Abstract: A semiconductor wafer comprising: a tubular trench formed at a position to form a through-hole electrode of a wafer; an insulating member buried inside the trench and on an upper surface of the trench; a gate electrode film and a metal film formed on an upper surface of the insulating member; a multilevel columnar wiring via formed on an upper surface of the metal film; and an external connection electrode formed electrically connected to the metal film via the multilevel columnar wiring via. In this manner, it is unnecessary to have a new process of dry etching to form a through-hole electrode after thinning the wafer and equipment development. Moreover, introduction of a specific design enables formation of through-hole electrodes with significantly reduced difficulties of respective processes.

Abstract: In a semiconductor device having a Low-k film as an interlayer insulator, peeling of the interlayer insulator in a thermal cycle test is prevented, thereby providing a highly reliable semiconductor device. In a semiconductor device having a structure in which interlayer insulators in which buried wires each having a main electric conductive layer made of copper are formed and cap insulators of the buried wires are stacked, the cap insulator having a relatively high Young's modulus and contacting by its upper surface with the interlayer insulator made of a Low-k film having a relatively low Young's modulus is formed so as not to be provided in an edge portion of the semiconductor device.

Abstract: A semiconductor wafer comprising: a tubular trench formed at a position to form a through-hole electrode of a wafer; an insulating member buried inside the trench and on an upper surface of the trench; a gate electrode film and a metal film formed on an upper surface of the insulating member; a multilevel columnar wiring via formed on an upper surface of the metal film; and an external connection electrode formed electrically connected to the metal film via the multilevel columnar wiring via. In this manner, it is unnecessary to have a new process of dry etching to form a through-hole electrode after thinning the wafer and equipment development. Moreover, introduction of a specific design enables formation of through-hole electrodes with significantly reduced difficulties of respective processes.

Abstract: In a state where an adhesive tape is attached onto a main surface of a semiconductor wafer, a trench is formed in a rear surface of the semiconductor wafer. For forming the trench in the rear surface of the semiconductor wafer, after coating a resist film on the rear surface of the semiconductor wafer, the resist film is patterned by using the photolithography technology. The patterning of the resist film is performed so as not to leave the resist film in the region where the trench is to be formed. Then, the trench is formed in a predetermined region of the semiconductor wafer by the dry etching technology using the patterned resist film as a mask. Specifically, the trench is formed in the region near the dicing line.

Abstract: A semiconductor wafer comprising: a tubular trench formed at a position to form a through-hole electrode of a wafer; an insulating member buried inside the trench and on an upper surface of the trench; a gate electrode film and a metal film formed on an upper surface of the insulating member; a multilevel columnar wiring via formed on an upper surface of the metal film; and an external connection electrode formed electrically connected to the metal film via the multilevel columnar wiring via. In this manner, it is unnecessary to have a new process of dry etching to form a through-hole electrode after thinning the wafer and equipment development. Moreover, introduction of a specific design enables formation of through-hole electrodes with significantly reduced difficulties of respective processes.

Abstract: In order to implement a high-density high-performance semiconductor system small in size, there is provided a method for implementing three-dimensional connection between a plurality of semiconductor chips differing from each other with the shortest metal interconnect length, using penetration electrodes, thereby enabling a fast operation at a low noise level, the method being a three-dimensional connection method very low in cost, and short in TAT in comparison with the known example, capable of bonding at an ordinary temperature, and excellent in connection reliability.

Abstract: In a semiconductor device in which a plurality of semiconductor chips are stacked, performance is enhanced without deteriorating productivity. The semiconductor device has a plurality of elements, an interlayer insulating film, a pad, and a bump electrode electrically connected with the pad sequentially formed on a main surface of a silicon substrate and has a back-surface electrode formed on a back surface of the silicon substrate and electrically connected with the bump electrode. The bump electrode has a protruding portion penetrating through the pad and protruding toward the silicon substrate side. The back-surface electrode is formed so as to reach the protruding portion of the bump electrode from the back surface side of the silicon substrate toward the main surface side and to cover the inside of a back-surface-electrode hole portion which does not reach the pad, so that the back-surface electrode is electrically connected with the bump electrode.

