A semiconductor device is provided, which has a wide-bandgap semiconductor element, such as a SiC element, and which includes a sensor capable of responding sufficiently to characteristic requirements for protecting and controlling the semiconductor element. The semiconductor device includes a wide-bandgap semiconductor element mounted on a substrate; and a light-receiving element that receives light emitted from the wide-bandgap semiconductor element when the wide-bandgap semiconductor element is in a conduction state.

Described herein are systems incorporating a Casimir cavity, such as an optical Casimir cavity or a plasmon Casimir cavity. The Casimir cavity modifies the zero-point energy density therein as compared to outside of the Casimir cavity. The Casimir cavities are paired in the disclosed systems with product generating devices and the difference in zero-point energy densities is used to directly drive the generation of products, such as chemical reaction products or emitted light.

In a method for making a light-emitting device, a plurality of windows (20) on which light source (10) are mounted is prepared, an block (AG1) in which a plurality of packages (30) are connected in an array is prepared, the window (20) is mounted in each package (30) of the block (AG1) to electrically connect a first pad (25) and a second pad (36) corresponding to each other, and the block (AG1) is separated to obtain the plurality of packages (30) on which the corresponding window (20) are mounted.

A micro-light emitting diode (micro-LED) includes a current aperture to confine the current in a localized region such that the carrier recombination mostly occurs in the localized region to emit photons, thereby reducing the surface recombination and improving the quantum efficiency. The current confinement and localization are achieved using a localized breakthrough of a barrier layer by a localized contact, lightly p-doped active layers to suppress lateral transport of the carriers to the surface region, selective ion implantation, etching, or oxidation of a semiconductor layer, or any combination thereof.

A micro-light emitting diode (micro-LED) includes a current aperture to confine the current in a localized region such that the carrier recombination mostly occurs in the localized region to emit photons, thereby reducing the surface recombination and improving the quantum efficiency. The current confinement and localization are achieved using a localized breakthrough of a barrier layer by a localized contact, lightly p-doped active layers to suppress lateral transport of the carriers to the surface region, selective ion implantation, etching, or oxidation of a semiconductor layer, or any combination thereof.

Described herein are systems incorporating a Casimir cavity, such as an optical Casimir cavity or a plasmon Casimir cavity. The Casimir cavity modifies the zero-point energy density therein as compared to outside of the Casimir cavity. The Casimir cavities are paired in the disclosed systems with product generating devices and the difference in zero-point energy densities is used to directly drive the generation of products, such as chemical reaction products or emitted light.

A silicon chip carrier includes at least two of a photosensitive P-I-N diode, a non-photosensitive P-I-N diode, a photosensitive P-(metal)-N diode, a non-photosensitive P-(metal)-N diode, and a Schottky diode all integrally formed in the same layers of the chip carrier. In some embodiments, diodes formed in the chip carrier provide photovoltaic power and power regulation to a circuit mounted on the chip carrier.

A silicon chip carrier includes at least two of a photosensitive P-I-N diode, a non-photosensitive P-I-N diode, a photosensitive P-(metal)-N diode, a non-photosensitive P-(metal)-N diode, and a Schottky diode all integrally formed in the same layers of the chip carrier. In some embodiments, diodes formed in the chip carrier provide photovoltaic power and power regulation to a circuit mounted on the chip carrier.

A light emitting device includes: a light emitting element; a first reflecting member containing reflecting particles, and covering the upper surface of a base while exposing a light extraction surface of the light emitting element; a first cover member having a lower concentration of reflecting particles than the first reflecting member and covering the first reflecting member and a portion of lateral surfaces of the light emitting element while exposing the light extraction surface of the light emitting element; a second cover member covering a portion of the lateral surfaces of the light emitting element; a second reflecting member surrounding the second cover member in a top view and contacting the second cover member and the first reflecting member; the second reflecting member having a narrow-width portion being in contact with the first reflecting member and a wide-width portion located above the narrow-width portion in a cross-sectional view.

Solid state transducer devices with independently controlled regions, and associated systems and methods are disclosed. A solid state transducer device in accordance with a particular embodiment includes a transducer structure having a first semiconductor material, a second semiconductor material and an active region between the first and second semiconductor materials, the active region including a continuous portion having a first region and a second region. A first contact is electrically connected to the first semiconductor material to direct a first electrical input to the first region along a first path, and a second contact electrically spaced apart from the first contact and connected to the first semiconductor material to direct a second electrical input to the second region along a second path different than the first path. A third electrical contact is electrically connected to the second semiconductor material.