A method of testing a semiconductor device includes providing a first wafer that includes a first surface, a second surface that is allocated at an opposite side of the first surface, a first electrode penetrating the first wafer from the first surface to the second surface, and a pad formed on the first surface and coupled electrically with the first electrode, providing a second wafer that includes a second electrode penetrating the second wafer, stacking the first wafer onto the second wafer to connect the first electrode with the second electrode such that the second surface of the first wafer faces the second wafer, probing a needle to the pad, and supplying, in such a state that the first wafer is stacked on the second wafer, a test signal to the first electrode to input the test signal into the second wafer via the first electrode and the second electrode.

A method of testing a semiconductor device includes providing a first wafer that includes a first surface, a second surface that is allocated at an opposite side of the first surface, a first electrode penetrating the first wafer from the first surface to the second surface, and a pad formed on the first surface and coupled electrically with the first electrode, providing a second wafer that includes a second electrode penetrating the second wafer, stacking the first wafer onto the second wafer to connect the first electrode with the second electrode such that the second surface of the first wafer faces the second wafer, probing a needle to the pad, and supplying, in such a state that the first wafer is stacked on the second wafer, a test signal to the first electrode to input the test signal into the second wafer via the first electrode and the second electrode.

A wire bonding method includes bonding a tip of a wire provided through a clamp and a capillary onto a bonding pad of a chip, moving the capillary to a connection pad of a substrate corresponding to the bonding pad, bonding the wire to the connection pad to form a bonding wire connecting the bonding pad to the connection pad, before the capillary is raised from the connection pad, applying a electrical signal to the wire to detect whether the wire and the connection pad are in contact with each other, changing a state of the clamp to a closed state when the wire is not in contact with the connection pad and maintaining the state of the clamp in an open state when the wire is in contact with the connection pad, and raising the capillary from the connection pad while maintaining the state of the clamp.

A semiconductor device and method for manufacturing the same are provided. The method includes providing a first substrate. The method also includes forming a first metal layer on the first substrate. The first metal layer includes a first metal material. The method further includes treating a first surface of the first metal layer with a solution including an ion of a second metal material. In addition, the method includes forming a plurality of metal particles including the second metal material on a portion of the first surface of the first metal layer.

A transistor includes first and second sets of gate fingers formed in an active area of a semiconductor substrate, an input bond pad formed in the semiconductor substrate and spaced apart from the active area, a first conductive structure with a proximal end coupled to the input bond pad and a distal end coupled to the first set of gate fingers, and a second conductive structure with a proximal end coupled to the input bond pad and a distal end coupled to the second set of gate fingers. A non-conductive gap is present between the distal ends of the first and second conductive structures. The transistor further includes an odd-mode oscillation stabilization circuit that includes a first resistor with a first terminal coupled to the distal end of the first conductive structure, and a second terminal coupled to the distal end of the second conductive structure.

A front-end method of fabricating nickel plated caps over copper bond pads used in a memory device. The method provides protection of the bond pads from an oxidizing atmosphere without exposing sensitive structures in the memory device to the copper during fabrication.

Methods of forming a microelectronic packaging structure are described. Those methods may include forming a solder paste comprising a sacrificial polymer on a substrate, curing the solder paste below a reflow temperature of the solder to form a solid composite hybrid bump on the conductive pads, forming a molding compound around the solid composite hybrid bump, and reflowing the hybrid bump, wherein the sacrificial polymer is substantially decomposed.

Methods of forming a microelectronic packaging structure are described. Those methods may include forming a solder paste comprising a sacrificial polymer on a substrate, curing the solder paste below a reflow temperature of the solder to form a solid composite hybrid bump on the conductive pads, forming a molding compound around the solid composite hybrid bump, and reflowing the hybrid bump, wherein the sacrificial polymer is substantially decomposed.

A semiconductor device (1,21) includes a solid state device (2,22), a semiconductor chip (3) that has a functional surface (3a) on which a functional element (4) is formed and that is bonded on a surface of the solid state device with the functional surface thereof facing the surface of the solid state device and while maintaining a predetermined distance between the functional surface thereof and the surface of the solid state device, an insulating film (6) that is provided on the surface (2a, 22a) of the solid state device facing the semiconductor chip and that has an opening (6a) greater in size than the semiconductor chip when the surface of the solid state device facing the semiconductor chip is vertically viewed down in plane, and a sealing layer (7) that seals a space between the solid state device and the semiconductor chip.

A semiconductor device (1,21) includes a solid state device (2,22), a semiconductor chip (3) that has a functional surface (3a) on which a functional element (4) is formed and that is bonded on a surface of the solid state device with the functional surface thereof facing the surface of the solid state device and while maintaining a predetermined distance between the functional surface thereof and the surface of the solid state device, an insulating film (6) that is provided on the surface (2a, 22a) of the solid state device facing the semiconductor chip and that has an opening (6a) greater in size than the semiconductor chip when the surface of the solid state device facing the semiconductor chip is vertically viewed down in plane, and a sealing layer (7) that seals a space between the solid state device and the semiconductor chip.