Abstract: Provided are a bonded structure by a lead-free solder and an electronic article comprising the bonded structure. The bonded structure has a stable bonding interface with respect to a change in process of time, an enough strength and resistance to occurrence of whiskers while keeping good wettability of the solder. In the bonded structure, a lead-free Sn—Ag—Bi alloy solder is applied to an electrode through an Sn—Bi alloy layer. The Sn—Bi alloy, preferably, comprises 1 to 20 wt % Bi in order to obtain good wettability of the solder. In order to obtain desirable bonding characteristics having higher reliability in the invention, a copper layer is provided under the Sn—Bi alloy layer thereby obtaining an enough bonding strength.

Abstract: In a semiconductor device having a three-layered buffer layer comprising core layer 1 having interconnected foams such as a three-dimensional reticular structure and adhesive layers 2 proved on both sides of the core layer as a stress buffer layer between semiconductor chip 5 and wiring 4 to lessen a thermal stress generated between the semiconductor device and the package substrate, where a thickness ratio of core layer 1 to total buffer layer is at least 0.2, the production process can be simplified by using such a buffer layer, thereby improving the mass production capacity and enhancing the package reliability.

Abstract: A ball grid array type semiconductor package includes a semiconductor chip formed with bonding pads, an elastomer bonded to the semiconductor chip, a flexible wiring substrate bonded to the elastomer and formed with wirings connected at one end of the bonding pads of the semiconductor chip, a solder resist formed on the main surface of the flexible wiring substrate and solder bump electrodes connected to the other ends of the wirings. The elastomer is bonded to the flexible wiring substrate on the side of the tape, the solder resist is formed on the side of the wirings, and the solder bump electrodes are connected with the wirings by way of through holes formed in the solder resist.

Abstract: Disclosed is a technique capable of enhancing the degree of freedom in the layout of a rerouting layer in a wafer level CSP in which defect repairing is performed by cutting a fuse. More specifically, after the defect repairing is performed by irradiating a laser beam to a fuse, an organic passivation layer (photo-sensitive polyimide layer) is filled in a fuse opening. Thereafter, a rerouting layer, a bump land, an uppermost wiring layer, and a solder bump are formed on the organic passivation layer. In the following steps of the defect repairing, the baking process to cure an elastomer layer and the uppermost protection layer is conducted at a temperature below 260° C. in order to prevent the variance of the refresh times of memory cells.

Abstract: A semiconductor device which can improve the connection reliability of solder bumps and productivity in manufacturing. Insulating tape having wiring patterns on its surface is bond ed to a lead frame. Semiconductor elements are loaded and circuit formed surfaces and sides of the semiconductor elements are sealed with sealing resin. After arrangements of individual semiconductor devices are formed, the lead frame is separated into individual metal plates to form individual semiconductor devices. Such simultaneous production of a plurality of semiconductor devices enhances productivity, and improves flatness of the insulating tape, whereby the connection reliability of solder bumps is improved.

Abstract: A semiconductor device which can improve the connection reliability of solder bumps and productivity in manufacturing. Insulating tape having wiring patterns on its surface is bonded to a lead frame. Semiconductor elements are loaded and circuit formed surfaces and sides of the semiconductor elements are sealed with sealing resin. After arrangements of individual semiconductor devices are formed, the lead frame is separated into individual metal plates to form individual semiconductor devices. Such simultaneous production of a plurality of semiconductor devices enhances productivity, and improves flatness of the insulating tape, whereby the connection reliability of solder bumps is improved.

Abstract: A semiconductor device and a manufacturing method thereof, which device includes a semiconductor element arranged to form integrated circuitry, a plurality of electrode pads formed on the side of the integrated circuitry formation surface of the semiconductor element, bump electrodes for electrically connecting to the electrode pads through a conductive layer, and a stress relaxation layer formed between the integrated circuitry formation surface and electrode pads on one hand and the bump electrodes and conductive layer on the other hand, the stress relaxation layer being adhered thereto, wherein more than one third of the stress relaxation layer from a surface thereof is cut away for removal and wherein the stress relaxation layer is subdivided into a plurality of regions. Accordingly, it is possible to provide a semiconductor device capable of offering high density mounting schemes with increased reliability while reducing production costs.

Abstract: Described herein is a stacked package according to the present invention, wherein a plurality of tape carriers which seal semiconductor chips, are multilayered in upward and downward directions. In the stacked package, one ends of leads formed over the whole surfaces of each tape carrier are electrically connected to their corresponding connecting terminals of the semiconductor chip. Other ends of the leads are electrically connected to their corresponding through holes defined in the tape carrier. Connecting terminals common to the plurality of semiconductor chips are formed at the same places of the plurality of tape carriers and withdrawn to the same external connecting terminals through a plurality of mutually-penetrated through holes.

Abstract: In a semiconductor device having a three-layered buffer layer comprising core layer 1 having interconnected foams such as a three-dimensional reticular structure and adhesive layers 2 provided on both sides of the core layer as a stress buffer layer between semiconductor chip 5 and wiring 4 to lessen a thermal stress generated between the semiconductor device and the package substrate, where a thickness ratio of core layer 1 to total buffer layer is at least 0.2, the production process can be simplified by using such a buffer layer, thereby improving the mass production capacity and enhancing the package reliability.

