A method for manufacturing a light emitting device includes: preparing a first substrate having an upper surface comprising an element placement region; placing a light emitting element in the element placement region; disposing an uncured, sheet-like light-transmissive member on the light emitting element and bringing an outer edge of a lower surface of the light-transmissive member into contact with an outer upper surface of the element placement region of the first substrate by pressing the light-transmissive member; and disposing a first protrusion portion along an outer edge of an upper surface of the light-transmissive member so that the first protrusion portion extends over the upper surface of the first substrate and the upper surface of the light-transmissive member.

A semiconductor device has a substrate and plurality of first bumps formed over the substrate in an array. An array of second bumps is formed over the substrate on at least two sides of the first bumps. An electrical component is disposed over the first bumps. A package structure is disposed over the substrate and electrical component. The package structure has a horizontal member and legs extending from the horizontal member to form a cavity. The package structure is coupled to the array of second bumps. The package structure includes a material to operate as a heat sink or shielding layer. The shielding layer makes ground connection through the array of second bumps. The first bumps and second bumps have a similar height and width to form in the same manufacturing step. A protective layer, such as conductive epoxy, is disposed over the array of second bumps.

Disclosed is a micro light-emitting component, a micro light-emitting diode, and a transfer layer. The transfer layer has a recess for receiving the micro light-emitting diode to permit the micro light-emitting diode to be retained by the transfer layer, and is transformable from a first state, in which the transfer layer is deformed by the micro light-emitting diode to form the recess, to a second state, in which the micro light-emitting diode received in the recess is retained by the transfer layer. Also disclosed are micro light-emitting component matrix and a method for manufacturing the micro light-emitting component matrix.

The present disclosure provides a package device including a conductive pad, a protecting block, and a redistribution layer. The protecting block is disposed on the conductive pad. The redistribution layer is disposed on the protecting block, and the conductive pad is electrically connected to the redistribution layer through the protecting block.

A light emitting diode includes: a light emitting layer arranged on at least part of a first semiconductor layer, and a second semiconductor layer; a local defect region over a portion of the second semiconductor layer and extending downward to the first semiconductor layer; a metal layer over a portion of the second semiconductor layer; an insulating layer covering the metal layer, the second and first semiconductor layers in the local defect region, with opening structures over the local defect region and the metal layer, respectively; and an electrode structure over the insulating layer and having a first layer and a second layer, and including a first-type electrode region and a second-type electrode region; wherein an upper surface and a lower surface of the first layer are not flat, and a lower surface of the second layer are both flat.

Methods and apparatus to embed host dies in a substrate are disclosed An apparatus includes a first die having a first side and a second side opposite the first side. The first side includes a first contact to be electrically coupled with a second die. The second side includes a second contact. The apparatus further includes a substrate including a metal layer and a dielectric material on the metal layer. The first die is encapsulated within the dielectric material. The second contact of the first die is bonded to the metal layer independent of an adhesive.

The present disclosure relates to a semiconductor chip that includes a substrate, a metal layer, and a number of component portions. Herein, the substrate has a substrate base and a number of protrusions protruding from a bottom surface of the substrate base. The substrate base and the protrusions are formed of a same material. Each of the protrusions has a same height. At least one via hole extends vertically through one protrusion and the substrate base. The metal layer selectively covers exposed surfaces at a backside of the substrate and fully covers inner surfaces of the at least one via hole. The component portions reside over a top surface of the substrate base, such that a certain one of the component portions is electrically coupled to a portion of the metal layer at the top of the at least one via hole.

The present disclosure relates to a semiconductor chip that includes a substrate, a metal layer, and a number of component portions. Herein, the substrate has a substrate base and a number of protrusions protruding from a bottom surface of the substrate base. The substrate base and the protrusions are formed of a same material. Each of the protrusions has a same height. At least one via hole extends vertically through one protrusion and the substrate base. The metal layer selectively covers exposed surfaces at a backside of the substrate and fully covers inner surfaces of the at least one via hole. The component portions reside over a top surface of the substrate base, such that a certain one of the component portions is electrically coupled to a portion of the metal layer at the top of the at least one via hole.

A uniform pressure gang bonding device and fabrication method are presented using an expandable upper chamber with an elastic surface. Typically, the elastic surface is an elastomer material having a Young's modulus in a range of 40 to 1000 kilo-Pascal (kPA). After depositing a plurality of components overlying a substrate top surface, the substrate is positioned over the lower plate, with the top surface underlying and adjacent (in close proximity) to the elastic surface. The method creates a positive upper chamber medium pressure differential in the expandable upper chamber, causing the elastic surface to deform. For example, the positive upper chamber medium pressure differential may be in the range of 0.05 atmospheres (atm) and 10 atm. Typically, the elastic surface deforms between 0.5 millimeters (mm) and 20 mm, in response to the positive upper chamber medium pressure differential.

A uniform pressure gang bonding device and fabrication method are presented using an expandable upper chamber with an elastic surface. Typically, the elastic surface is an elastomer material having a Young's modulus in a range of 40 to 1000 kilo-Pascal (kPA). After depositing a plurality of components overlying a substrate top surface, the substrate is positioned over the lower plate, with the top surface underlying and adjacent (in close proximity) to the elastic surface. The method creates a positive upper chamber medium pressure differential in the expandable upper chamber, causing the elastic surface to deform. For example, the positive upper chamber medium pressure differential may be in the range of 0.05 atmospheres (atm) and 10 atm. Typically, the elastic surface deforms between 0.5 millimeters (mm) and 20 mm, in response to the positive upper chamber medium pressure differential.