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 device comprises a first chip bonded on a second chip. The first chip comprises a first substrate and first interconnection components formed in first IMD layers. The second chip comprises a second substrate and second interconnection components formed in second IMD layers. The device further comprises a first conductive plug formed within the first substrate and the first IMD layers, wherein the first conductive plug is coupled to a first interconnection component and a second conductive plug formed through the first substrate and the first IMD layers and formed partially through the second IMD layers, wherein the second conductive plug is coupled to a second interconnection component.

A first semiconductor structure including a first bonding oxide layer having a first metallic structure embedded therein and a second semiconductor structure including a second bonding oxide layer having second metallic structure embedded therein are provided. A high-k dielectric material is formed on a surface of the first metallic structure. A nitride surface treatment process is performed to provide a nitrided surface layer to each structure. The nitrided surface layer includes nitridized oxide regions located in an upper portion of the bonding oxide layers and either a nitridized high-k dielectric material located in at least an upper portion of the high k dielectric material or a nitridized metallic region located in an upper portion of the second metallic structure. The nitrogen within the nitridized metallic region is then selectively removed to restore the upper portion of the second metallic structure to its original composition. Bonding is then performed.

A first semiconductor structure including a first bonding oxide layer having a first metallic structure embedded therein and a second semiconductor structure including a second bonding oxide layer having second metallic structure embedded therein are provided. A high-k dielectric material is formed on a surface of the first metallic structure. A nitride surface treatment process is performed to provide a nitrided surface layer to each structure. The nitrided surface layer includes nitridized oxide regions located in an upper portion of the bonding oxide layers and either a nitridized high-k dielectric material located in at least an upper portion of the high k dielectric material or a nitridized metallic region located in an upper portion of the second metallic structure. The nitrogen within the nitridized metallic region is then selectively removed to restore the upper portion of the second metallic structure to its original composition. Bonding is then performed.

A memory array and single-crystal circuitry are provided by wafer bonding (e.g., adhesive wafer bonding or anodic wafer bonding) in the same integrated circuit and interconnected by conductors of a interconnect layer. Additional circuitry or memory arrays may be provided by additional wafer bonds and electrically connected by interconnect layers at the wafer bonding interface. The memory array may include storage or memory transistors having single-crystal epitaxial silicon channel material.

A memory array and single-crystal circuitry are provided by wafer bonding (e.g., adhesive wafer bonding or anodic wafer bonding) in the same integrated circuit and interconnected by conductors of a interconnect layer. Additional circuitry or memory arrays may be provided by additional wafer bonds and electrically connected by interconnect layers at the wafer bonding interface. The memory array may include storage or memory transistors having single-crystal epitaxial silicon channel material.

A semiconductor device and a method for forming a semiconductor are provided. The semiconductor device includes: a first substrate, a first conductive line disposed on the first substrate, a second substrate opposite to the first substrate, a second conductive line disposed on the second substrate and adjacent to the first conductive line, and a plurality of bonding structures between the first conductive line and the second conductive line. The first conductive line includes a plurality of first segments separated from one another. The second conductive line includes a plurality of second segments separated from one another. Each of the bonding structures is connected to a respective first segment of the plurality of first segments and a respective second segment of the plurality of second segments such that the plurality of first segments, the plurality of bonding structures and the plurality of second segments are connected in series.

A metal-dielectric bonding method includes providing a first semiconductor structure including a first semiconductor layer, a first dielectric layer on the first semiconductor layer, and a first metal layer on the first dielectric layer, where the first metal layer has a metal bonding surface facing away from the first semiconductor layer; planarizing the metal bonding surface; applying a plasma treatment on the metal bonding surface; providing a second semiconductor structure including a second semiconductor layer, and a second dielectric layer on the second semiconductor layer, where the second dielectric layer has a dielectric bonding surface facing away from the second semiconductor layer; planarizing the dielectric bonding surface; applying a plasma treatment on the dielectric bonding surface; and bonding the first semiconductor structure with the second semiconductor structure by bonding the metal bonding surface with the dielectric bonding surface.

A metal-dielectric bonding method includes providing a first semiconductor structure including a first semiconductor layer, a first dielectric layer on the first semiconductor layer, and a first metal layer on the first dielectric layer, where the first metal layer has a metal bonding surface facing away from the first semiconductor layer; planarizing the metal bonding surface; applying a plasma treatment on the metal bonding surface; providing a second semiconductor structure including a second semiconductor layer, and a second dielectric layer on the second semiconductor layer, where the second dielectric layer has a dielectric bonding surface facing away from the second semiconductor layer; planarizing the dielectric bonding surface; applying a plasma treatment on the dielectric bonding surface; and bonding the first semiconductor structure with the second semiconductor structure by bonding the metal bonding surface with the dielectric bonding surface.

A process for bonding chips to a substrate by direct bonding includes providing a support with which the chips are in contact, the chips in contact with the support being separate from one another. This bonding process also includes forming a liquid film on one face of the substrate, bringing the chips into contact with the liquid film, where the action of bringing the chips into contact with the liquid film causes attraction of the chips toward the substrate, and evaporating the liquid film in order to bond the chips to the substrate by direct bonding.