Some embodiments include a method of forming integrated circuitry. A first assembly is formed to have a first dielectric material, a first conductive pad and a conductive structure. The first assembly has a first surface which includes a surface of the first dielectric material, a surface of the first conductive pad and a surface of the conductive structure. A second assembly is formed to have a second dielectric material and a second conductive pad. The second assembly has a second surface which includes a surface of the second dielectric material and a surface of the second conductive pad. The first surface is placed directly against the second surface. The surface of the first dielectric material is bonded with the surface of the second dielectric material, and the surface of the first conductive pad is bonded with the surface of the second conductive pad.

The present disclosure provides a semiconductor package, including a first device having a first joining surface, a first conductive component at least partially protruding from the first joining surface, a second device having a second joining surface facing the first joining surface, and a second conductive component at least exposing from the second joining surface. The first conductive component and the second conductive component form a joint having a first beak. The first beak points to either the first joining surface or the second joining surface.

The present disclosure provides a semiconductor package, including a first device having a first joining surface, a first conductive component at least partially protruding from the first joining surface, a second device having a second joining surface facing the first joining surface, and a second conductive component at least exposing from the second joining surface. The first conductive component and the second conductive component form a joint having a first beak. The first beak points to either the first joining surface or the second joining surface.

A semiconductor laser structure is provided. The semiconductor laser comprises a central thermal shunt, a ring shaped silicon waveguide, a contiguous thermal shunt, an adhesive layer and a laser element. The central thermal shunt is located on a SOI substrate which has a buried oxide layer surrounding the central thermal shunt. The ring shaped silicon waveguide is located on the buried oxide layer and surrounds the central thermal shunt. The ring shaped silicon waveguide includes a P-N junction of a p-type material portion, an n-type material portion and a depletion region there between. The contiguous thermal shunt covers a portion of the buried oxide layer and surrounds the ring shaped silicon waveguide. The adhesive layer covers the ring shaped silicon waveguide and the buried oxide layer. The laser element covers the central thermal shunt, the adhesive layer and the contiguous thermal shunt.

A semiconductor laser structure is provided. The semiconductor laser comprises a central thermal shunt, a ring shaped silicon waveguide, a contiguous thermal shunt, an adhesive layer and a laser element. The central thermal shunt is located on a SOI substrate which has a buried oxide layer surrounding the central thermal shunt. The ring shaped silicon waveguide is located on the buried oxide layer and surrounds the central thermal shunt. The ring shaped silicon waveguide includes a P-N junction of a p-type material portion, an n-type material portion and a depletion region there between. The contiguous thermal shunt covers a portion of the buried oxide layer and surrounds the ring shaped silicon waveguide. The adhesive layer covers the ring shaped silicon waveguide and the buried oxide layer. The laser element covers the central thermal shunt, the adhesive layer and the contiguous thermal shunt.

Semiconductor devices having stacked structures and methods for fabricating the same are provided. A semiconductor device includes at least one single block including a first semiconductor chip and a second semiconductor chip stacked thereon. Each of the first and second semiconductor chips includes a semiconductor substrate including a through-electrode, a circuit layer on a front surface of the semiconductor substrate, and a front pad that is provided in the circuit layer and is electrically connected to the through-electrode. The surfaces of the semiconductor substrates face each other. The circuit layers directly contact each other such that the semiconductor chips are bonded to each other.

Semiconductor devices having stacked structures and methods for fabricating the same are provided. A semiconductor device includes at least one single block including a first semiconductor chip and a second semiconductor chip stacked thereon. Each of the first and second semiconductor chips includes a semiconductor substrate including a through-electrode, a circuit layer on a front surface of the semiconductor substrate, and a front pad that is provided in the circuit layer and is electrically connected to the through-electrode. The surfaces of the semiconductor substrates face each other. The circuit layers directly contact each other such that the semiconductor chips are bonded to each other.

A first semiconductor structure having a first metallic structure that has a convex outermost surface and a second semiconductor structure having a second metallic structure that has a concave outermost surface are first provided. The first and second metallic structures are provided utilizing liner systems that have an opposite galvanic reaction to the metal or metal alloy that constitutes the first and second metallic structures such that during a planarization process the metal liners have a different removal rate than the metal or metal alloy that constitutes the first and second metallic structures. The first semiconductor structure and the second semiconductor structure are then bonded together such that the convex outermost surface of the first metallic structure is in direct contact with the concave outermost surface of the second metallic structure.

A first semiconductor structure having a first metallic structure that has a convex outermost surface and a second semiconductor structure having a second metallic structure that has a concave outermost surface are first provided. The first and second metallic structures are provided utilizing liner systems that have an opposite galvanic reaction to the metal or metal alloy that constitutes the first and second metallic structures such that during a planarization process the metal liners have a different removal rate than the metal or metal alloy that constitutes the first and second metallic structures. The first semiconductor structure and the second semiconductor structure are then bonded together such that the convex outermost surface of the first metallic structure is in direct contact with the concave outermost surface of the second metallic structure.

An integrated circuit (IC) die including a top surface and a bottom surface, a plurality of spaced apart ground connection traces positioned between the top surface and the bottom surface; with a hole in the die exposing the plurality of spaced apart ground connection traces.