Disclosed is a die packaging structure comprising a semiconductor die, an encapsulant layer disposed around the semiconductor die, wherein a backside surface of the semiconductor die is exposed, and a conductive layer coupled to the semiconductor die, the conductive layer comprising a plurality of conductive pillar bumps, wherein a bump density of the plurality of conductive pillar bumps is greater than 5%, wherein the encapsulant layer is further disposed between the plurality of conductive bumps, and wherein the encapsulant layer is disposed between the plurality of conductive bumps using a mold underfill (MUF) process. A method of forming the same is also disclosed.

A repairing method, manufacturing method, device and electronic apparatus of micro-LED are disclosed. The method for repairing micro-LED defects comprises: obtaining a micro-LED defect pattern on a receiving substrate; forming micro-LEDs (703b) corresponding to the defect pattern on a laser-transparent repair carrier substrate (707); aligning the micro-LEDs (703b) on the repair carrier substrate (707) with defect positions on the receiving substrate, and bringing the micro-LEDs (703b) into contact with pads at the defect positions; and irradiating the repair carrier substrate with a laser from the repair carrier substrate side, to lift-off the micro-LEDs from the repair carrier substrate (707).

An electronic component package includes a frame, an electronic component, an encapsulant, a metal layer, and a redistribution layer. The frame has a through hole. The electronic component is disposed in the through hole of the frame and has an active surface on which electrode pads are formed and an inactive surface opposing the active surface. The encapsulant covers the inactive surface of the electronic component and is disposed between the frame and the electronic component within the through hole. The metal layer is formed on a surface of the encapsulant. The redistribution layer is disposed adjacently to the active surface of the electronic component and electrically connected to the electrode pads.

A die stack structure including a first semiconductor die, a second semiconductor die, an insulating encapsulation and a redistribution circuit structure is provided. The first semiconductor die includes a first semiconductor substrate including a first portion and a second portion, a first interconnect structure and a first bonding structure. The first interconnect structure is disposed on a top surface of the second portion, a lateral dimension of the first portion is greater than a lateral dimension of the top surface of the second portion. The second semiconductor die is disposed on the first semiconductor die and includes a second bonding structure, the second semiconductor die is electrically connected with the first semiconductor die through the first and second bonding structures. The insulating encapsulation is disposed on the first portion and laterally encapsulating the second portion and the second semiconductor die. The redistribution circuit structure is electrically connected with the first and second semiconductor dies, and the lateral dimension of the first portion is greater than a lateral dimension of the redistribution circuit structure.

Microelectronic assemblies, and related devices and methods, are disclosed herein. In some embodiments, a microelectronic assembly may include a first microelectronic component, having a first surface and an opposing second surface including a first direct bonding region at the second surface with first metal contacts and a first dielectric material between adjacent ones of the first metal contacts; a second microelectronic component, having a first surface and an opposing second surface, including a second direct bonding region at the first surface with second metal contacts and a second dielectric material between adjacent ones of the second metal contacts, wherein the second microelectronic component is coupled to the first microelectronic component by the first and second direct bonding regions; and a shield structure in the first direct bonding dielectric material at least partially surrounding the one or more of the first metal contacts.

Disclosed herein are microelectronic assemblies including microelectronic components coupled by direct bonding, and related structures and techniques. In some embodiments, a microelectronic assembly may include a first microelectronic component including a first guard ring extending through at least a portion of a thickness of and along a perimeter; a second microelectronic component including a second guard ring extending through at least a portion of a thickness of and along a perimeter, where the first and second microelectronic components are coupled by direct bonding; and a seal ring formed by coupling the first guard ring to the second guard ring. In some embodiments, a microelectronic assembly may include a microelectronic component coupled to an interposer that includes a first liner material at a first surface; a second liner material at an opposing second surface; and a perimeter wall through the interposer and connected to the first and second liner materials.

A die stack structure including a first semiconductor die, a second semiconductor die, an insulating encapsulation and a redistribution circuit structure is provided. The first semiconductor die includes a first semiconductor substrate including a first portion and a second portion, a first interconnect structure and a first bonding structure. The first interconnect structure is disposed on a top surface of the second portion, a lateral dimension of the first portion is greater than a lateral dimension of the top surface of the second portion. The second semiconductor die is disposed on the first semiconductor die and includes a second bonding structure, the second semiconductor die is electrically connected with the first semiconductor die through the first and second bonding structures. The insulating encapsulation is disposed on the first portion and laterally encapsulating the second portion and the second semiconductor die. The redistribution circuit structure is electrically connected with the first and second semiconductor dies, and the lateral dimension of the first portion is greater than a lateral dimension of the redistribution circuit structure.

A lead frame includes a first side having a first die attach pad that is bondable to a die, and a second side that has a second die attach pad that is bondable to another die. The lead frame includes multiple leads on the edges of the lead frame to connect the die. As part of a no-leads device, such as a quad flat no leads (QFN) or dual flat no-leads (DFN), one of the die attach pads is used in binding to a die, and the other die attach pad is used for thermal dissipation and mounting to a structure such as printed circuit board (PCB).

A semiconductor package includes a first semiconductor die, a second semiconductor die and a plurality of bumps. The first semiconductor die has a front side and a backside opposite to each other. The second semiconductor die is disposed at the backside of the first semiconductor die and electrically connected to first semiconductor die. The plurality of bumps is disposed at the front side of the first semiconductor die and physically connects first die pads of the first semiconductor die. A total width of the first semiconductor die may be less than a total width of the second semiconductor die.

The present disclosure provides a camera assembly and a packaging method thereof, a lens module, and an electronic device. The packaging method of the camera assembly includes: providing a carrier substrate and forming a redistribution layer (RDL) structure on the carrier substrate; providing functional components having solder pads; forming a photosensitive unit, including a photosensitive chip and an optical filter mounted on the photosensitive chip, that the photosensitive chip has solder pads facing the optical filter; temporarily bonding the optical filter of the photosensitive unit with the carrier substrate, and placing the functional components on the RDL structure, that each of the solder pads of the photosensitive chip and the solder pads of the functional components faces the RDL structure and electrically connects with the RDL structure; forming an encapsulation layer covering the carrier substrate, that the encapsulation layer is coplanar with a highest top of the photosensitive chip and the functional components; and removing the carrier substrate.