The present disclosure provides a semiconductor device and a preparation method thereof. The semiconductor device comprises: a semiconductor substrate; a passivation layer, arranged on an upper surface of the semiconductor substrate; a protective layer, arranged on an upper surface of the passivation layer, a dummy opening being formed on the protective layer; and, a dummy bump, partially located in the dummy opening and closely attached to the protective layer.

An optical module includes an optical semiconductor chip including a first electrode pad, a second electrode pad, and a third electrode pad arranged between the first electrode pad and the second electrode pad, a wiring substrate on which the optical semiconductor chip is flip-chip mounted, including a fourth electrode pad, a fifth electrode pad, and a sixth electrode pad arranged between the fourth electrode pad and the fifth electrode pad, a first conductive material connecting the first electrode pad with the fourth electrode pad, a second conductive material connecting the second electrode pad with the fifth electrode pad, a third conductive material arranged between the first conductive material and the second conductive material, connecting the third electrode pad with the sixth electrode pad, and a resin provided in an area on the second conductive material side of the third conductive material between the optical semiconductor chip and the wiring substrate.

Provided is a ceramic laminated substrate which is formed on an electronic component to be mounted and is less likely to cause mounting defects even if there is irregularity in the height of solders. The ceramic laminated substrate includes: a ceramic laminate on which ceramic layers are laminated; via conductors; terminal electrodes; and a land electrode. The land electrode has a first land electrode and a second land electrode that are used to join different terminal electrodes of a single electronic component. The area of the first land electrode is smaller than the area of the second land electrode, and the first land electrode has a bump electrode and a plating layer, the second land electrode has a membrane electrode and plating layers, and the height of the first land electrode is formed higher than the height of the second land electrode.

Methods and apparatus to reduce defects in interconnects between semiconductor dies and package substrates are disclosed. An apparatus includes a substrate and a semiconductor die mounted to the substrate. The apparatus further includes bumps to electrically couple the die to the substrate. Ones of the bumps have corresponding bases. The bases have a shape that is non-circular.

A chip transfer method including: disposing a target substrate in a closed cavity, the target substrate including a first alignment bonding structure and a second alignment bonding structure; applying a charge of a first polarity to the first alignment bonding structure of the target substrate; applying a charge of a second polarity to a first chip bonding structure of a chip; injecting an insulating fluid into the closed cavity to suspend the chip in the insulating fluid within the closed cavity; and applying a bonding force to the chip.

A semiconductor die includes a substrate and an integrated circuit provided on the substrate and having contacts. An electrically conductive layer is provided on the integrated circuit and defines electrically conductive elements electrically connected to the contacts. Electrically conductive interconnects coupled with respective electrically conductive elements. The electrically conductive interconnects have at least one of different sizes or shapes from one another.

A semiconductor package includes a first semiconductor chip, a second semiconductor chip on the first semiconductor chip, and a first chip connection structure disposed between the first semiconductor chip and the second semiconductor chip. The first chip connection structure includes a first insertion connection structure connected to the first semiconductor chip, a first recess connection structure connected to the second semiconductor chip, and a first contact layer interposed between the first insertion connection structure and the first recess connection structure. The first recess connection structure includes a base and a side wall which defines a recess. A portion of the first insertion connection structure is disposed in the recess. A portion of the first contact layer is disposed in the recess, and the first contact layer covers at least a portion of a bottom surface of the side wall.

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.

A chip removing device and a chip removing method are provided. The chip removing device includes: a carrier substrate, a laser generation module, and a blowing module. The carrier substrate carries at least one substrate, and a plurality of chips disposed on the substrate. The laser generation module corresponds to the carrier substrate and is used to apply a laser beam to the chip to reduce the bonding force between the chip and the substrate. The blowing module is disposed above the carrier substrate and close to the substrate for applying a gas to the chip to blow the chip away from the substrate.

A package comprising a substrate and an integrated device coupled to the substrate through a plurality of pillar interconnects and a plurality of solder interconnects. The plurality of pillar interconnects comprises a first pillar interconnect. The first pillar interconnect comprises a first pillar interconnect portion comprising a first width and a second pillar interconnect portion comprising a second width that is different than the first width.