Abstract: A semiconductor integrated circuit device includes a semiconductor substrate, a circuit element formed on one major surface of the semiconductor substrate and constituting an integrated circuit having a plurality of functions or a plurality of characteristics, an internal connection terminal, connected to the integrated circuit, for selecting one of the plurality of functions or one of the characteristics in the integrated circuit, an insulating layer covering the internal connection terminal such that the internal connection terminal is selectively exposed, and an external connection terminal arranged on the insulating layer. One of the plurality of functions or one of the plurality of characteristics is selected by a connection state between the internal connection terminal and the external connection terminal.

Abstract: Described herein is a stacked package according to the present invention, wherein a plurality of tape carriers which seal semiconductor chips, are multilayered in upward and downward directions. In the stacked package, one ends of leads formed over the whole surfaces of each tape carrier are electrically connected to their corresponding connecting terminals of the semiconductor chip. Other ends of the leads are electrically connected to their corresponding through holes defined in the tape carrier. Connecting terminals common to the plurality of semiconductor chips are formed at the same places of the plurality of tape carriers and withdrawn to the same external connecting terminals through a plurality of mutually-penetrated through holes.

Abstract: The present invention provides a method of forming bumps capable of forming many bumps having an adequate volume and having a narrow range of variations in height and few limitations in selecting materials on an object such as a semiconductor device or the like at high production rates with high reliability and with ease, and a system therefor. The present invention uses a suction head using a porous plate and a stencil having many apertures. Solder balls are previously aligned and charged into the stencil. The solder balls and the stencil are sucked and retained by the suction head and then are positioned with respect to the surfaces of the pads of a semiconductor device and only the solder balls are dropped on the pads. The solder balls are fixed to the pads with an adhesive previously applied thereto and then are reflowed to form bumps.

Abstract: A ball grid array type semiconductor package includes a semiconductor chip formed with bonding pads, an elastomer bonded to the semiconductor chip, a flexible wiring substrate bonded to the elastomer and formed with wirings connected at one end of the bonding pads of the semiconductor chip, a solder resist formed on the main surface of the flexible wiring substrate and solder bump electrodes connected to the other ends of the wirings. The elastomer is bonded to the flexible wiring substrate on the side of the tape, the solder resist is formed on the side of the wirings, and the solder bump electrodes are connected with the wirings by way of through holes formed in the solder resist.

Abstract: In the conventional bump forming method that can be applied to a semiconductor device in which a large number of bumps are required to form, there are various limitations to the material of which the bumps are made, to enough cubic volume of bumps and to small scattering of the bump height. According to the invention, solder balls and a tool having a large number of through-holes are used, and under the condition that the through-holes of the tool are aligned with the pads of the semiconductor device, the solder balls are charged into the through-holes, pressed to be fixed on the pads, and then reflowed to form bumps.

Abstract: A ball grid array type semiconductor package includes a semiconductor chip formed with bonding pads, an elastomer bonded to the semiconductor chip, a flexible wiring substrate bonded to the elastomer and formed with wirings connected at one end of the bonding pads of the semiconductor chip, a solder resist formed on the main surface of the flexible wiring substrate and solder bump electrodes connected to the other ends of the wirings. The elastomer is bonded to the flexible wiring substrate on the side of the tape, the solder resist is formed on the side of the wirings, and the solder bump electrodes are connected with the wirings by way of through holes formed in the solder resist.

Abstract: A ball grid array type semiconductor package includes a semiconductor chip formed with bonding pads, an elastomer bonded to the semiconductor chip, a flexible wiring substrate bonded to the elastomer and formed with wirings connected at one end of the bonding pads of the semiconductor chip, a solder resist formed on the main surface of the flexible wiring substrate and solder bump electrodes connected to the other ends of the wirings. The elastomer is bonded to the flexible wiring substrate on the side of the tape, the solder resist is formed on the side of the wirings, and the solder bump electrodes are connected with the wirings by way of through holes formed in the solder resist.

Abstract: The object of the present invention is to realize a semiconductor device enabling a flip chip connection without use of underfill.

Abstract: A ball grid array type semiconductor package includes a semiconductor chip formed with bonding pads, an elastomer bonded to the semiconductor chip, a flexible wiring substrate bonded to the elastomer and formed with wirings connected at one end of the bonding pads of the semiconductor chip, a solder resist formed on the main surface of the flexible wiring substrate and solder bump electrodes connected to the other ends of the wirings. The elastomer is bonded to the flexible wiring substrate on the side of the tape, the solder resist is formed on the side of the wirings, and the solder bump electrodes are connected with the wirings by way of through holes formed in the solder resist.

Abstract: A semiconductor device includes a semiconductor element arranged to form integrated circuitry, a plurality of electrode pads formed on the side of the integrated circuitry formation surface of the in semiconductor element, bump electrodes for external connection electrically connected to the electrode pads through a conductive layer, and a stress relaxation layer formed between the integrated circuitry formation surface and electrode pads on one hand and the bump electrodes and conductive layer on the other hand, the stress relaxation layer being adhered thereto, wherein more than one third of the stress relaxation layer from a surface thereof is cut away for removal and wherein the stress relaxation layer is subdivided into a plurality of regions.

Abstract: A semiconductor device includes a semiconductor chip and a printed circuit board. Metal electrodes of the semiconductor chip and the internal connection terminals of the printed circuit board are electrically connected through the metallic joining via precious metal bumps. A melting point of a metal material constituting each of the metallic joining parts is equal to or higher than 275 degrees, and a space defined between the chip and the board is filled with resin (under fill) containing 50 vol % or more inorganic fillers.