Techniques are employed to mitigate the anchoring effects of cavity sidewall adhesion on an embedded conductive interconnect structure, and to allow a lower annealing temperature to be used to join opposing conductive interconnect structures. A vertical gap may be disposed between the conductive material of an embedded interconnect structure and the sidewall of the cavity to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material. Additionally or alternatively, one or more vertical gaps may be disposed within the bonding layer, near the embedded interconnect structure to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material.

Techniques are employed to mitigate the anchoring effects of cavity sidewall adhesion on an embedded conductive interconnect structure, and to allow a lower annealing temperature to be used to join opposing conductive interconnect structures. A vertical gap may be disposed between the conductive material of an embedded interconnect structure and the sidewall of the cavity to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material. Additionally or alternatively, one or more vertical gaps may be disposed within the bonding layer, near the embedded interconnect structure to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material.

Techniques are employed to mitigate the anchoring effects of cavity sidewall adhesion on an embedded conductive interconnect structure, and to allow a lower annealing temperature to be used to join opposing conductive interconnect structures. A vertical gap may be disposed between the conductive material of an embedded interconnect structure and the sidewall of the cavity to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material. Additionally or alternatively, one or more vertical gaps may be disposed within the bonding layer, near the embedded interconnect structure to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material.

Techniques are employed to mitigate the anchoring effects of cavity sidewall adhesion on an embedded conductive interconnect structure, and to allow a lower annealing temperature to be used to join opposing conductive interconnect structures. A vertical gap may be disposed between the conductive material of an embedded interconnect structure and the sidewall of the cavity to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material. Additionally or alternatively, one or more vertical gaps may be disposed within the bonding layer, near the embedded interconnect structure to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material.

A semiconductor device includes a first substrate, a through substrate via, a second substrate, and a bonding structure. The first substrate includes a first dielectric material, and the first dielectric material includes a first conductive pad embedded therein. The through substrate via is formed in the first substrate. The second substrate includes a second dielectric material, the second dielectric material includes a second conductive pad embedded therein, the first dielectric material is different from the second dielectric material, the second conductive pad has a first height, the second dielectric material has a second height, and the first height is less than the second height. The bonding structure is formed between the first substrate and the second substrate, wherein the bonding structure includes the first conductive pad bonded to the second conductive pad and the first dielectric material bonded to the second dielectric material.

A semiconductor device includes a first substrate, a through substrate via, a second substrate, and a bonding structure. The first substrate includes a first dielectric material, and the first dielectric material includes a first conductive pad embedded therein. The through substrate via is formed in the first substrate. The second substrate includes a second dielectric material, the second dielectric material includes a second conductive pad embedded therein, the first dielectric material is different from the second dielectric material, the second conductive pad has a first height, the second dielectric material has a second height, and the first height is less than the second height. The bonding structure is formed between the first substrate and the second substrate, wherein the bonding structure includes the first conductive pad bonded to the second conductive pad and the first dielectric material bonded to the second dielectric material.

Techniques are employed to mitigate the anchoring effects of cavity sidewall adhesion on an embedded conductive interconnect structure, and to allow a lower annealing temperature to be used to join opposing conductive interconnect structures. A vertical gap may be disposed between the conductive material of an embedded interconnect structure and the sidewall of the cavity to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material. Additionally or alternatively, one or more vertical gaps may be disposed within the bonding layer, near the embedded interconnect structure to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material.

Techniques are employed to mitigate the anchoring effects of cavity sidewall adhesion on an embedded conductive interconnect structure, and to allow a lower annealing temperature to be used to join opposing conductive interconnect structures. A vertical gap may be disposed between the conductive material of an embedded interconnect structure and the sidewall of the cavity to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material. Additionally or alternatively, one or more vertical gaps may be disposed within the bonding layer, near the embedded interconnect structure to laterally unpin the conductive structure and allow uniaxial expansion of the conductive material.

An integrated circuit includes a substrate, an electronic component, a wiring layer, a dielectric bonding layer, a connection pattern, and a barrier layer. The wiring layer is disposed on the substrate, and is electrically connected to the electronic component. The wiring layer includes a metal trace. The dielectric bonding layer is disposed on a side that is of the wiring layer and that is away from the substrate. The connection pattern runs through the dielectric bonding layer, and is electrically connected to the metal trace. The connection pattern includes a seed layer and a conductive block that are stacked, and the seed layer is located on a side that is of the conductive block and that is close to the substrate. The barrier layer is disposed between the conductive block and the dielectric bonding layer, and surrounds a side surface of the conductive block.