Abstract: Semiconductor devices and methods of forming the devices are provided. Semiconductor devices include a semiconductor layer structure comprising a trench in an upper surface thereof, a dielectric layer in a lower portion of the trench, and a gate electrode in the trench and on the dielectric layer opposite the semiconductor layer structure. The trench may include rounded upper corner and a rounded lower corner. A center portion of a top surface of the dielectric layer may be curved, and the dielectric layer may be on opposed sidewalls of the trench. The dielectric layer may include a bottom dielectric layer on a bottom surface of the trench and on lower portions of the sidewalls of the trench and a gate dielectric layer on upper portions of the sidewalls of the trench and on the bottom dielectric layer.

Abstract: A power semiconductor device comprises a semiconductor layer structure having a wide band-gap drift region having a first conductivity type, a gate trench having first and second opposed sidewalls that extend in a first direction in an upper portion of the semiconductor layer structure, first and second well regions having a second conductivity type in the upper portion of the semiconductor layer structure, the first well region comprising part of the first sidewall and the second well region comprising part of the second sidewall. A deep shielding region having the second conductivity type is provided underneath the gate trench, and a plurality of deep shielding connection patterns that have the second conductivity type are provided that electrically connect the deep shielding region to the first and second well regions. The deep shielding connection patterns are spaced apart from each other along the first direction.

Abstract: A power semiconductor device comprises a semiconductor layer structure comprising a drift region that comprises a wide band-gap semiconductor material that has a first conductivity type, a well region that has a second conductivity type, and a source region that has the first conductivity type in an upper portion of the well region and a gate trench in an upper portion of the semiconductor layer structure and comprising a portion obliquely angled in plan view. Sidewalls of the gate trench may extend along substantially the same crystal plane in the semiconductor layer structure.

Abstract: Semiconductor devices and methods of forming a semiconductor device that includes a polysilicon layer that may improve device reliability and/or a functioning of the device. An example device may include a wide band-gap semiconductor layer structure including a drift region that has a first conductivity type; a plurality of gate trenches in an upper portion of the semiconductor layer structure, each gate trench having a bottom surface, a first sidewall, a second sidewall, and an upper opening; and a plurality of polysilicon layers, each polysilicon layer on the second sidewall of a respective gate trench.

Abstract: Semiconductor devices and methods of forming a semiconductor device that includes a deep shielding pattern that may improve a reliability and/or a functioning of the device. An example method may include forming a wide band-gap semiconductor layer structure on a substrate, the semiconductor layer structure including a drift region that has a first conductivity type; forming a plurality of gate trenches in an upper portion of the semiconductor layer structure, the gate trenches spaced apart from each other, each gate trench having a bottom surface, a first sidewall, a second sidewall, and an upper opening; forming an obstruction over a portion of each gate trench that partially obscures the upper opening; and implanting dopants having a second conductivity type that is opposite the first conductivity type into the bottom surfaces of the gate trenches, where the dopants implanted into the bottom surface of the gate trenches form deep shielding patterns.

Abstract: A vertical field effect device having a body, gate dielectric, and a gate electrode, which is in a trench that extends into the body from the top surface of the body and is located between first and second source regions. The first and second regions vertically overlap the gate electrode. The first and second channel regions laterally overlap a bottom of the gate electrode, such that each channel formed in the first and second source regions have a horizontal segment where the first and second channel regions laterally overlap the bottom of the gate electrode. In another embodiment, the first and second channel regions also vertically overlap the gate electrode such that each channel formed in the first and second source regions also have a vertical segment where the first and second channel regions vertically overlap the gate electrode.

Abstract: Embodiments of the present invention are directed to various methods for generating airway and lung progenitors and epithelial cells and three-dimensional anterior foregut spheres, and to populations of cells made using the methods. The airway and lung progenitors and epithelial cells can be used as a model to study diseases that primarily affect airway epithelial cells, and to study human lung development. Methods are also provided for drug screening. Anterior foregut spheres can be used as a model for lung fibrosis.

Abstract: Embodiments of the present invention are directed to various methods for generating airway and lung progenitors and epithelial cells and three-dimensional anterior foregut spheres, and to populations of cells made using the methods. The airway and lung progenitors and epithelial cells can be used as a model to study diseases that primarily affect airway epithelial cells, and to study human lung development. Methods are also provided for drug screening. Anterior foregut spheres can be used as a model for lung fibrosis.