A method for bonding semiconductor dies, resulting semiconductor devices, and associated systems and methods are disclosed. In some embodiments, the method includes depositing a first material on the first semiconductor die. The first material has a first outer surface and a first chemical composition at the first outer surface. The method also includes depositing a second material on the second semiconductor die. The second material has a second outer surface and a second chemical composition at the second outer surface that is different from the first chemical composition. The method also includes stacking the dies. The second outer surface of the second semiconductor die is in contact with the first outer surface of the first semiconductor die in the stack. The method also includes reacting the first outer surface with the second outer surface. The reaction causes the first outer surface to bond to the second outer surface.

A heat dissipation structure of a semiconductor device with excellent heat dissipation applicable to surface-mount thin semiconductor devices is provided, and preferably a heat dissipation structure of a semiconductor device also with excellent insulating reliability is provided. In a heat dissipation structure 101 of a semiconductor device 10, the semiconductor device 10 has an electric bonding surface 11a electrically connected with a substrate 20 and a heat dissipation surface 11b on an opposite side thereof, wherein the heat dissipation surface 11b is bonded or contacted to a heat spreader 31 via a non-insulated member 32, and the heat spreader 31 is bonded or contacted to a heat sink 30 via an insulated member 41.

A thermally-conductive and mechanically-robust bonding method for attaching a metal nanowire (MNW) array to an adjacent surface includes the steps of: removing a template membrane from the MNW; infiltrating the MNW with a bonding material; placing the bonding material on the adjacent surface; bringing an adjacent surface into contact with a top surface of the MNW while the bonding material is bondable; and allowing the bonding material to cool and form a solid bond between the MNW and the adjacent surface. A thermally-conductive and mechanically-robust bonding method for attaching a metal nanowire (MNW) array to an adjacent surface includes the steps of: choosing a bonding material based on a desired bonding process; and without removing the MNW from a template membrane that fills an interstitial volume of the MNW, depositing the bonding material onto a tip of the MNW.

A semiconductor structure includes: a first semiconductor workpiece; a second semiconductor workpiece, bonded to a first surface of the first semiconductor workpiece, wherein the second semiconductor workpiece includes two adjacent semiconductor dies; a dielectric material, disposed between the two adjacent semiconductor dies; a first electrically conductive via, formed in the dielectric material and extended to electrically connect the first semiconductor workpiece; a third semiconductor workpiece, bonded to a second surface of the first semiconductor workpiece, the second surface being opposite to the first surface; and a second electrically conductive via, extended into the first semiconductor workpiece and substantially aligned with the first electrically conductive via such that the first electrically conductive via connects the second electrically conductive via.

A heat dissipation structure of a semiconductor device with excellent heat dissipation applicable to surface-mount thin semiconductor devices is provided, and preferably a heat dissipation structure of a semiconductor device also with excellent insulating reliability is provided. In a heat dissipation structure 101 of a semiconductor device 10, the semiconductor device 10 has an electric bonding surface 11a electrically connected with a substrate 20 and a heat dissipation surface 11b on an opposite side thereof, wherein the heat dissipation surface 11b is bonded or contacted to a heat spreader 31 via a non-insulated member 32, and the heat spreader 31 is bonded or contacted to a heat sink 30 via an insulated member 41.

A semiconductor structure includes: a first semiconductor workpiece; a second semiconductor workpiece, bonded to a first surface of the first semiconductor workpiece, wherein the second semiconductor workpiece includes two adjacent semiconductor dies; a dielectric material, disposed between the two adjacent semiconductor dies; a first electrically conductive via, formed in the dielectric material and extended to electrically connect the first semiconductor workpiece; a third semiconductor workpiece, bonded to a second surface of the first semiconductor workpiece, the second surface being opposite to the first surface; and a second electrically conductive via, extended into the first semiconductor workpiece and substantially aligned with the first electrically conductive via such that the first electrically conductive via connects the second electrically conductive via.

A semiconductor structure and a method for forming the same are provided. The method comprises: providing a first semiconductor workpiece; bonding a second semiconductor workpiece to a first surface of the first semiconductor workpiece; forming a first electrically conductive via through the second semiconductor workpiece to the first semiconductor workpiece; bonding a third semiconductor workpiece to a second surface of the first semiconductor workpiece, the second surface being opposite to the first surface; and forming a second electrically conductive via through the first semiconductor workpiece and the third semiconductor workpiece to the second semiconductor workpiece such that the first electrically conductive via and the second electrically conductive via are electrically connected.

A semiconductor structure and a method for forming the same are provided. The method comprises: providing a first semiconductor workpiece; bonding a second semiconductor workpiece to a first surface of the first semiconductor workpiece; forming a first electrically conductive via through the second semiconductor workpiece to the first semiconductor workpiece; bonding a third semiconductor workpiece to a second surface of the first semiconductor workpiece, the second surface being opposite to the first surface; and forming a second electrically conductive via through the first semiconductor workpiece and the third semiconductor workpiece to the second semiconductor workpiece such that the first electrically conductive via and the second electrically conductive via are electrically connected.

A thermally-conductive and mechanically-robust bonding method for attaching a metal nanowire (MNW) array to an adjacent surface includes the steps of: removing a template membrane from the MNW; infiltrating the MNW with a bonding material: placing the bonding material on the adjacent surface; bringing an adjacent surface into contact with a top surface of the MNW while the bonding material is bondable; and allowing the bonding material to cool and form a solid bond between the MNW and the adjacent surface. A thermally-conductive and mechanically-robust bonding method for attaching a metal nanowire (MNW) array to an adjacent surface includes the steps of: choosing a bonding material based on a desired bonding process; and without removing the MNW from a template membrane that fills an interstitial volume of the MNW, depositing the bonding material onto a tip of the MNW.

A method of and system for adhesive bonding. The method and system a) treat a surface of an element to be bonded to provide an adherent structure including one or more rubber compounds on the surface; b) place a polymerizable adhesive composition, including at least one photoinitiator and at least one energy converting material, in contact with the adherent structure and two or more components to be bonded to form an assembly, c) irradiated the assembly with radiation at a first wavelength, capable of conversion by the at least one energy converting material, to a second wavelength capable of activating the at least one photoinitiator to produce from the polymerizable adhesive composition a cured adhesive composition; and d) adhesively join the two or more components by way of the adherent structure and the cured adhesive composition.