric sidewall spacer does not contact the first dielectric layer.

A transistor structure is provided, the transistor structure comprising a source, a drain, and a gate between the source and the drain. The gate may have a top surface. A first field plate may be between the source and the drain. The first field plate may be L-shaped and having a vertical portion over a horizontal portion. A top surface of the vertical portion of the first field plate may be at least as high as the top surface of the gate. A second field plate, whereby the second field plate may be connected to the gate and the second field plate may partially overlap the horizontal portion of the first field plate.

A transistor structure is provided, the transistor structure comprising a source, a drain, and a gate between the source and the drain. The gate may have a top surface. A first field plate may be between the source and the drain. The first field plate may be L-shaped and having a vertical portion over a horizontal portion. A top surface of the vertical portion of the first field plate may be at least as high as the top surface of the gate. A second field plate, whereby the second field plate may be connected to the gate and the second field plate may partially overlap the horizontal portion of the first field plate.

Placement of a field plate in a field-effect transistor is optimized by using multiple dielectric layers such that a first end of field plate is separated from a channel region of the transistor by a first set of one or more distinct dielectric material layers. A second end of the field plate overlies the channel region and a control electrode from which it is separated by the first set of dielectric layers and one or more additional dielectric layers. Relative positioning of the control electrode and the field plate are determined by a single processing step such that the field plate is self-aligned to the control electrode in order to reduce variations in transistor performance associated with manufacturing process variations.

Placement of a field plate in a field-effect transistor is optimized by using multiple dielectric layers such that a first end of field plate is separated from a channel region of the transistor by a first set of one or more distinct dielectric material layers. A second end of the field plate overlies the channel region and a control electrode from which it is separated by the first set of dielectric layers and one or more additional dielectric layers. Relative positioning of the control electrode and the field plate are determined by a single processing step such that the field plate is self-aligned to the control electrode in order to reduce variations in transistor performance associated with manufacturing process variations.

Placement of a field plate in a field-effect transistor is optimized by using multiple dielectric layers such that a first end of field plate is separated from a channel region of the transistor by a first set of one or more distinct dielectric material layers. A second end of the field plate overlies the channel region and a control electrode from which it is separated by the first set of dielectric layers and one or more additional dielectric layers.