The present invention provides a stabilized fine textured metal microstructure that constitutes a durable activated surface usable for bonding a 3D stacked chip. A fine-grain layer that resists self anneal enables metal to metal bonding at moderate time and temperature and wider process flexibility.

The present invention provides a stabilized fine textured metal microstructure that constitutes a durable activated surface usable for bonding a 3D stacked chip. A fine-grain layer that resists self anneal enables metal to metal bonding at moderate time and temperature and wider process flexibility.

The present invention provides a stabilized fine textured metal microstructure that constitutes a durable activated surface usable for bonding a 3D stacked chip. A fine-grain layer that resists self anneal enables metal to metal bonding at moderate time and temperature and wider process flexibility.

A method for bonding of a first, at least partially metallic contact surface of a first substrate to a second, at least partially metallic contact surface of a second substrate, with the following steps, especially the following progression: application of a sacrificial layer which is at least partially, especially predominantly soluble in the material of at least one of the contact surfaces to at least one of the contact surfaces, bonding of the contact surfaces with at least partial solution of the sacrificial layer in at least one of the contact surfaces.

A method for bonding of a first, at least partially metallic contact surface of a first substrate to a second, at least partially metallic contact surface of a second substrate, with the following steps, especially the following progression: application of a sacrificial layer which is at least partially, especially predominantly soluble in the material of at least one of the contact surfaces to at least one of the contact surfaces, bonding of the contact surfaces with at least partial solution of the sacrificial layer in at least one of the contact surfaces.

A method of bonding a first substrate to a second substrate includes disposing a first high melting point metal layer onto a first substrate, disposing a first low melting point metal layer onto the first high melting point metal layer, disposing a second high melting point metal layer onto a second substrate, and disposing a second low melting point metal layer onto the second high melting point metal layer. The method further includes applying precursor metal particles onto the first and/or second low melting point metal layers, positioning the first and second low melting point metal layers such that the precursor metal particles contact both the first and second low melting point metal layers, and bonding the first substrate to the second substrate by heating the precursor metal particles and each metal layer to form an intermetallic alloy bonding layer between the first and second substrates.

A method of bonding a first substrate to a second substrate includes disposing a first high melting point metal layer onto a first substrate, disposing a first low melting point metal layer onto the first high melting point metal layer, disposing a second high melting point metal layer onto a second substrate, and disposing a second low melting point metal layer onto the second high melting point metal layer. The method further includes applying precursor metal particles onto the first and/or second low melting point metal layers, positioning the first and second low melting point metal layers such that the precursor metal particles contact both the first and second low melting point metal layers, and bonding the first substrate to the second substrate by heating the precursor metal particles and each metal layer to form an intermetallic alloy bonding layer between the first and second substrates.

Bonded structures and method of forming the same are provided. A conductive layer is formed on a first surface of a bonded structure, the bonded structure including a first substrate bonded to a second substrate, the first surface of the bonded structure being an exposed surface of the first substrate. A patterned mask having first openings and second openings is formed on the conductive layer, the first openings and the second openings exposing portions of the conductive layer. First portions of first bonding connectors are formed in the first openings and first portions of second bonding connectors are formed in the second openings. The conductive layer is patterned to form second portions of the first bonding connectors and second portions of the second bonding connectors. The bonded structure is bonded to a third substrate using the first bonding connectors and the second bonding connectors.

Bonded structures and method of forming the same are provided. A conductive layer is formed on a first surface of a bonded structure, the bonded structure including a first substrate bonded to a second substrate, the first surface of the bonded structure being an exposed surface of the first substrate. A patterned mask having first openings and second openings is formed on the conductive layer, the first openings and the second openings exposing portions of the conductive layer. First portions of first bonding connectors are formed in the first openings and first portions of second bonding connectors are formed in the second openings. The conductive layer is patterned to form second portions of the first bonding connectors and second portions of the second bonding connectors. The bonded structure is bonded to a third substrate using the first bonding connectors and the second bonding connectors.

One example includes an electronic circuit package. The electronic circuit package includes a lead frame. The electronic circuit package includes an electronic circuit die disposed on the lead frame. The electronic circuit package includes a metal plate structure formed on the electronic circuit die, the metal plate structure comprising an aperture that extends through the metal plate structure from a first surface coupled to the electronic circuit die to a second surface opposite the first surface, and further comprising a tapered foot portion formed around a periphery of the metal plate structure at the first surface. The electronic circuit package includes a molding material covering the electronic circuit die around the metal plate structure.