A semiconductor device is provided, which includes a substrate, a first semiconductor structure, a plurality of first holes, a first dielectric structure and a second semiconductor structure. The first semiconductor structure is located on the substrate. The first holes are periodically arranged in the first semiconductor structure. The first dielectric structure is filled in one or more of the first holes. The second semiconductor structure is located on the first semiconductor structure.

During electro-oxidative metal removal on a semiconductor substrate, the substrate having a metal layer is anodically biased and the metal is electrochemically dissolved into an electrolyte. Metal particles (e.g., copper particles when the dissolved metal is copper) can inadvertently form on the surface of the substrate during electrochemical metal removal and cause defects during subsequent semiconductor processing. Contamination with such particles can be mitigated by preventing particle formation and/or by dissolution of particles. In one implementation, mitigation involves using an electrolyte that includes an oxidizer, such as hydrogen peroxide, during the electrochemical metal removal. An electrochemical metal removal apparatus in one embodiment has a conduit for introducing an oxidizer to the electrolyte and a sensor for monitoring the concentration of the oxidizer in the electrolyte.

Disclosed embodiments include frame-array interconnects that have a ledge portion to accommodate a passive device. A seated passive device is between at least two frame-array interconnects for semiconductor package-integrated decoupling capacitors.

A light emitting diode module includes a first conductive device, a second conductive device, an insulating structure and a plating layer. The first conductive device includes a first metal layer and a first protecting layer covering the first metal layer. The second conductive device includes a second metal layer and a second protecting layer covering the second metal layer. The insulating structure covers around the first and the second conductive devices. The plating layer is disposed on the first and the second protecting layers in a first and a second openings of the insulating structure. The insulating structure covers portions of upper surfaces of the first and the second conductive devices. The plating layer covers remaining portions of the upper surfaces of the first and the second conductive devices. Lower surfaces of the first and the second conductive devices are located in the second opening.

The present invention is an IC chip mounting apparatus including: a plurality of nozzles, each movable between a first position and a second position, each configured to suck an IC chip, when located at the first position, and to place the IC chip on the adhesive at the reference position of the corresponding antenna of an antenna continuous body, when located at the second position; a nozzle attachment to which the plurality of nozzles is attached; and a controller configured to control an angular velocity in rotating the nozzle attachment, so that a first nozzle of the plurality of nozzles that reaches the second position later than a non-sucking nozzle, places an IC chip on an antenna corresponding to the non-sucking nozzle, the non-sucking nozzle being a nozzle of the plurality of nozzles that has been determined as not sucking an IC chip.

In some examples, a quad flat no lead (QFN) semiconductor package comprises a flip chip semiconductor die having a surface and circuitry formed in the surface; and a conductive pillar coupled to the semiconductor die surface. The conductive pillar has a distal end relative to the semiconductor die, the distal end having a cavity including a cavity floor and one or more cavity walls circumscribing the cavity floor. The one or more cavity walls are configured to contain solder.

An integrated circuit includes a middle active-region structure between a group-one active-region structure and a group-two active-region structure. The integrated circuit also includes a main circuit, a group-one circuit, and a group-two circuit. The main circuit includes at least one boundary gate-conductor intersecting the middle active-region structure. The group-one circuit includes a group-one isolation structure separating the group-one active-region structure into a first part in the group-one circuit and a second part in a first adjacent circuit. The group-two circuit includes a group-two isolation structure separating the group-two active-region structure into a first part in the group-two circuit and a second part in a second adjacent circuit.

Embodiments of 3D memory devices and methods for forming the same are disclosed. In an example, a 3D memory device includes a substrate having a first side and a second side opposite to the first side. The 3D memory device also includes a memory stack including interleaved conductive layers and dielectric layers at the first side of the substrate. The 3D memory device also includes a plurality of channel structures each extending vertically through the memory stack. The 3D memory device also includes a first insulating structure extending vertically through the memory stack and extending laterally to separate the plurality of channel structures into a plurality of blocks. The 3D memory device further includes a first doped region in the substrate and in contact with the first insulating structure. The 3D memory device further includes a first contact extending vertically from the second side of the substrate to be in contact with the first doped region.

A semiconductor device of an embodiment includes: a wiring board; a semiconductor chip mounted on the wiring board; and a resin-containing layer bonded on the wiring board so as to fix the semiconductor chip to the wiring board. The resin-containing layer contains a resin-containing material having a breaking strength of 15 MPa or more at 125° C.

In some embodiments, the present disclosure relates to method of forming an integrated circuit, including forming a semiconductor device on a frontside of a semiconductor substrate; depositing a dielectric layer over a backside of the semiconductor substrate; patterning the dielectric layer to form a first opening in the dielectric layer so that the first opening exposes a surface of the backside of the semiconductor substrate; depositing a glue layer having a first thickness over the first opening; filling the first opening with a first material to form a backside contact that is separated from the semiconductor substrate by the glue layer; and depositing more dielectric layers, bonding contacts, and bonding wire layers over the dielectric layer to form a second bonding structure on the backside of the semiconductor substrate, so that the backside contact is coupled to the bonding contacts and the bonding wire layers.