A display apparatus includes a substrate, a light-emitting device provided on the substrate, a driving transistor device configured to control the light-emitting device, a first power supply line electrically connected to a source region of the driving transistor device, a conductive pattern electrically connected to a gate electrode of the driving transistor device, and a second power supply line electrically connected to the first power supply line, wherein the conductive pattern and the first power supply line constitute a first capacitor, and the conductive pattern and the second power supply line constitute a second capacitor, wherein the first capacitor and the second capacitor are connected in parallel.

A micro semiconductor chip, a micro semiconductor structure, and a transfer device are provided. The micro semiconductor chip includes an epitaxial structure, a first-type electrode, a second-type electrode and a top light guide element. The epitaxial structure has a top surface, a bottom surface and a side surface. The top light guide element is disposed on the top surface of the epitaxial structure, wherein the top light guide element has a light extraction surface and a bottom surface, wherein the edge of the light extraction surface completely overlaps the edge of the bottom surface of the top light guide element. The light extraction surface is a curved surface, a combination of at least two curved surfaces, or a combination of at least one curved surface and at least one planar surface.

A micro semiconductor chip, a micro semiconductor structure, and a transfer device are provided. The micro semiconductor chip includes an epitaxial structure, a first-type electrode, a second-type electrode and a top light guide element. The epitaxial structure has a top surface, a bottom surface and a side surface. The top light guide element is disposed on the top surface of the epitaxial structure, wherein the top light guide element has a light extraction surface and a bottom surface, wherein the edge of the light extraction surface completely overlaps the edge of the bottom surface of the top light guide element. The light extraction surface is a curved surface, a combination of at least two curved surfaces, or a combination of at least one curved surface and at least one planar surface.

A semiconductor light-emitting element includes: an n-type semiconductor layer made of an n-type AlGaN-based semiconductor material; an active layer made of an AlGaN-based semiconductor material provided on the n-type semiconductor layer; a p-type semiconductor layer provided on the active layer; a p-side contact electrode made of Rh and in contact with the p-type semiconductor layer; a p-side electrode covering layer made of TiN that covers the p-side contact electrode; a dielectric protective layer that covers the n-type semiconductor layer, the active layer, the p-type semiconductor layer, and the p-side electrode covering layer; and a p-side pad electrode in contact with the p-side electrode covering layer in a p-side opening that extends through the dielectric protective layer on the p-side contact electrode.

A method for manufacturing micro light-emitting diode chips includes the steps of: providing a to-be-divided light-emitting component, which includes a metal substrate and a plurality of micro light-emitting diode dies disposed on the metal substrate to permit the metal substrate to define a to-be-etched region among the micro light-emitting diode dies; and etching the metal substrate to remove the to-be-etched region so as to divide the light-emitting component into a plurality of the micro light-emitting diode chips.

An LED display includes a wafer-level substrate, a first adhesive layer, a plurality of first light-emitting assemblies, and a first conductive structure. The wafer-level substrate includes a plurality of control circuits, each of which has a conductive contact. The first adhesive layer is disposed on the wafer-level substrate. Each first light-emitting assembly includes a plurality of first LED structures disposed on the first adhesive layer. The first conductive structure is electrically connected between the corresponding first LED structure and the control circuit. Thereby, each first light-emitting assembly including a plurality of first LED structures and a wafer-level substrate having a plurality of control circuits can be connected to each other through a first adhesive layer.

An LED display includes a wafer-level substrate, a first adhesive layer, a plurality of first light-emitting assemblies, and a first conductive structure. The wafer-level substrate includes a plurality of control circuits, each of which has a conductive contact. The first adhesive layer is disposed on the wafer-level substrate. Each first light-emitting assembly includes a plurality of first LED structures disposed on the first adhesive layer. The first conductive structure is electrically connected between the corresponding first LED structure and the control circuit. Thereby, each first light-emitting assembly including a plurality of first LED structures and a wafer-level substrate having a plurality of control circuits can be connected to each other through a first adhesive layer.

A method for manufacturing micro light-emitting diode chips includes the steps of: providing a to-be-divided light-emitting component, which includes a metal substrate and a plurality of micro light-emitting diode dies disposed on the metal substrate to permit the metal substrate to define a to-be-etched region among the micro light-emitting diode dies; and etching the metal substrate to remove the to-be-etched region so as to divide the light-emitting component into a plurality of the micro light-emitting diode chips.

The invention provides a light emitting chip comprising a conductive carrier, a semiconductor layer body having a first semiconductor layer, a second semiconductor layer, and a radiation emitting layer, wherein the semiconductor layer has a concave part extending from the surface of the first semiconductor layer through the radiation emitting layer toward the second semiconductor layer; a first electrical connection layer electrically connected between the first semiconductor layer and the first electrode; a second electrical connection layer electrically connected between the second semiconductor layer and the conductive carrier, wherein the second electrical connection layer includes a continuous electrode structure connected to the second semiconductor layer, the continuous electrode structure being constituted by at least a frame structure distributed at the edge of the light emitting chip; and a second electrode electrically connected to the conductive carrier.

The invention provides a light emitting chip comprising a conductive carrier, a semiconductor layer body having a first semiconductor layer, a second semiconductor layer, and a radiation emitting layer, wherein the semiconductor layer has a concave part extending from the surface of the first semiconductor layer through the radiation emitting layer toward the second semiconductor layer; a first electrical connection layer electrically connected between the first semiconductor layer and the first electrode; a second electrical connection layer electrically connected between the second semiconductor layer and the conductive carrier, wherein the second electrical connection layer includes a continuous electrode structure connected to the second semiconductor layer, the continuous electrode structure being constituted by at least a frame structure distributed at the edge of the light emitting chip; and a second electrode electrically connected to the conductive carrier.