The present invention discloses a method for transferring a micro LED that is capable of easily mounting a micro LED or a nano LED on a desired position on a substrate by using an electric field.

Embodiments are related to systems and methods for fluidic assembly, and more particularly to systems and methods for increasing the efficiency of fluidic assembly.

The present disclosure relates to an assembly substrate used for a display device manufacturing method in which semiconductor light-emitting diodes are placed on the assembly substrate at preset positions using electric field and magnetic field. Specifically, the assembly substrate includes a base portion, a plurality of assembly electrodes extending in one direction and disposed on the base portion, a dielectric layer stacked on the base portion to cover the assembly electrodes, a barrier wall formed on the base portion and having a plurality of recesses for guiding the semiconductor light-emitting diodes to the preset positions, and a metal shielding layer formed on the base portion, wherein the metal shielding layer overlaps the barrier wall so that an electric field formed between the assembly electrodes is shielded.

Discussed is a self-assembly apparatus of a semiconductor light emitting device, the self-assembly apparatus including a fluid chamber configured to accommodate a plurality of semiconductor light emitting devices, each semiconductor light emitting device having a magnetic body; a magnet disposed to be spaced apart from the fluid chamber and configured to apply a magnetic force to the plurality of semiconductor light emitting devices; and a position controller connected to the magnet, and configured to control a position of the magnet; and a power supply configured to induce formation of an electric field on a substrate placed at an assembly position so that the plurality of semiconductor light emitting devices are seated at preset positions on the substrate while being moved due to a positional change of the magnet, wherein the position controller transfers the magnet in one direction while rotating the magnet about a rotation axis for the magnet.

A back plate for rapid and fluid-assisted assembly of micro light emitting elements thereon includes a substrate with a driving circuit, and blocking walls made to protrude from a top surface of the substrate. The top surface of the substrate defines grooves for accommodating and powering micro light emitting elements. Each of the blocking walls semi-surrounds one groove and defines a notch. The notches defined by each blocking wall all face a single direction and the blocking walls and notches impede and gather micro light emitting elements which are made to flow in a fluid suspension and render them much more likely to tumble into the groove. A method for fluid-assisted assembly is also disclosed.

A light emitting device includes: a substrate; a first electrode and a second electrode on the substrate and spaced apart from each other; a light emitting diode between the first electrode and the second electrode and connected to the first and second electrodes; a first contact on the first electrode; and a second contact on the second electrode. The first contact contacts the first electrode and a first portion of the light emitting diode, and the second contact contacts the second electrode and a second portion of the light emitting diode.

A micro-component comprises a component substrate having a first side and an opposing second side. Fenders project from the first and second sides of the component substrate and include first-side fenders extending from the first side and a second-side fender extending from the second side of the component substrate. At least two of the first-side fenders have a non-conductive surface and are disposed closer to a corner of the component substrate than to a center of the component substrate.

A micro-semiconductor chip wet alignment apparatus is provided. The micro-semiconductor chip wet alignment apparatus includes a semiconductor chip wet supply module configured to supply the plurality of micro-semiconductor chips and a liquid onto the transfer substrate so that the plurality of micro-semiconductor chips are flowable on the transfer substrate; and a chip alignment module including an absorber capable of relative movement along a surface of the transfer substrate and configured to absorb the liquid so that the plurality of micro-semiconductor chips are aligned in the plurality of grooves.

Discussed is a display device including: a substrate; a power wiring and a ground wiring disposed on the substrate and spaced apart from each other; a driving thin film transistor (TFT) disposed on the substrate and having a source terminal electrically connected to the ground wiring; at least one insulating. layer disposed on the substrate; and a pair of assembly electrodes spaced apart from each other between the at least one insulating layer and the substrate, wherein the pair of assembly electrodes is configured to generate an electric field as a voltage is applied to any one of the pair of assembly electrodes.

A cell of fluidic assembly of microchips on a substrate, including: a base having its upper surface intended to receive the substrate; a body laterally delimiting a fluidic chamber above the substrate; and a cover closing the fluidic chamber from its upper surface, wherein the body comprises first and second nozzles respectively emerging onto opposite first and second lateral edges of the fluidic chamber, each of the first and second nozzles being adapted to injecting and/or sucking in a liquid suspension of microchips into and/or from the fluidic chamber, in a direction parallel to the mean plane of the substrate.