An integrated circuit chip includes an SOI substrate having a structure in which a bulk substrate, a buried insulating film, and a semiconductor body layer are sequentially stacked, a conductive ion implantation region formed at a position adjacent to the buried insulating film in the bulk substrate, an integrated circuit portion formed on an active surface of the semiconductor body layer, and a penetrating electrode portion arranged at a position spaced apart from the integrated circuit portion in a horizontal direction, the penetrating electrode portion penetrating the semiconductor body layer and the buried insulating layer in a vertical direction, and the penetrating electrode portion connected to the conductive ion implantation region. An integrated circuit package and a display device include the integrated circuit chip.

A solid-state imaging device capable of achieving a further decrease in size such as a further decrease in height, a further increase in speed of wiring, and a further increase in density of wiring is to be provided.

A solid-state imaging device to be provided includes: a first semiconductor device including a semiconductor layer in which a photoelectric conversion unit that photoelectrically converts incident light and a penetrating via are provided, a first connecting portion and a second connecting portion on the surface side of the semiconductor layer on the side that receives the light, and a connecting wiring line that connects the first connecting portion, the second connecting portion, and the penetrating via; and a second semiconductor device that is mounted on the first semiconductor device with the first connecting portion. The solid-state imaging device is connected to an external terminal by the second connecting portion.

In a method of manufacturing a semiconductor device, an opening is formed in a first dielectric layer so that a part of a lower conductive layer is exposed at a bottom of the opening, one or more liner conductive layers are formed over the part of the lower conductive layer, an inner sidewall of the opening and an upper surface of the first dielectric layer, a main conductive layer is formed over the one or more liner conductive layers, a patterned conductive layer is formed by patterning the main conductive layer and the one or more liner conductive layers, and a cover conductive layer is formed over the patterned conductive layer. The main conductive layer which is patterned is wrapped around by the cover conductive layer and one of the one or more liner conductive layers.

The present disclosure provides a method of manufacturing a semiconductor device. The method includes forming an interconnect layer on a semiconductor component, wherein the interconnect layer contains at least one metal pad electrically coupled to the semiconductor component; depositing an insulating layer on the interconnect layer; depositing a bonding dielectric on the insulating layer; and forming a re-routing layer penetrating through the bonding dielectric and the insulating layer and contacting the interconnect layer.

The present disclosure relates to a solid-state image-capturing device, a semiconductor apparatus, an electronic apparatus, and a manufacturing method that enable improvement in reliability of through electrodes and increase in density of through electrodes. A common opening portion is formed including a through electrode formation region that is a region in which the plurality of through electrodes electrically connected respectively to a plurality of electrode pads provided on a joint surface side from a device formation surface of a semiconductor substrate is formed. Then, a plurality of through portions is formed so as to penetrate to the plurality of respective electrode pads in the common opening portion, and wiring is formed along the common opening portion and the through portions from the electrode pads to the device formation surface corresponding to the respective through electrodes. The present technology can be applied to a layer-type solid-state image-capturing device, for example.

A packaging semiconductor device, such as a fan-out Wafer-Level Packaging (FOWLP) device, is fabricated by providing a semiconductor device (20) having conductive patterns (22) disposed on a first surface and then forming, on the conductive patterns, photoresist islands (24) having a first predetermined shape defined by a first critical width dimension and a minimum height dimension so that a subsequently-formed dielectric polymer layer (26) surrounds but does not cover each photoresist island (24), thereby allowing each photoresist island to be selectively removed from the one or more conductive patterns to form one or more via openings (28) in the dielectric polymer layer such that each via opening has a second predetermined shape which matches at least part of the first predetermined shape of the photoresist islands.

An embodiment is a method including forming a first interconnect structure over a first substrate, the first interconnect structure comprising dielectric layers and metallization patterns therein, patterning the first interconnect structure to form a first opening, coating the first opening with a barrier layer, etching a second opening through the barrier layer and the exposed portion of the first substrate, depositing a liner in the first opening and the second opening, filling the first opening and the second opening with a conductive material, and thinning the first substrate to expose a portion of the conductive material in the second opening, the conductive material extending through the first interconnect structure and the first substrate forming a through substrate via.

A method for forming microvias for packaging applications is disclosed. A sacrificial photosensitive material is developed to form microvias with reduced diameter and improved placement accuracy. The microvias are filled with a conductive material and the surrounding dielectric is removed and replaced with an RDL polymer layer.

An integrated circuit (IC) device includes a redistribution line over a substrate, wherein an entire sidewall of the redistribution line is curved. The IC device further includes a passivation layer over the redistribution line, wherein a distance from a bottommost surface of the passivation layer to the substrate is less than a distance from a bottommost surface of the redistribution line to the substrate. The IC device further includes a polymer layer over the passivation layer.

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.