Abstract: A semiconductor device is provided with connection reliability between a bump electrode and a substrate electrode. An elastic modulus of an adhesive material used to electrically connect a metal bump and an interconnect pattern, and sealing the circuit surface of an LSI chip, after thermosetting is Ea; an elastic modulus of an insulating material of a packaging substrate surface layer after thermosetting is Eb; an elastic modulus of a core material, if used, is Ec, and the following rational expression is satisfied at normal temperature or a thermal contact bonding temperature of the adhesive material: at least Ea<Eb<Ec, preferably ?Eb<Ea<Eb<3Ea(<Ec). With this arrangement, a stable connection state can be attained irrespective of the level of the contact bonding load or fluctuations of it upon mass production and, therefore, high yield can be attained at low cost.

Abstract: Heating elements different in heat generating timing are laminated in a stacked state, and the heating element close to a wiring substrate is allowed to function as a heat diffusion plate for another heating element.

Abstract: When a through-hole electrode and a rear-surface wire are formed on a rear surface of a chip, a convex portion is formed on the rear surface of the chip due to a rear-surface wiring pad which is a part of the through-hole electrode and the rear-surface wire. This causes the air leakage when the chip is sucked, and therefore, the reduction of the sucking force of the chip occurs. A concave portion is formed in advance in a region where a rear-surface wiring pad and a rear-surface wire are formed. The rear-surface wiring pad and the rear-surface wire are provided inside the concave portion. Thus, a flatness of the rear surface of the chip is ensured by a convex portion caused by thicknesses of the rear-surface wiring pad and the rear-surface wire, so that the reduction of the sucking force does not occur when the chip is handled.

Abstract: In a semiconductor device having a Low-k film as an interlayer insulator, peeling of the interlayer insulator in a thermal cycle test is prevented, thereby providing a highly reliable semiconductor device. In a semiconductor device having a structure in which interlayer insulators in which buried wires each having a main electric conductive layer made of copper are formed and cap insulators of the buried wires are stacked, the cap insulator having a relatively high Young's modulus and contacting by its upper surface with the interlayer insulator made of a Low-k film having a relatively low Young's modulus is formed so as not to be provided in an edge portion of the semiconductor device.

Abstract: After forming a ring-shaped trench penetrating through a semiconductor substrate from a rear surface side thereof and forming an insulating film inside the trench and on the rear surface of the semiconductor substrate, a through hole is formed in the insulating film and semiconductor substrate on an inner side of the ring-shaped trench from the rear surface side, thereby exposing a surface protection insulating film formed on a front surface of the semiconductor substrate at a bottom of the through hole. After removing the surface protection insulating film at the bottom of the through hole to form an opening to expose an element surface electrode, a contact electrode connected to the element surface electrode is formed on inner walls of the through hole and opening, and a pad electrode made of the same layer as the contact electrode is formed on the rear surface of the semiconductor substrate.

Abstract: A through silicon via reaching a pad from a second surface of a semiconductor substrate is formed. A penetration space in the through silicon via is formed of a first hole and a second hole with a diameter smaller than that of the first hole. The first hole is formed from the second surface of the semiconductor substrate to the middle of the interlayer insulating film. Further, the second hole reaching the pad from the bottom of the first hole is formed. Then, the interlayer insulating film formed on the first surface of the semiconductor substrate has a step shape reflecting a step difference between the bottom surface of the first hole and the first surface of the semiconductor substrate. More specifically, the thickness of the interlayer insulating film between the bottom surface of the first hole and the pad is smaller than that in other portions.

