There is provided an aluminum nitride laminate member including: a sapphire substrate having a base surface on which bumps are distributed periodically, each bump having a height of smaller than or equal to 500 nm; and an aluminum nitride layer provided on the base surface and having a surface on which protrusions are formed above the apices of the bumps.

There is provided an aluminum nitride laminate member including: a sapphire substrate having a base surface on which bumps are distributed periodically, each bump having a height of smaller than or equal to 500 nm; and an aluminum nitride layer grown on the base surface and having a flat surface, there being substantially no voids in the aluminum nitride layer.

There is provided an aluminum nitride laminate member including: a sapphire substrate having a base surface on which bumps are distributed periodically, each bump having a height of smaller than or equal to 500 nm; and an aluminum nitride layer grown on the base surface and having a flat surface, there being substantially no voids in the aluminum nitride layer.

A light-emitting diode (LED) sub-chip and a method of producing the same are provided. The LED sub-chip comprises an epitaxial layer disposed on a growth substrate, where the epitaxial layer comprises a plurality of electrodes. The groove disposed between the LED sub-chip and a second LED sub-chip, where the groove penetrates through the epitaxial layer separating the two sub-chips. The bridge insulating layer at least partially covering a sidewall of the groove, where the sidewall comprises a first surface and a second surface above the first surface, where the texture of the second surface is less granular than a texture of the first surface. The bridge electrode on the bridge insulating layer, where the bridge electrode connects respective electrodes of the two sub-chips at the first surface.

A light-emitting diode (LED) sub-chip and a method of producing the same are provided. The LED sub-chip comprises an epitaxial layer disposed on a growth substrate, where the epitaxial layer comprises a plurality of electrodes. The groove disposed between the LED sub-chip and a second LED sub-chip, where the groove penetrates through the epitaxial layer separating the two sub-chips. The bridge insulating layer at least partially covering a sidewall of the groove, where the sidewall comprises a first surface and a second surface above the first surface, where the texture of the second surface is less granular than a texture of the first surface. The bridge electrode on the bridge insulating layer, where the bridge electrode connects respective electrodes of the two sub-chips at the first surface.

Disclosed is a light-emitting structure including a light-emitting diode and a connecting unit. The light-emitting diode includes an epitaxial laminate, a first electrode, and a second electrode. The epitaxial laminate includes a first type semiconductor layer, a second type semiconductor layer, and a light-emitting layer. The connecting unit is connected to the epitaxial laminate.

An organic light-emitting display panel having a display area and a non-display area surrounding the display area and includes a base substrate, an organic light-emitting layer, a pixel definition layer, and a microlens layer that are located in the display area is disclosed. The organic light-emitting layer is located at a side of the base substrate and includes light-emitting units. The pixel definition layer includes first openings, and each light-emitting unit is located in one of the first openings. The microlens layer is located at a side of the pixel definition layer facing away from the base substrate and includes at least one first microlens. An orthogonal projection of the first microlens on the base substrate is located between orthogonal projections of two adjacent first openings on the base substrate.

An organic light-emitting display panel having a display area and a non-display area surrounding the display area and includes a base substrate, an organic light-emitting layer, a pixel definition layer, and a microlens layer that are located in the display area is disclosed. The organic light-emitting layer is located at a side of the base substrate and includes light-emitting units. The pixel definition layer includes first openings, and each light-emitting unit is located in one of the first openings. The microlens layer is located at a side of the pixel definition layer facing away from the base substrate and includes at least one first microlens. An orthogonal projection of the first microlens on the base substrate is located between orthogonal projections of two adjacent first openings on the base substrate.

Solid-state lighting devices including light-emitting diodes (LEDs) and more particularly contact structures for LED chips are disclosed. LED chips as disclosed herein may include contact structure arrangements that have reduced impact on areas of active LED structures within the LED chips. Electrical connections between an n-contact and an n-type layer may be arranged outside of a perimeter edge or a perimeter corner of the active LED structure. N-contact interconnect configurations are disclosed that form electrical connections between n-contacts and n-type layers of LED chips outside of lateral boundaries of the active LED structures. By electrically contacting n-type layers outside of the lateral boundaries of the active LED structures, LED chips are provided with improved current spreading and improved brightness.

Solid-state lighting devices including light-emitting diodes (LEDs) and more particularly contact structures for LED chips are disclosed. LED chips as disclosed herein may include contact structure arrangements that have reduced impact on areas of active LED structures within the LED chips. Electrical connections between an n-contact and an n-type layer may be arranged outside of a perimeter edge or a perimeter corner of the active LED structure. N-contact interconnect configurations are disclosed that form electrical connections between n-contacts and n-type layers of LED chips outside of lateral boundaries of the active LED structures. By electrically contacting n-type layers outside of the lateral boundaries of the active LED structures, LED chips are provided with improved current spreading and improved brightness.