A method of making a secure integrated-circuit system comprises providing a first integrated circuit in a first die having a first die size and providing a second integrated circuit in a second die. The second die size is smaller than the first die size. The second die is transfer printed onto the first die and connected to the first integrated circuit, forming a compound die. The compound die is packaged. The second integrated circuit is operable to monitor the operation of the first integrated circuit and provides a monitor signal responsive to the operation of the first integrated circuit. The first integrated circuit can be constructed in an insecure facility and the second integrated circuit can be constructed in a secure facility.

An embodiment of the present invention provides a method for producing a bonded object. The method comprises a step for preparing a laminate in which a first member, a copper bonding paste, and a second member are laminated in order and a step for sintering the copper bonding paste under a pressure of 0.1-1 MPa. The copper bonding paste contains metal particles and a dispersion medium, wherein the content of metal particles is at 50 mass % or more with respect to the total mass of the copper bonding paste, and the metal particles contain 95 mass % or more of submicro copper particles with respect to the total mass of the metal particles.

Processes for adjusting dimensions of dielectric bond line materials in stacks of microelectronic components to prevent extrusion of the dielectric bond line materials beyond component peripheries during thermocompression bonding by patterning the materials with boundary portions inset from component peripheries, or employing an inset dielectric material surrounded by another solidified dielectric material. Related material films, articles and assemblies are also disclosed.

This member connection method includes a printing step. In the printing step, a coating film-formed region in which the coating film is formed, and a coating film non-formed region in which the coating film is not formed are formed in the print pattern, and the coating film-formed region is divided into a plurality of concentric regions and a plurality of radial regions by means of a plurality of line-shaped regions provided so as to connect various points, which are separated apart from one another in the marginal part of the connection region.

This member connection method includes a printing step. In the printing step, a coating film-formed region in which the coating film is formed, and a coating film non-formed region in which the coating film is not formed are formed in the print pattern, and the coating film-formed region is divided into a plurality of concentric regions and a plurality of radial regions by means of a plurality of line-shaped regions provided so as to connect various points, which are separated apart from one another in the marginal part of the connection region.

Techniques of protecting cored or coreless semiconductor packages having materials formed from dissimilar metals from galvanic corrosion are described. An exemplary semiconductor package comprises one or more build-up layers; first and second semiconductor components (e.g., die, EMIB, etc.) on or embedded in the one or more build-up layers. The first semiconductor component may be electrically coupled to the second semiconductor component via a contact pad and an interconnect structure that are formed in the one or more build-up layers. The contact pad can comprise a contact region, a non-contact region, and a gap region that separates the contact region from the non-contact region. Coupling of the contact pad and an interconnect structure is performed by coupling only the contact region with the interconnect structure. Also, a surface area of the contact region can be designed to substantially equal to a surface area of the interconnect structure.

Techniques of protecting cored or coreless semiconductor packages having materials formed from dissimilar metals from galvanic corrosion are described. An exemplary semiconductor package comprises one or more build-up layers; first and second semiconductor components (e.g., die, EMIB, etc.) on or embedded in the one or more build-up layers. The first semiconductor component may be electrically coupled to the second semiconductor component via a contact pad and an interconnect structure that are formed in the one or more build-up layers. The contact pad can comprise a contact region, a non-contact region, and a gap region that separates the contact region from the non-contact region. Coupling of the contact pad and an interconnect structure is performed by coupling only the contact region with the interconnect structure. Also, a surface area of the contact region can be designed to substantially equal to a surface area of the interconnect structure.

Die-substrate assemblies having sinter-bonded backside via structures, and methods for fabricating such die-substrate assemblies, are disclosed. In embodiments, the method includes obtaining an integrated circuit (IC) die having a backside over which a backmetal layer is formed and into which a plated backside via extends. The IC die is attached to an electrically-conductive substrate by: (i) applying sinter precursor material over the backmetal layer and into the plated backside via; (ii) positioning a frontside of the electrically-conductive substrate adjacent the plated backmetal layer and in contact with the sinter precursor material; and (iii) sintering the sinter precursor material to yield a sintered bond layer attaching and electrically coupling the IC die to the frontside of the electrically-conductive substrate through the backmetal layer and through the plated backside via. The sintered bond layer contacts and is metallurgically bonded to the backside via lining.

Die-substrate assemblies having sinter-bonded backside via structures, and methods for fabricating such die-substrate assemblies, are disclosed. In embodiments, the method includes obtaining an integrated circuit (IC) die having a backside over which a backmetal layer is formed and into which a plated backside via extends. The IC die is attached to an electrically-conductive substrate by: (i) applying sinter precursor material over the backmetal layer and into the plated backside via; (ii) positioning a frontside of the electrically-conductive substrate adjacent the plated backmetal layer and in contact with the sinter precursor material; and (iii) sintering the sinter precursor material to yield a sintered bond layer attaching and electrically coupling the IC die to the frontside of the electrically-conductive substrate through the backmetal layer and through the plated backside via. The sintered bond layer contacts and is metallurgically bonded to the backside via lining.

Invention compositions are a replacement for high melting temperature solder pastes and preforms in high operating temperature and step-soldering applications. In the use of the invention, a mixture of metallic powders reacts below 350 degrees C. to form a dense metallic joint that does not remelt at the original process temperature.