A method of restricting a micro device on a conductive pad is provided. The method includes: forming the conductive pad having a first lateral length on a substrate; forming a liquid layer on the conductive pad; and placing the micro device having a second lateral length over the conductive pad such that the micro device is in contact with the liquid layer and is gripped by a capillary force produced by the liquid layer between the micro device and the conductive pad, the micro device comprising an electrode facing the conductive pad, wherein the first lateral length is less than or equal to twice of the second lateral length.

A method of liquid assisted bonding includes: forming a structure with a liquid layer between an electrode of a device and a contact pad of a substrate, and two opposite surfaces of the liquid layer being respectively in contact with the electrode and the contact pad in which hydrogen bonds are formed between the liquid layer and at least one of the electrode and the contact pad; and evaporating the liquid layer to break said hydrogen bonds such that at least one of a surface of the electrode facing the contact pad and a surface of the contact pad facing the electrode is activated so as to assist a formation of a diffusion bonding between the electrode of the device and the contact pad in which a contact area between the electrode and the contact pad is smaller than or equal to about 1 square millimeter.

Light emitting devices and methods for their manufacture are provided. According to one aspect, a light emitting device is provided that comprises a substrate having a recess, and an interlayer dielectric layer located on the substrate. The interlayer dielectric layer may have a first hole and a second hole, the first hole opening over the recess of the substrate. The light emitting device may further include first and second micro LEDs, the first micro LED having a thickness greater than the second micro LED. The first micro LED and the second micro LED may be placed in the first hole and the second hole, respectively.

A semiconductor device includes a semiconductor element, a first lead supporting the semiconductor element, a second lead separated from the first lead, and a connection lead electrically connecting the semiconductor element to the second lead. The connection lead has an end portion soldered to the second lead. This connection-lead end portion has a first surface facing the semiconductor element and a second surface opposite to the first surface. The second lead is formed with a recess that is open toward the semiconductor element. The recess has a side surface facing the second surface of the connection-lead end portion. A solder contact area of the second surface of the connection-lead end portion is larger than a solder contact area of the first surface of the connection-lead end portion.

A method of liquid assisted binding is provided. The method includes: forming a conductive pad on the substrate; placing a micro device on the conductive pad, such that the micro device is in contact with the conductive pad in which the micro device comprises an electrode facing the conductive pad; forming a liquid layer on the micro device and the substrate after said placing, such that a part of the liquid layer penetrates between the micro device and the conductive pad, and the micro device is gripped by a capillary force produced by said part of the liquid layer; and evaporating the liquid layer such that the electrode is bound to the conductive pad and is in electrical connection with the conductive pad.

First and second contacts are formed on first and second wafers from disparate first and second conductive materials, at least one of which is subject to surface oxidation when exposed to air. A layer of oxide-inhibiting material is disposed over a bonding surface of the first contact and the first and second wafers are positioned relative to one another such that a bonding surface of the second contact is in physical contact with the layer of oxide-inhibiting material. Thereafter, the first and second contacts and the layer of oxide-inhibiting material are heated to a temperature that renders the first and second contacts and the layer of oxide-inhibiting material to liquid phases such that at least the first and second contacts alloy into a eutectic bond.

The device and method according to the invention are used to transfer an electronic ferromagnetic component from a carrier to a substrate using a magnetic assembly. The magnetic assembly is designed and arranged to aid in the correct positioning of the at least partly ferromagnetic electronic component on the substrate. The magnetic field generated by the magnetic assembly produces a magnetic force oriented from the carrier towards the substrate, said magnetic force aiding the transfer of the component from the carrier to the substrate such that a significantly increased positioning accuracy of the component is achieved compared to a transfer without said magnetic force.

A display device includes a first substrate that includes a first electrode, a second substrate disposed under the first substrate and that includes, a second electrode that overlaps the first electrode, and an anisotropic conductive film disposed between the first substrate and the second substrate. The anisotropic conductive film includes an insulating resin layer and a plurality of conductive particles in the insulating resin layer. The conductive particles include first conductive particles that overlap the first electrode and the second electrode, and second conductive particles other than the first conductive particles. Each of the first conductive particles and the second conductive particles includes a first flat surface, a second flat surface that faces the first flat surface, and a curved surface rounded between the first flat surface and the second flat surface.

A method of liquid assisted bonding includes: forming a structure with a liquid layer between an electrode of a device and a contact pad of a substrate, and two opposite surfaces of the liquid layer being respectively in contact with the electrode and the contact pad in which hydrogen bonds are formed between the liquid layer and at least one of the electrode and the contact pad; and evaporating the liquid layer to break said hydrogen bonds such that at least one of a surface of the electrode facing the contact pad and a surface of the contact pad facing the electrode is activated so as to assist a formation of a diffusion bonding between the electrode of the device and the contact pad in which a contact area between the electrode and the contact pad is smaller than or equal to about 1 square millimeter.

A manufacturing method of the light-emitting diode package structure is provided. A carrier is formed. The carrier comprises a first build-up circuit. At least one self-assembled material layer is formed on the first build-up circuit. A first solder mask layer is formed on the first build-up circuit. The first solder mask layer has at least one opening to expose a portion of the at least one self-assembled material layer. At least one light-emitting diode is disposed on the first build-up circuit. The at least one light-emitting diode has a self-assembled pattern, and the at least one light-emitting diode is self-assembled into the at least one opening of the first solder mask layer through a force between the self-assembled pattern and the at least one self-assembled material layer.