The present disclosure relates an integrated chip structure. The integrated chip structure includes a first chiplet predominantly having a first plurality of integrated chip devices coupled to a first plurality of interconnects over a first substrate. The first plurality of integrated chip devices are a first type of integrated chip device. The integrated chip structure further includes a second chiplet predominantly having a second plurality of integrated chip devices coupled to a second plurality of interconnects over a second substrate. The second plurality of integrated chip devices are a second type of integrated chip device different than the first type of integrated chip device. One or more inter-chiplet connectors are between the first and second chiplets and are configured to electrically couple the first and second chiplets. The first plurality of interconnects have a first minimum width different than a second minimum width of the second plurality of interconnects.

Embodiments of this application provide a semiconductor structure and a method for forming the same. The method for forming the semiconductor structure includes: a first substrate is provided; the back surface of the first substrate is etched to form a trench; a conductive layer is formed in the trench; a first conductive column that extends into the trench is formed at a back surface of the first substrate; a device layer is formed at a front surface of the first substrate, and the device layer includes a storage array and a contact structure; and a second conductive column that penetrates through the device layer and extends into the first substrate is formed; the first conductive column is electrically connected with the second conductive column through the conductive layer.

A method for forming a thermal conduction structure includes: a substrate is provided, at least a dielectric layer being formed on the substrate; a Through Silicon Via (TSV) and at least one silicon blind hole are formed, where the at least one silicon blind hole is located on at least one side of the TSV, the TSV penetrates through the substrate and the dielectric layer, and each silicon blind hole does not penetrate through the substrate.

A method includes forming a plurality of dielectric layers, forming a plurality of redistribution lines in the plurality of dielectric layers, etching the plurality of dielectric layers to form an opening, filling the opening to form a through-dielectric via penetrating through the plurality of dielectric layers, forming an insulation layer over the through-dielectric via and the plurality of dielectric layers, forming a plurality of bond pads in the dielectric layer, and bonding a device to the insulation layer and a portion of the plurality of bond pads through hybrid bonding.

A semiconductor device includes a first dielectric structure, a second dielectric structure, a first substrate between the first dielectric structure and the second dielectric structure, a passivation structure over the second dielectric structure, a first metallic structure over the first dielectric structure, a second metallic structure over the passivation structure, and a third metallic structure in the first and second dielectric structures, the first substrate, and the passivation structure. The second dielectric structure is between the passivation structure and the first substrate. The first metallic structure is electrically connected to the second metallic structure through the third metallic structure, the third metallic structure includes a first portion in the first dielectric structure and the first substrate, a second portion in the second dielectric structure and a third portion in the passivation structure. Widths of the first portion, the second portion and the third portion are different from each other.

A method for producing a semiconductor apparatus capable of producing a semiconductor apparatus with improved transmission loss characteristic using an interposer substrate in which semiconductor devices formed on a silicon single crystal substrate are connected to each other by a through electrode, the method including: a step of providing the silicon single crystal substrate containing a dopant; a step of forming the semiconductor devices and the through electrode on the silicon single crystal substrate to obtain the interposer substrate; and a step of irradiating a particle beam to at least around a formation part for the through electrode on the silicon single crystal substrate to deactivate the dopant in a region around the formation part for the through electrode.

A semiconductor device includes an electronic circuit within a device layer; wherein the device layer is between a thin layer of wiring for signal connections having a first thickness and a thick layer of wiring for power having a second thickness, the second thickness being greater than the first thickness; a silicon layer above the device layer, the thin layer of wiring, and the thick layer of wiring; a first via connection from a top of the semiconductor device to the thin layer of wiring; a second via connection from the top of the semiconductor device to the thick layer of wiring; and a packaging substrate with a connection to the thick layer of wiring.

A semiconductor structure with backside through silicon vias (TSVs) is provided in the present invention, including a semiconductor substrate with a front side and a back side, multiple dummy pads set on the front side, multiple backside TSVs extending from the back side to the front side, wherein a number of the dummy pads are connected with the backside TSVs while other dummy pads are not connected with the backside TSVs, and a metal coating covering the back side and the surface of backside TSVs and connected with those dummy pads that connecting with the backside TSVs.

A semiconductor device including a first structure including a first conductive pattern, the first conductive pattern exposed on an upper portion of the first structure, a mold layer covering the first conductive pattern, a second structure on the mold layer, and a through via penetrating the second structure and the mold layer, the through via electrically connected to the first conductive pattern, the through via including a first via segment in the second structure and a second via segment in the mold layer, the second via segment connected to the first via segment, an upper portion of the second via segment having a first width and a middle portion of the second via segment having a second width greater than the first width may be provided.

Wafers including a diamond layer and a semiconductor layer having III-Nitride compounds and methods for fabricating the wafers are provided. A nucleation layer, at least one semiconductor layer having III-Nitride compound and a protection layer are formed on a silicon substrate. Then, a silicon carrier wafer is glass bonded to the protection layer. Subsequently the silicon substrate, nucleation layer and a portion of the semiconductor layer are removed. Then, an intermediate layer, a seed layer and a first diamond layer are sequentially deposited on the III-Nitride layer. Next, the silicon carrier wafer and the protection layer are removed. Then, a silicon substrate wafer that includes a protection layer, silicon substrate and a diamond layer is prepared and glass bonded to the first diamond layer.