A nucleation suppression layer including a self-assembly material can be formed on a surface of a bonding dielectric layer without depositing the self-assembly material on physically exposed surfaces of first metal bonding pads of a first semiconductor die. Metallic liners including a second metal can be formed on the physically exposed surfaces of the metal bonding pads without depositing the second metal on the nucleation suppression layer. The first semiconductor die is bonded to a second semiconductor die by inducing metal-to-metal bonding between mating pairs of the first metal bonding pads and second metal bonding pads of the second semiconductor die.

A nucleation suppression layer including a self-assembly material can be formed on a surface of a bonding dielectric layer without depositing the self-assembly material on physically exposed surfaces of first metal bonding pads of a first semiconductor die. Metallic liners including a second metal can be formed on the physically exposed surfaces of the metal bonding pads without depositing the second metal on the nucleation suppression layer. The first semiconductor die is bonded to a second semiconductor die by inducing metal-to-metal bonding between mating pairs of the first metal bonding pads and second metal bonding pads of the second semiconductor die.

A nucleation suppression layer including a self-assembly material can be formed on a surface of a bonding dielectric layer without depositing the self-assembly material on physically exposed surfaces of first metal bonding pads of a first semiconductor die. Metallic liners including a second metal can be formed on the physically exposed surfaces of the metal bonding pads without depositing the second metal on the nucleation suppression layer. The first semiconductor die is bonded to a second semiconductor die by inducing metal-to-metal bonding between mating pairs of the first metal bonding pads and second metal bonding pads of the second semiconductor die.

A nucleation suppression layer including a self-assembly material can be formed on a surface of a bonding dielectric layer without depositing the self-assembly material on physically exposed surfaces of first metal bonding pads of a first semiconductor die. Metallic liners including a second metal can be formed on the physically exposed surfaces of the metal bonding pads without depositing the second metal on the nucleation suppression layer. The first semiconductor die is bonded to a second semiconductor die by inducing metal-to-metal bonding between mating pairs of the first metal bonding pads and second metal bonding pads of the second semiconductor die.

A structure has a first substrate bonded to a first under-bump metallization (UBM) structure, the first UBM structure comprising a first bonding region laterally surrounded by a first superconducting region. A second substrate is bonded to a second under-bump metallization (UBM) structure, the second UBM structure comprising a second bonding region laterally surrounded by a second superconducting region; and a superconducting solder material joins the first UBM structure to the second UBM structure.

A structure has a first substrate bonded to a first under-bump metallization (UBM) structure, the first UBM structure comprising a first bonding region laterally surrounded by a first superconducting region. A second substrate is bonded to a second under-bump metallization (UBM) structure, the second UBM structure comprising a second bonding region laterally surrounded by a second superconducting region; and a superconducting solder material joins the first UBM structure to the second UBM structure.

A technique relates to a structure. An under-bump-metallization (UBM) structure includes a first region and a second region. The first and second regions are laterally positioned in the UBM structure. The first region includes a superconducting material. A substrate opposes the UBM structure. A superconducting solder material joins the first region to the substrate and the second region to the substrate.

A technique relates to a structure. An under-bump-metallization (UBM) structure includes a first region and a second region. The first and second regions are laterally positioned in the UBM structure. The first region includes a superconducting material. A substrate opposes the UBM structure. A superconducting solder material joins the first region to the substrate and the second region to the substrate.

A structure has a first substrate bonded to a first under-bump metallization (UBM) structure, the first UBM structure comprising a first bonding region laterally surrounded by a first superconducting region. A second substrate is bonded to a second under-bump metallization (UBM) structure, the second UBM structure comprising a second bonding region laterally surrounded by a second superconducting region; and a superconducting solder material joins the first UBM structure to the second UBM structure.

A structure has a first substrate bonded to a first under-bump metallization (UBM) structure, the first UBM structure comprising a first bonding region laterally surrounded by a first superconducting region. A second substrate is bonded to a second under-bump metallization (UBM) structure, the second UBM structure comprising a second bonding region laterally surrounded by a second superconducting region; and a superconducting solder material joins the first UBM structure to the second UBM structure.