A method of forming a semiconductor structure includes providing a substrate comprising a first material portion and a single crystal silicon layer on the first material portion. The substrate further comprises a major front surface, a major backside surface opposing the major front surface, and a plurality of grooves positioned in the major front surface. A buffer layer is deposited in one or more of the plurality of grooves. A semiconductor material is epitaxially grown over the buffer layer and in the one or more plurality of grooves, the epitaxially grown semiconductor material comprising a hexagonal crystalline phase layer and a cubic crystalline phase structure disposed over the hexagonal crystalline phase.

A semiconductor structure including an anodic aluminum oxide layer is described. The anodic aluminum oxide layer can include a plurality of pores extending to an adjacent surface of the semiconductor structure. A filler material can penetrate at least some of the plurality of pores and directly contact the surface of the semiconductor structure. In an illustrative embodiment, multiple types of filler material at least partially fill the pores of the aluminum oxide layer.

A semiconductor light emitting element includes: an n-type clad layer formed of an n-type aluminum gallium nitride (AlGaN) based semiconductor material; an intermediate layer provided on the n-type clad layer and having a higher oxygen (O) concentration than the n-type clad layer; an active layer provided on the intermediate layer and formed of an AlGaN-based semiconductor material; and a p-type semiconductor layer provided on the active layer. The intermediate layer may contain at least oxygen (O) and aluminum (Al).

A semiconductor device includes a substrate, a flowable dielectric material and a GaN-based semiconductor layer. The substrate has a pit exposed from an upper surface of the substrate, the flowable dielectric material fully fills the pit, and the GaN-based semiconductor layer is disposed over the substrate and the flowable dielectric material.

A light-emitting device comprises a textured substrate comprising a plurality of textured structures, wherein the textured structures and the textured substrate are both composed of sapphire; and a light-emitting stack overlaying the textured substrate, comprising a first conductivity type semiconductor layer, an active layer, and a second conductivity type semiconductor layer, wherein each of the plurality of textured structures comprises a top portion having a first top-view shape, and a bottom portion parallel to the top portion and having a second top-view shape, wherein the first top-view shape comprises a circle or an ellipse, the first top-view shape comprises a first periphery and the second top-view shape comprises a second periphery, the first periphery is enclosed by the second periphery, and various distances are between each of the first periphery and the second periphery.

Vertical solid-state transducers (SSTs) having backside contacts are disclosed herein. An SST in accordance with a particular embodiment can include a transducer structure having a first semiconductor material at a first side of the SST, a second semiconductor material at a second side of the SST opposite the first side, and an active region between the first and second semiconductor materials. The SST can further include first and second contacts electrically coupled to the first and second semiconductor materials, respectively. A portion of the first contact can be covered by a dielectric material, and a portion can remain exposed through the dielectric material. A conductive carrier substrate can be disposed on the dielectric material. An isolating via can extend through the conductive carrier substrate to the dielectric material and surround the exposed portion of the first contact to define first and second terminals electrically accessible from the first side.

A semiconductor chip (100) is provided, having a first semiconductor layer (1), which has a lateral variation of a material composition along at least one direction of extent. Additionally provided is a method for producing a semiconductor chip (100).

Integrated active-matrix multi-color light emitting pixel arrays based displays and methods of fabricating the integrated displays are provided. An example integrated device includes a backplane device and different color light emitting diodes (LEDs) devices arranged in different height planar layers on the backplane device. The backplane device includes at least one backplane having a number of pixel circuits. Each LED device includes an array of LEDs each operable to emit light with a particular color and conductively coupled to respective pixel circuits in the backplane to form active-matrix LED sub-pixels. The different color LED sub-pixels form an array of active-matrix multi-color display pixels. Plug vias can be arranged in different planar layers to conductively couple upper-level LEDs to respective pixel circuits in respective regions over the backplane device. The plug vias can extend from an upper planar layer into a lower planar layer to fix the two planar layers together.

A gallium nitride (GaN) based light emitting diode (LED), wherein light is extracted through a nitrogen face (N-face) of the LED and a surface of the N-face is roughened into one or more hexagonal shaped cones. The roughened surface reduces light reflections occurring repeatedly inside the LED, and thus extracts more light out of the LED. The surface of the N-face is roughened by an anisotropic etching, which may comprise a dry etching or a photo-enhanced chemical (PEC) etching.

A semiconductor device and a method for fabricating the same are provided. The semiconductor device includes: a substrate, a bonding metal layer, a reflective layer, a first conductive layer, an active layer, a second conductive layer, first electrode(s) and second electrode(s). The first electrode(s) extends, from one side of the bonding metal layer away from the substrate, to the first conductive layer, to be connected with the bonding metal layer and the first conductive layer. The second electrode(s) penetrates through the substrate and the bonding metal layer to be in contact with the reflective layer. The semiconductor device, forming a structure sharing the first conductive layer, has more uniform illumination and a higher light extraction rate, and eliminates interferences between pixel units, achieves better uniformity of emitted light wavelength and makes distribution of electric current flowing through different pixel units more even.