A semiconductor device includes a semiconductor base body, and a first main electrode and a second main electrode provided on the semiconductor base body. The semiconductor base body includes a drift region of a first conductivity type through which a main current flows, a column region of a second conductivity type arranged adjacent to the drift region in parallel to a current passage of the main current, a second electrode-connection region of the first conductivity type electrically connected to the second main electrode, and a low-density electric-field relaxation region of the first conductivity type having a lower impurity concentration than the drift region and arranged between the second electrode-connection region and the column region.

Implementations of a semiconductor device may include a trench including a gate and a gate oxide formed therein, the trench extending into a doped pillar of a first conductivity type formed in a substrate material. The device may include a trench channel adjacent to the trench and two doped pillars of a second conductivity type extending on each side of the first conductivity type doped pillar where a ratio of a depth of each of the two second conductivity type doped pillars to a depth of the trench into the substrate material may be at least 1.6 to 1.

According to one aspect of the present disclosure, a semiconductor device includes a substrate; a drift layer of a first conductivity type provided on the substrate; a base layer of a second conductivity type provided above the drift layer on the substrate; a source layer of the first conductivity type provided on an upper surface side of the base layer; a first electrode electrically connected to the source layer; a second electrode provided on the rear surface of the substrate; a gate electrode; a trench gate extending from an upper surface of the substrate to the drift layer; and a first bottom layer of the second conductivity type provided below the trench gate in the drift layer, wherein a first distance between a portion of the first bottom layer where an impurity concentration peaks in a thickness direction and the trench gate is larger than 1 μm.

A semiconductor device includes a semiconductor base body, and a first main electrode and a second main electrode provided on the semiconductor base body. The semiconductor base body includes a drift region of a first conductivity type through which a main current flows, a column region of a second conductivity type arranged adjacent to the drift region in parallel to a current passage of the main current, a second electrode-connection region of the first conductivity type electrically connected to the second main electrode, and a low-density electric-field relaxation region of the first conductivity type having a lower impurity concentration than the drift region and arranged between the second electrode-connection region and the column region.

Methods may include providing a device structure including a well formed in an epitaxial layer, and forming a plurality of shielding layers in the device structure, wherein at least one shielding layer is formed between a pair of adjacent sacrificial gates of a plurality of sacrificial gates. The method may further include forming a contact over the at least one shielding layer, forming a fill layer over the contact, and forming a plurality of trenches into the device structure, wherein at least one trench of the plurality of trenches is formed between a pair of adjacent shielding layers of the plurality of shielding layers, and wherein the at least one trench of the plurality of trenches is defined in part by a sidewall of the fill layer. The method may further include forming a gate structure within the at least one trench of the plurality of trenches.

Self-aligned FET devices and associated fabrication methods are disclosed herein. A disclosed process for forming a FET includes forming a first mask, implanting a deep well region in a drift region using the first mask, forming a spacer in contact with the first mask, and implanting a shallow well region in the drift region using the first mask and the spacer. A disclosed FET includes a drift region, a shallow well region, a deep well region located between the shallow well region and the drift region, and a junction field effect region: in contact with the shallow well region, the drift region, and the deep well region; and having a junction field effect doping concentration of the first conductivity type. The FETs can include a hybrid channel formed by a portion of the junction field effect region, as influenced by the deep well region, and the shallow well region.

A semiconductor device includes a semiconductor base body, and a first main electrode and a second main electrode provided on the semiconductor base body. The semiconductor base body includes a drift region of a first conductivity type through which a main current flows, a column region of a second conductivity type arranged adjacent to the drift region in parallel to a current passage of the main current, a second electrode-connection region of the first conductivity type electrically connected to the second main electrode, and a low-density electric-field relaxation region of the first conductivity type having a lower impurity concentration than the drift region and arranged between the second electrode-connection region and the column region.

Before formation of gate insulating films, an oblique ion implantation of oxygen into opposing sidewalls of trenches, from a top of an oxide film mask is performed, forming oxygen ion-implanted layers in surface regions of the sidewalls. A peak position of oxygen concentration distribution of the oxygen ion-implanted layers is inside the oxide film mask. After removal of the oxide film mask, HTO films constituting the gate insulating films are formed. During deposition of the HTO films, excess carbon occurring at the start of the deposition of the HTO films and in the gate insulating films reacts with oxygen in the oxygen ion-implanted layers, thereby becoming an oxocarbon and being desorbed. The oxygen ion-implanted layers have a thickness in a direction orthogonal to the sidewalls at most half of the thickness of the gate insulating films, and an oxygen concentration higher than any other portion of the semiconductor substrate.

A silicon carbide semiconductor device includes an electric field relaxation layer disposed in a drift layer. The electric field relaxation layer includes a first region having a second conductivity type and disposed at a position deeper than trenches, and a second region having the second conductivity type and disposed between the adjacent trenches to be away from a side surface of each of the adjacent trenches. Each of the first region and the second region is made of an ion implantation layer. The electric field relaxation layer further includes a double implantation region in which the first region and the second region overlap with each other, and the electric field relaxation layer has a peak of a second conductivity type impurity concentration in the double implantation region.

According to one aspect of the present disclosure, a semiconductor device includes a substrate; a drift layer of a first conductivity type provided on the substrate; a base layer of a second conductivity type provided above the drift layer on the substrate; a source layer of the first conductivity type provided on an upper surface side of the base layer; a first electrode electrically connected to the source layer; a second electrode provided on the rear surface of the substrate; a gate electrode; a trench gate extending from an upper surface of the substrate to the drift layer; and a first bottom layer of the second conductivity type provided below the trench gate in the drift layer, wherein a first distance between a portion of the first bottom layer where an impurity concentration peaks in a thickness direction and the trench gate is larger than 1 μm.