Abstract: The quality and reliability of a semiconductor device can be improved by eliminating a warp of a chip and performing a chip-stack. A wiring substrate, the first semiconductor chip connected via the first gold bump on the wiring substrate, the second semiconductor chip stacked via the second gold bump on the first semiconductor chip, and a sealing body are comprised. A first gold bump is connected to the wiring substrate, heating, and injection by pressure welding of the first gold bump is done under normal temperature after that at the hole-like electrode of the first semiconductor chip. Since injection by pressure welding of the second gold bump of the second semiconductor chip is done under normal temperature into the hole-like electrode of the first semiconductor chip and the second semiconductor chip is stacked, the chip-stack can be performed under normal temperature.

Abstract: A semiconductor device has a semiconductor chip including first and second surfaces opposed to each other in a thickness direction of the semiconductor chip, wherein the first and second surfaces include first and second electrode surfaces respectively, and first and second electrically conductive members covering the first and second electrode surfaces respectively as seen in the thickness direction to be electrically connected to the first and second electrode surfaces respectively.

Abstract: In a semiconductor device adapted to be mounted on a board and to be electrically connected to the board, comprising, at least two semiconductor electric chips, and a substrate on which the semiconductor electric chips are mounted and to which the semiconductor electric chips are electrically connected, in such a manner that the semiconductor electric chips are mounted on and electrically connected to the board through the substrate, according to the present invention, a thickness of each of the semiconductor electric chips in a direction in which the each of the semiconductor electric chips and the substrate are stacked is smaller than a thickness of the substrate in the direction.

Abstract: A semiconductor wafer comprising: a tubular trench formed at a position to form a through-hole electrode of a wafer; an insulating member buried inside the trench and on an upper surface of the trench; a gate electrode film and a metal film formed on an upper surface of the insulating member; a multilevel columnar wiring via formed on an upper surface of the metal film; and an external connection electrode formed electrically connected to the metal film via the multilevel columnar wiring via. In this manner, it is unnecessary to have a new process of dry etching to form a through-hole electrode after thinning the wafer and equipment development. Moreover, introduction of a specific design enables formation of through-hole electrodes with significantly reduced difficulties of respective processes.

Abstract: A connection method is disclosed for a high-performance semiconductor system. The connection method enables high-speed operation with low noise, so as to obtain reliable and excellent connection in a short TAT at low costs. Semiconductor chips and the interposer chips are polished by grinding at their rear surfaces, holes are formed at rear surface positions corresponding to external electrode parts on the device side (front surface side) so that the holes extend to front surface electrodes, and metal plating films are applied to the side walls of the holes and rear surface side. Metal bumps of another semiconductor chip laminated at an upper stage being press-fitted into the holes applied with the metal plating films through deformation and being geometrically calked in the through holes formed in the semiconductor chip so as to electrically connected thereto.

Abstract: An object of the present invention is to establish, for an LSI having a stacked interconnection structure of Cu interconnect/Low-k material, a narrow pitch wire bonding technique enabling a reduction in damage to a bonding pad and application similar to the conventional LSI of an aluminum interconnection. In a semiconductor device having a multilayer interconnection made of a Cu interconnect/Low-k dielectric material, the above-described object can be attained by a bonding pad structure in which all the wiring layers up to the uppermost cap interconnect are formed of a Cu wiring layer and a bonding pad portion formed of a Cu layer is equipped with a refractory intermediate metal layer such as Ti (titanium) filmor (tungsten) film on the Cu layer and an aluminum alloy layer on the intermediate metal layer.

Abstract: A semiconductor chip production method including the steps of: forming a front side recess in a semiconductor substrate; depositing a metal material in the front side recess to form a front side electrode electrically connected to a functional device formed on the front surface; removing a rear surface portion of the semiconductor substrate to reduce the thickness of the semiconductor substrate to a thickness greater than the depth of the front side recess; forming a rear side recess communicating with the front side recess in the rear surface of the semiconductor substrate after the thickness reducing step; and depositing a metal material in the rear side recess to form a rear side electrode electrically connected to the front side electrode for formation of a through-electrode.