In one example, a semiconductor device can comprise a unit substrate comprising a unit conductive structure and a unit dielectric structure, and an electronic component coupled to the unit conductive structure. The unit substrate can comprise a portion of a singulated subpanel substrate of a panel substrate. Other examples and related methods are also disclosed herein.

In one example, a semiconductor device can comprise a unit substrate comprising a unit conductive structure and a unit dielectric structure, and an electronic component coupled to the unit conductive structure. The unit substrate can comprise a portion of a singulated subpanel substrate of a panel substrate. Other examples and related methods are also disclosed herein.

A light emitting diode (LED) includes a n-doped semiconductor material layer, a p-doped semiconductor material layer, an active region disposed between the n-doped semiconductor layer and the p-doped semiconductor layer, and a photonic crystal grating configured to increase the light extraction efficiency of the LED.

This application relates to semiconductor manufacturing, and more particularly to an interconnect structure for semiconductors with an ultra-fine pitch and a forming method thereof. The forming method includes: preparing copper nanoparticles using a vapor deposition device, where coupling parameters of the vapor deposition device are adjusted to control an initial particle size of the copper nanoparticles; depositing the copper nanoparticles on a substrate; invertedly placing a chip with copper pillars as I/O ports on the substrate; and subjecting the chip and the substrate to hot-pressing sintering to enable the bonding.

An apparatus includes a product substrate having a transfer surface, and a semiconductor die defined, at least in part, by a first surface adjoined to a second surface that extends in a direction transverse to the first surface. The transfer surface includes ripples in a profile thereof such that an apex on an individual ripple is a point on a first plane and a trough on the individual ripple is a point on a second plane. The semiconductor die is disposed on the transfer surface between the first plane and the second plane such that the second surface of the semiconductor die extends transverse to the first plane and the second plane.

An apparatus includes a product substrate having a transfer surface, and a semiconductor die defined, at least in part, by a first surface adjoined to a second surface that extends in a direction transverse to the first surface. The transfer surface includes ripples in a profile thereof such that an apex on an individual ripple is a point on a first plane and a trough on the individual ripple is a point on a second plane. The semiconductor die is disposed on the transfer surface between the first plane and the second plane such that the second surface of the semiconductor die extends transverse to the first plane and the second plane.

A method of using an optoelectronic semiconductor stamp to manufacture an optoelectronic semiconductor device comprises the following steps: a preparation step: preparing at least one optoelectronic semiconductor stamp group and a target substrate, wherein each optoelectronic semiconductor stamp group comprises at least one optoelectronic semiconductor stamp, each optoelectronic semiconductor stamp comprises a plurality of optoelectronic semiconductor components disposed on a heat conductive substrate, each optoelectronic semiconductor component has at least one electrode, and the target substrate has a plurality of conductive portions; an align-press step: aligning and attaching at least one optoelectronic semiconductor stamp to the target substrate, so that the electrodes are pressed on the corresponding conductive portions; and a bonding step: electrically connecting the electrodes to the corresponding conductive portions.

A method for manufacturing a semiconductor package structure is provided. The method includes: (a) providing a substrate, wherein an upper surface of the substrate includes a predetermined region and an energy-absorbing region adjacent to the predetermined region; (b) disposing a first device in the predetermined region of the upper surface of the substrate; and (c) bonding the first device to the substrate by irradiating an upper surface of the first device with an energy-beam, wherein a center of the energy-beam is moved toward the energy-absorbing region from a first position before bonding.

A heat assisted flip chip bonding apparatus includes a semiconductor assembly having a substrate and a chip, a heating source and a press and cover assembly having a cover element and press elements. The chip is disposed above the substrate and includes conductors which contact with conductive pads on the substrate. The heating source is provided to emit a heated light which illuminates the chip via an opening of the cover element. The press elements are located between the cover element and the semiconductor assembly and each includes an elastic unit and a pressing unit. Both ends of the elastic unit are connected to the cover element and the pressing unit respectively, and the pressing unit is provided to press a back surface of the chip.

According to an aspect, a manufacturing method of a display device includes: obtaining a first reference position on a surface of a holding substrate based on positions of a plurality of first alignment marks of the holding substrate; and aligning the holding substrate with a transfer destination substrate such that the first reference position on the holding substrate and a second reference position on a surface of the transfer destination substrate coincide. The holding substrate is sectioned into a plurality of first sections and a plurality of second sections when viewed from one direction. Each of the first sections is provided in a part of a gap between the second sections when viewed from the one direction, has a light transmission rate higher than a light transmission rate of the second sections, and forms the first alignment mark through which light passes when viewed from the one direction.