A transistor using patterned metamaterial electrode manipulating electromagnetic waves to achieve matched phase velocity on the input and output ports. A design method is taught wherein the layout of the electrodes can be designed to compensate for the phase-velocity mismatch induced by the transistor's intrinsic properties.

In some embodiments, an optoelectronic semiconductor light emitting device includes: a substrate; and a plurality of epitaxial semiconductor layers disposed on the substrate. Each of the epitaxial semiconductor layers can comprise an epitaxial oxide. At least one of the epitaxial semiconductor layers can comprise an optically emissive material of direct bandgap type. At least one of the epitaxial semiconductor layers can comprise (Al.sub.x1Ga.sub.1−x1).sub.2O.sub.3 wherein 0≤x1≤1. The plurality of epitaxial semiconductor layers can comprise: first region comprising a first conductivity type; a second region comprising a not-intentionally doped (NID) intrinsic region; and a third region comprising a second conductivity type. The substrate and the plurality of epitaxial semiconductor layers can be a substantially single crystal epitaxially formed device. The optoelectronic semiconductor light emitting device can be configured to emit light having a wavelength in a range from 150 nm to 425 nm.

The present disclosure relates to a method for reducing metal contamination on a surface of a substrate. The method involves plasma treatment of the surface of the substrate by ion bombardment, wherein a plasma of a supplied gas is generated, and a bombardment energy of the ions in the plasma is controlled by a radio frequency electromagnetic field. The bombardment energy of the ions is higher than a first threshold so as to tear the metal contamination from the surface of the substrate, and the bombardment energy of the ions is lower than a second threshold so as to prevent a surface quality degradation of the surface of the substrate.

An optoelectronic semiconductor light emitting device configured to emit light having a wavelength in the range from about 150 nm to about 425 nm is disclosed. In embodiments, the device comprises a substrate having at least one epitaxial semiconductor layer disposed thereon, wherein each of the one or more epitaxial semiconductor layers comprises a metal oxide. Also disclosed is an optoelectronic semiconductor device for generating light of a predetermined wavelength comprising a substrate and an optical emission region. The optical emission region has an optical emission region band structure configured for generating light of the predetermined wavelength and comprises one or more epitaxial metal oxide layers supported by the substrate.

An optoelectronic semiconductor light emitting device configured to emit light having a wavelength in the range from about 150 nm to about 425 nm is disclosed. In embodiments, the device comprises a substrate having at least one epitaxial semiconductor layer disposed thereon, wherein each of the one or more epitaxial semiconductor layers comprises a metal oxide. Also disclosed is an optoelectronic semiconductor device for generating light of a predetermined wavelength comprising a substrate and an optical emission region. The optical emission region has an optical emission region band structure configured for generating light of the predetermined wavelength and comprises one or more epitaxial metal oxide layers supported by the substrate.

A laser annealing apparatus (1) according to the embodiment includes: a laser beam source (11) configured to emit a laser beam (L1) to crystallize an amorphous silicon film (101a) on a substrate (100) and to form a poly-silicon film (101b); a projection lens (13) configured to condense the laser beam to irradiate a silicon film (101); a probe beam source configured to emit a probe beam (L2); a photodetector (25) configured to detect the probe beam (L3) transmitted through the silicon film (101), a processing apparatus (26) configured to calculate a standard deviation of detection values of a detection signal output from the photodetector, and to determine a crystalline state of the crystallized film based on the standard deviation.

Provided is a method for stripping a substrate of a semiconductor structure, including: providing a substrate, a first A1N layer, a first AlGaN layer and a function layer from bottom to top; and irradiating the first AlGaN layer from the substrate with laser light to decompose the first AlGaN layer, such that the function layer is separated from the substrate and the first A1N layer. By the method, the first A1N layer and the first AlGaN layer respectively correspond to a nucleation layer and a buffer layer when the function layer is epitaxially grown, to improve the quality of the function layer.

An optoelectronic semiconductor light emitting device configured to emit light having a wavelength in the range from about 150 nm to about 425 nm is disclosed. In embodiments, the device comprises a substrate having at least one epitaxial semiconductor layer disposed thereon, wherein each of the one or more epitaxial semiconductor layers comprises a metal oxide. An epitaxial semiconductor layer of the device can include a first single crystal oxide material. The first single crystal oxide material can include: at least one of magnesium, nickel, and zinc; at least one of aluminum and gallium; and oxygen. The first single crystal oxide material can also include a cubic crystal symmetry.

An optoelectronic semiconductor light emitting device configured to emit light having a wavelength in the range from about 150 nm to about 425 nm is disclosed. In embodiments, the device comprises a substrate having at least one epitaxial semiconductor layer disposed thereon, wherein each of the one or more epitaxial semiconductor layers comprises a metal oxide. At least one of the epitaxial semiconductor layers can include single crystal A.sub.xB.sub.1-xO.sub.n, where: 0<x<1.0; A is Al and/or Ga; and B is Mg, Ni, a rare earth, Er, Gd, Ir, Bi, or Li.

A semiconductor device includes: a substrate, including an upper surface and a first to a fourth side surfaces; wherein the upper surface includes a first edge connecting the first side surface and a second edge opposite to the first edge and connecting the second side surface; a first modified trace formed on the first side surface; and a semiconductor stack formed on the upper surface, including a lower surface connecting the upper surface of the substrate, and the lower surface comprises a fifth edge adjacent to the first edge and a sixth edge opposite to the fifth edge and adjacent to the second edge; wherein a shortest distance between the first edge and the fifth edge is S1 μm, and a shortest distance between the second edge and the sixth edge is S2 μm; wherein in a lateral view viewing from the third side surface, the first side surface forms a first acute angle with a degree of θ1 with the vertical direction, the second side surface forms a second acute angle with a degree of θ2 with the vertical direction, and a distance between the first modified trace and the upper surface in the vertical direction is D1 μm; and wherein S1, S2, θ1, θ2 and D1 satisfy the equation: D1≤0.2×(S1+S2)/tan θa, wherein θa=(θ1+θ2)/2.