A photoelectric conversion apparatus includes a first chip having a first semiconductor element layer including a pixel region of a plurality of pixel circuits, and a second chip having a second semiconductor element layer. The first and second chips are bonded by a plurality of metal bonding portions between the first and second semiconductor element layers. The plurality of metal bonding portions includes first and second metal bonding portions disposed in a region overlapping with the pixel region in a plan view. The first metal bonding portion connects at least either one of the plurality of pixel circuits and the second semiconductor element layer. The second metal bonding portion is connected to at least either one of the plurality of pixel circuits and is not connected to the second semiconductor element layer in the region overlapping with the pixel region.

A semiconductor device including a first semiconductor die, a second semiconductor die, thermal silicon substrates and an encapsulation is provided. The second semiconductor die is disposed on and electrically connected to the first semiconductor die. The thermal silicon substrates are disposed on the first semiconductor die, wherein the thermal silicon substrates are spaced apart from the second semiconductor die. The encapsulation is disposed on the first semiconductor die. The encapsulation encapsulates the second semiconductor die and the thermal silicon substrates. The encapsulation includes a filling material layer and an insulator, wherein the filling material layer is disposed on the first semiconductor die and located between the second semiconductor die and thermal silicon substrates, and the filling material layer is spaced apart from the second semiconductor die and the thermal silicon substrates by the insulator.

A heat spreading material is integrated into a composite die structure including a first IC die having a first dielectric material and a first electrical interconnect structure, and a second IC die having a second dielectric material and a second electrical interconnect structure. The composite die structure may include a composite electrical interconnect structure comprising the first interconnect structure in direct contact with the second interconnect structure at a bond interface. The heat spreading material may be within at least a portion of a dielectric area through which the bond interface extends. The heat spreading material may be located within one or more dielectric materials surrounding the composite interconnect structure, and direct a flow of heat generated by one or more of the first and second IC dies.

A semiconductor heat dissipation structure includes a first semiconductor device including a first active surface and a first back surface opposite to the first active surface, a second semiconductor device including a second active surface and a second back surface opposite to the second active surface, a first heat conductive layer embedded in the first back surface of the first semiconductor device, a second heat conductive layer embedded in the second back surface of the second semiconductor device, and a third heat conductive layer disposed adjoining the first heat conductive layer and extending to the first active surface of the first semiconductor device. The first back surface of the first semiconductor device and the second back surface of the second semiconductor device are in contact with each other. At least a portion of the first heat conductive layer are in contact with the second heat conductive layer.

A heat spreading material is integrated into a composite die structure including a first IC die having a first dielectric material and a first electrical interconnect structure, and a second IC die having a second dielectric material and a second electrical interconnect structure. The composite die structure may include a composite electrical interconnect structure comprising the first interconnect structure in direct contact with the second interconnect structure at a bond interface. The heat spreading material may be within at least a portion of a dielectric area through which the bond interface extends. The heat spreading material may be located within one or more dielectric materials surrounding the composite interconnect structure, and direct a flow of heat generated by one or more of the first and second IC dies.

A heat spreading material is integrated into a composite die structure including a first IC die having a first dielectric material and a first electrical interconnect structure, and a second IC die having a second dielectric material and a second electrical interconnect structure. The composite die structure may include a composite electrical interconnect structure comprising the first interconnect structure in direct contact with the second interconnect structure at a bond interface. The heat spreading material may be within at least a portion of a dielectric area through which the bond interface extends. The heat spreading material may be located within one or more dielectric materials surrounding the composite interconnect structure, and direct a flow of heat generated by one or more of the first and second IC dies.

A semiconductor heat dissipation structure includes a first semiconductor device including a first active surface and a first back surface opposite to the first active surface, a second semiconductor device including a second active surface and a second back surface opposite to the second active surface, a first heat conductive layer embedded in the first back surface of the first semiconductor device, a second heat conductive layer embedded in the second back surface of the second semiconductor device, and a third heat conductive layer disposed adjoining the first heat conductive layer and extending to the first active surface of the first semiconductor device. The first back surface of the first semiconductor device and the second back surface of the second semiconductor device are in contact with each other. At least a portion of the first heat conductive layer are in contact with the second heat conductive layer.

A manufacturing method of a semiconductor structure includes at least the following steps. Forming a first portion includes forming a first patterned conductive pad with a first through hole on a first interconnect structure over a first semiconductor substrate; patterning a dielectric material over the first interconnect structure to form a first patterned dielectric layer with a first opening that passes through a portion of the dielectric material formed inside the first through hole to accessibly expose the first interconnect structure; and forming a conductive material inside the first opening and in contact with the first interconnect structure to form a first conductive connector laterally isolated from the first patterned conductive pad by the first patterned dielectric layer. A singulation process is performed to cut off the first patterned dielectric layer, the first interconnect structure, and the first semiconductor substrate to form a continuous sidewall of a semiconductor structure.

A stacking structure including a first die, a second die stacked on the first die, and a filling material is provided. The first die has a first bonding structure, and the first bonding structure includes first bonding pads and a first heat dissipating element. The second die has a second bonding structure, and the second bonding structure includes second bonding pads and a second heat dissipating element. The first bonding pads are bonded with the second bonding pads. The first heat dissipating element is connected to one first bonding pad of the first bonding pads and the second heat dissipating element is connected to one second bonding pad of the second bonding pads. The filling material is disposed over the first die and laterally around the second die. The first and second dies are bonded through the first and second bonding structures.

A method includes depositing a first dielectric layer over a substrate; forming a first dummy metal layer over the first dielectric layer, wherein the first dummy metal layer has first and second portions laterally separated from each other; depositing a second dielectric layer over the first dummy metal layer; etching an opening having an upper portion in the second dielectric layer, a middle portion between the first and second portions of the first dummy metal layer, and a lower portion in the first dielectric layer, wherein a width of the lower portion of the opening is greater than a width of the middle portion of the opening, and a bottom of the opening is higher than a bottom of the first dielectric layer; and forming a dummy via in the opening and a second dummy metal layer over the dummy via and the second dielectric layer.