A chip structure, a wafer structure and a method for manufacturing the same are provided in the present disclosure. A first chip and a second chip are bonded by bonding layers of a dielectric material. Top wiring layers are led out through bonding via holes from a back surface of a bonded chip. The bonding via holes are used for bonding and are surrounded by the bonding layers. A top wiring layer of a third chip is led out through bonding pads formed in a bonding layer. The bonding via holes are aligned with and bonded to the bonding pads to achieve bonding of the three chips. The top wiring layer of the third chip is led out from the back surface of the third chip through a lead-out pad.

A method of manufacturing a high-frequency device includes mounting a first chip having a first pillar on an upper surface thereof on a metal base, forming an insulator layer covering the first chip on the metal base, exposing an upper surface of the first pillar from the insulator layer, and forming a first wiring connected to the first pillar on the insulator layer and transmitting a high-frequency signal.

A light emitting module including a circuit board and a lighting emitting device thereon and including first, second, and third LED stacks each including first and second conductivity type semiconductor layers, a first bonding layer between the second and third LED stacks, a second bonding layer between the first and second LED stacks, a first planarization layer between the second bonding layer and the third LED stack, a second planarization layer on the first LED stack, a lower conductive material extending along sides of the first planarization layer, the second LED stack, the first bonding layer, and electrically connected to the first conductivity type semiconductor layers of each LED stack, respectively, and an upper conductive material between the circuit board and the lower conductive material, in which a width of an upper end of the upper conductive material is greater than a width of the corresponding upper conductive material.

Disclosed is a method for testing a semiconductor element. The method comprises forming at least one redistribution layer on a chip, utilizing the at least one redistribution layer to test an array of semiconductor elements on the chip, and removing the at least one redistribution layer from the chip, wherein the length of each semiconductor element is between 2-150 μm and the width of each semiconductor element is between 2-150 μm.

An interconnect apparatus and a method of forming the interconnect apparatus is provided. Two integrated circuits are bonded together. A first opening is formed through one of the substrates. A multi-layer dielectric film is formed along sidewalls and a bottom of the first opening. A second opening is formed extending from the first opening to pads in the integrated circuits. A dielectric liner is formed, and the opening is filled with a conductive material to form a conductive plug.

A method includes forming a dielectric layer over a carrier, forming a plurality of bond pads in the dielectric layer, and performing a planarization to level top surfaces of the dielectric layer and the plurality of bond pads with each other. A device die is bonded to the dielectric layer and portions of the plurality of bond pads through hybrid bonding. The device die is encapsulated in an encapsulating material. The carrier is then demounted from the device die and the dielectric layer.

A semiconductor device includes an encapsulant including a first hollow region, a sensing die in the first hollow region of the encapsulant, and a redistribution structure disposed on the encapsulant and the sensing die and electrically coupled to the sensing die. A top width of the hollow region is greater than a bottom width of the hollow region. The redistribution structure includes a second hollow region which exposes a sensing area of the sensing die, and the redistribution structure is slanted downward from an edge of the device toward the sensing area.

A light emitting module including a circuit board and a lighting emitting device thereon and including first, second, and third LED stacks each including first and second conductivity type semiconductor layers, a first bonding layer between the second and third LED stacks, a second bonding layer between the first and second LED stacks, a first planarization layer between the second bonding layer and the third LED stack, a second planarization layer on the first LED stack, a lower conductive material extending along sides of the first planarization layer, the second LED stack, the first bonding layer, and electrically connected to the first conductivity type semiconductor layers of each LED stack, respectively, and an upper conductive material between the circuit board and the lower conductive material.

A liquid circulating cooling package substrate includes a circulating cooling structure including a cooling chamber in a first dielectric layer to expose a heat dissipation face, a metal heat dissipation layer on the inner surface of the cooling chamber, an upright support column formed on a metal heat dissipation layer, and a cooling cover supported on the support column to close the cooling chamber along the periphery of the cooling chamber. The metal heat dissipation layer completely covers the heat dissipation face and the inner side surface of the cooling chamber, and a liquid inlet and a liquid outlet are formed on the cooling cover. A circulating cooling structure is provided in the first dielectric layer, and the circulating cooling structure is formed during the processing of an embedded package substrate such that the processing flow is simple and the cost is low.

A method includes encapsulating a device in an encapsulating material, planarizing the encapsulating material and the device, and forming a conductive feature over the encapsulating material and the device. The formation of the conductive feature includes depositing a first conductive material to from a first seed layer, depositing a second conductive material different from the first conductive material over the first seed layer to form a second seed layer, plating a metal region over the second seed layer, performing a first etching on the second seed layer, performing a second etching on the first seed layer, and after the first seed layer is etched, performing a third etching on the second seed layer and the metal region.