Disclosed is a conversion element (1) comprising an active region (13) that is formed by a semiconductor material and includes a plurality of barriers (131) and quantum troughs (132), a plurality of first structural elements (14) on a top face (la) of the conversion element (1), and a plurality of second structural elements (15) and/or third structural elements (16) which are arranged on a face of the active region (13) facing away from the plurality of first structural elements (14). Also disclosed is a method for producing a conversion element of said type.

Disclosed is a conversion element (1) comprising an active region (13) that is formed by a semiconductor material and includes a plurality of barriers (131) and quantum troughs (132), a plurality of first structural elements (14) on a top face (la) of the conversion element (1), and a plurality of second structural elements (15) and/or third structural elements (16) which are arranged on a face of the active region (13) facing away from the plurality of first structural elements (14). Also disclosed is a method for producing a conversion element of said type.

A light emitting diode includes an n-type nitride semiconductor layer, a V-pit generation layer located over the n-type nitride semiconductor layer and having a V-pit, an active layer located on the V-pit generation layer, and a p-type nitride semiconductor layer located on the active layer. The active layer includes a well layer, which includes a first well layer portion formed along a flat surface of the V-pit generation layer and a second well layer portion formed in the V-pit of the V-pit generation layer. The light emitting diode emits light having at least two peak wavelengths at a single chip level.

A light emitting diode includes an n-type nitride semiconductor layer, a V-pit generation layer located over the n-type nitride semiconductor layer and having a V-pit, an active layer located on the V-pit generation layer, and a p-type nitride semiconductor layer located on the active layer. The active layer includes a well layer, which includes a first well layer portion formed along a flat surface of the V-pit generation layer and a second well layer portion formed in the V-pit of the V-pit generation layer. The light emitting diode emits light having at least two peak wavelengths at a single chip level.

A quantum device includes a substrate including a first material and including an upper surface thereof, a first layer comprising a compound of the first material disposed on the upper surface of the substrate, a second layer, comprising a metal oxide, disposed on the first layer, a third layer, comprising a noble metal, disposed on the second layer, a fourth layer, comprising a metal oxide, disposed on the third layer, a fifth layer, comprising a piezoelectric material, disposed on the fourth layer, a sixth layer, comprising a noble metal, disposed on the fifth layer, a seventh layer, comprising a material capable of quantum emission, disposed on the sixth layer, and an eighth layer, comprising a noble metal, disposed on the seventh layer, and at least one of the eighth layer and the seventh layer are sized to enable quantum emission from the seventh layer.

A quantum device includes a substrate including a first material and including an upper surface thereof, a first layer comprising a compound of the first material disposed on the upper surface of the substrate, a second layer, comprising a metal oxide, disposed on the first layer, a third layer, comprising a noble metal, disposed on the second layer, a fourth layer, comprising a metal oxide, disposed on the third layer, a fifth layer, comprising a piezoelectric material, disposed on the fourth layer, a sixth layer, comprising a noble metal, disposed on the fifth layer, a seventh layer, comprising a material capable of quantum emission, disposed on the sixth layer, and an eighth layer, comprising a noble metal, disposed on the seventh layer, and at least one of the eighth layer and the seventh layer are sized to enable quantum emission from the seventh layer.

An epitaxial structure includes a quantum well structure, a first type semiconductor layer, and a second type semiconductor layer. The quantum well structure has an upper surface and a lower surface opposite to each other and includes at least one quantum well layer and at least one quantum barrier layer stacked alternately. The quantum well layer includes at least one patterned layer, and the patterned layer includes multiple geometric patterns. The first type semiconductor layer is disposed on the lower surface of the quantum well structure. The second type semiconductor layer is disposed on the upper surface of the quantum well structure.

An epitaxial structure includes a quantum well structure, a first type semiconductor layer, and a second type semiconductor layer. The quantum well structure has an upper surface and a lower surface opposite to each other and includes at least one quantum well layer and at least one quantum barrier layer stacked alternately. The quantum well layer includes at least one patterned layer, and the patterned layer includes multiple geometric patterns. The first type semiconductor layer is disposed on the lower surface of the quantum well structure. The second type semiconductor layer is disposed on the upper surface of the quantum well structure.

An epitaxial wafer of a light-emitting chip, a method for manufacturing an epitaxial wafer, and a light-emitting chip are provided. A light-emitting layer (5) of an active region of the epitaxial wafer of the light-emitting chip includes at least one superlattice (51), and each superlattice includes: a quantum well sub-layer (511) and a stress conversion sub-layer (512) which is formed on the quantum well sub-layer (511) and enables the quantum well sub-layer (511) to be converted from compressive strain to tensile strain, and the stress conversion sub-layer (512) and the quantum well sub-layer (511) form a two-dimensional electron gas.

An epitaxial wafer of a light-emitting chip, a method for manufacturing an epitaxial wafer, and a light-emitting chip are provided. A light-emitting layer (5) of an active region of the epitaxial wafer of the light-emitting chip includes at least one superlattice (51), and each superlattice includes: a quantum well sub-layer (511) and a stress conversion sub-layer (512) which is formed on the quantum well sub-layer (511) and enables the quantum well sub-layer (511) to be converted from compressive strain to tensile strain, and the stress conversion sub-layer (512) and the quantum well sub-layer (511) form a two-dimensional electron gas.