The present application discloses a semiconductor device with slanted conductive layers and a method for fabricating the semiconductor device with the slanted conductive layers. The semiconductor device includes a substrate, a first insulating layer positioned above the substrate, first slanted conductive layers positioned in the first insulating layer, and a top conductive layer positioned covering the first slanted conductive layers.

The present application discloses a semiconductor device with slanted conductive layers and a method for fabricating the semiconductor device with the slanted conductive layers. The semiconductor device includes a substrate, a first insulating layer positioned above the substrate, first slanted conductive layers positioned in the first insulating layer, and a top conductive layer positioned covering the first slanted conductive layers.

The present application discloses a method for fabricating a semiconductor device with slanted conductive layers. The method for fabricating a semiconductor device includes providing a substrate, forming a first insulating layer above the substrate, forming first slanted recesses along the first insulating layer, and forming first slanted conductive layers in the first slanted recesses and a top conductive layer covering the first slanted conductive layers.

The invention provides a semiconductor bonding structure, the semiconductor bonding structure includes a first chip and a second chip which are bonded with each other, the first chip has a first bonding pad and the second bonding pad contacted and electrically connected to each other on a bonding interface, the first bonding pad and the second bonding pad are made of copper, and a heterogeneous contact combination in the first chip, the heterogeneous contact combination comprises a contact stack structure of a copper element, a tungsten element and an aluminum element, the tungsten element is located between the copper element and the aluminum element.

A package structure and method for forming the same are provided. The package structure includes a conductive layer formed over a first substrate, and a dielectric layer formed over the conductive layer. The package structure includes a metal-insulator-metal (MIM) capacitor embedded in the dielectric layer, and a shielding layer formed over the MIM capacitor. The shielding layer is insulated from the MIM capacitor by the dielectric layer. The package structure also includes a first through via formed through the MIM capacitor, and the first through via is connected to the conductive layer, and the first through via is insulated from the shielding layer.

A semiconductor apparatus comprising: a first semiconductor component including a first semiconductor layer and a first insulation film; and a second semiconductor component including a second semiconductor layer and a second insulation film, wherein the first semiconductor component and the second semiconductor component are bonded to each other by each of a plurality of first electric conductor portions provided in the first insulation film and each of a plurality of second electric conductor portions provided in the second insulation film, each of the plurality of first electric conductor portions is constituted by one pad surrounded by the first insulation film and N vias bonded to the one pad so as to be positioned between the one pad and the first semiconductor layer, and a volume VTR of the one pad and a total volume VTH of the N vias satisfy VTR/VTH≥N.

A method of forming a metal-insulator-metal (MIM) capacitor with copper top and bottom plates may begin with a copper interconnect layer (e.g., Cu MTOP) including a copper structure defining the capacitor bottom plate. A passivation region is formed over the bottom plate, and a wide top plate opening is etched in the passivation region, to expose the bottom plate. A dielectric layer is deposited into the top plate opening and onto the exposed bottom plate. Narrow via opening(s) are then etched in the passivation region. The wide top plate opening and narrow via opening(s) are concurrently filled with copper to define a copper top plate and copper via(s) in contact with the bottom plate. A first aluminum bond pad is formed on the copper top plate, and a second aluminum bond pad is formed in contact with the copper via(s) to provide a conductive coupling to the bottom plate.

A package structure and method for forming the same are provided. The package structure includes a conductive layer formed over a first substrate, and a dielectric layer formed over the conductive layer. The package structure includes a metal-insulator-metal (MIM) capacitor embedded in the dielectric layer, and a shielding layer formed over the MIM capacitor. The shielding layer is insulated from the MIM capacitor by the dielectric layer. The package structure also includes a first through via formed through the MIM capacitor, and the first through via is connected to the conductive layer, and the first through via is insulated from the shielding layer.

A semiconductor substrate has a back side surface and a front side surface. Metallization levels are provide at the front side surface. Capacitive deep trench isolation structures extend completely through the semiconductor substrate from the front side surface to the back side surface. Each capacitive deep trench isolation structure includes a conductive region insulated from the semiconductor substrate by an insulating liner. The conductive regions at first ends of the plurality of capacitive deep trench isolation structures are electrically connected to a first metallization level by electrical contacts. A bonding pad structure is located at the back side surface of the semiconductor substrate in direct physical and electrical connection to the conductive regions at second ends of the capacitive deep trench isolation structures.

A semiconductor apparatus comprising: a first semiconductor component including a first semiconductor layer and a first insulation film; and a second semiconductor component including a second semiconductor layer and a second insulation film, wherein the first semiconductor component and the second semiconductor component are bonded to each other by each of a plurality of first electric conductor portions provided in the first insulation film and each of a plurality of second electric conductor portions provided in the second insulation film, each of the plurality of first electric conductor portions is constituted by one pad surrounded by the first insulation film and N vias bonded to the one pad so as to be positioned between the one pad and the first semiconductor layer, and a volume VTR of the one pad and a total volume VTH of the N vias satisfy VTR/VTHN.