In a high electron mobility transistor (HEMT), dielectric material may be included between edge portions of a HEMT gate and gate field plates in contact with a HEMT gate electrode. At least some portions of the HEMT gate and HEMT gate electrode remain in direct contact with one another, and the HEMT gate electrode and gate field plates may be further connected to a gate metal.

In a high electron mobility transistor (HEMT), dielectric material may be included between edge portions of a HEMT gate and gate field plates in contact with a HEMT gate electrode. At least some portions of the HEMT gate and HEMT gate electrode remain in direct contact with one another, and the HEMT gate electrode and gate field plates may be further connected to a gate metal.

A semiconductor device, and methods of forming the same. In one example, the semiconductor device includes a trench in a substrate having a top surface, and a shield within the trench. The semiconductor device also includes a shield liner between a sidewall of the trench and the shield, and a lateral insulator over the shield contacting the shield liner. The semiconductor device also includes a gate dielectric layer on an exposed sidewall of the trench between the lateral insulator and the top surface. The lateral insulator may have a minimum thickness at least two times thicker than a maximum thickness of the gate dielectric layer.

A semiconductor device, and methods of forming the same. In one example, the semiconductor device includes a trench in a substrate having a top surface, and a shield within the trench. The semiconductor device also includes a shield liner between a sidewall of the trench and the shield, and a lateral insulator over the shield contacting the shield liner. The semiconductor device also includes a gate dielectric layer on an exposed sidewall of the trench between the lateral insulator and the top surface. The lateral insulator may have a minimum thickness at least two times thicker than a maximum thickness of the gate dielectric layer.

An isolation structure prevents inter-device and intra-device leakage in first and second adjacent semiconductor devices in a substrate. The first and second semiconductor devices each include a gate region and at least one active region. A first channel stop region is configured to surround the first semiconductor device. A second channel stop region is configured to surround the second semiconductor device. A first field plate is located above at least part of the first channel stop region, and overlaps the gate region of the first semiconductor device in a first overlap region. A second field plate is located above at least part of the second channel stop region, and overlaps the gate region of the second semiconductor device in a second overlap region.

An isolation structure prevents inter-device and intra-device leakage in first and second adjacent semiconductor devices in a substrate. The first and second semiconductor devices each include a gate region and at least one active region. A first channel stop region is configured to surround the first semiconductor device. A second channel stop region is configured to surround the second semiconductor device. A first field plate is located above at least part of the first channel stop region, and overlaps the gate region of the first semiconductor device in a first overlap region. A second field plate is located above at least part of the second channel stop region, and overlaps the gate region of the second semiconductor device in a second overlap region.

A power semiconductor device includes a semiconductor body having a drift region of a first conductivity type inside an active region. An edge termination region includes: a guard region of a second conductivity type at a front side of the semiconductor body and surrounding the active region; and a field plate trench structure extending vertically into the body from the front side and at least partially filled with a conductive material that is electrically connected with the guard region and insulated from the body external of the guard region. A first portion of the field plate trench structure at least partially extends into the guard region and is at least partially arranged below a metal layer arranged at the front side. A second portion of the field plate trench structure extends outside of the guard region and surrounds the active area, the metal layer not extending above the second portion.

A power semiconductor device includes a semiconductor body having a drift region of a first conductivity type inside an active region. An edge termination region includes: a guard region of a second conductivity type at a front side of the semiconductor body and surrounding the active region; and a field plate trench structure extending vertically into the body from the front side and at least partially filled with a conductive material that is electrically connected with the guard region and insulated from the body external of the guard region. A first portion of the field plate trench structure at least partially extends into the guard region and is at least partially arranged below a metal layer arranged at the front side. A second portion of the field plate trench structure extends outside of the guard region and surrounds the active area, the metal layer not extending above the second portion.

In a general aspect, a field-effect transistor (FET) can include a semiconductor region, and a trench disposed in the semiconductor region. The FET can also include a trench gate disposed in an upper portion of the trench in an active region of the FET. The FET can further include a conductive runner disposed in a bottom portion of the trench. The conductive runner can be electrically coupled with a drain terminal of the FET. A portion of the conductive runner can be disposed in the active region below the trench gate.

In a general aspect, a field-effect transistor (FET) can include a semiconductor region, and a trench disposed in the semiconductor region. The FET can also include a trench gate disposed in an upper portion of the trench in an active region of the FET. The FET can further include a conductive runner disposed in a bottom portion of the trench. The conductive runner can be electrically coupled with a drain terminal of the FET. A portion of the conductive runner can be disposed in the active region below the trench gate.