Abstract: An integrated circuit inductance and the fabrication method thereof are disclosed. The manufacture process provided by the present invention fabricates an integrated circuit inductance having a simple production process, low cost, a near equal loop size and good performance, due to making the order of the planarization processes of the inductance loops substantially perpendicular to the wafer and the direction of the current of the inductance substantially in parallel with the wafer, by way of the manufacture process of the plugs and the conductive wires of the integrated-circuit process.

Abstract: A bumping process is disclosed. The bumping process comprises the steps of: providing a wafer having a plurality of bonding pads and a passivation layer, wherein the passivation layer exposes the bonding pads; forming an UBM layer over the wafer to cover the bonding pads; forming two or more photoresist layers over the wafer, wherein the photoresist layers have different exposure and development characteristics; forming at least one or more stair-shaped openings in the photoresist layers by a single exposure corresponding to the bonding pads; filling solder into the stair-shaped openings to form a plurality of solder bumps; removing the entire photoresist layer. The bumping process can provide bumps with higher heights, so that the connection between chips and carriers becomes more reliable.

Abstract: An under bump metallurgy structure is applicable to be disposed above the wafer and on the bonding pads of the wafer. The wafer comprises a passivation layer and an under bump metallurgy structure. The passivation layer exposes the wafer pads, and the under bump metallurgy structure including an adhesive layer, a first barrier layer, a wetting layer and a second barrier layer are sequentially formed on the bonding pads. Specifically, the material of the second barrier mainly includes lead.

Abstract: A semiconductor device with a capability can prevent a burnt fuse pad from re-electrical connection, wherein the semiconductor device includes a bump pad and a fuse pad over a wafer. The fuse pad includes the burnt fuse pad having a gap for electrical isolation. The semiconductor device comprises a dielectric layer, disposed substantially above the burnt fuse pad and filling the gap, and a bump structure, disposed on the bump pad. The foregoing semiconductor device can further comprise a passivation layer, which exposes the bump pad and a portion of the burnt fuse pad. Wherein, the dielectric layer is over the passivation layer, covers the exposed portion of the burnt fuse pad and fills the gap.

Abstract: A wafer-level package structure, applicable to a flip-chip type arrangement on a carrier having a plurality of contact points is described. This wafer-level package structure comprises a chip having a protective layer and a plurality of bonding pads and a conductive layer. The conductive layer is arranged on the bonding pads of the chip as contact points. The wafer-level package structure can further include a heat sink to enhance the heat dissipation ability of the package structure.

Abstract: A wafer bumping process is disclosed. A wafer having a plurality of bonding pads formed thereon is provided. A first under bump metallurgy layer is formed to cover the bonding pads. A first patterned photoresist layer having a plurality of first openings is formed on the first under bump metallurgy layer, wherein a portion of the first under bump metallurgy layer is exposed within the first openings. A second under bump metallurgy layer is formed within the first openings, wherein the second under bump metallurgy layer is much thicker than the first under bump metallurgy layer. A second patterned photoresist layer having a plurality of second openings is formed on the first patterned photoresist layer, wherein the second openings being larger than the first openings.

Abstract: A method of forming a plurality of bumps over a wafer. The wafer has an active surface having a passivation layer and a plurality of contact pads thereon. The passivation layer exposes the contact pads on the active surface. An adhesion layer is formed over the active surface of the wafer and covers both the contact pads and the passivation layer. A metallic layer is formed over the adhesion layer. The adhesion layer and the metallic layer are patterned so that the adhesion layer and the metallic layer remain on top of the contact pads. A photoresist layer is formed on the active surface of the wafer. The photoresist layer has a plurality of openings that expose the metallic layer. Flux material is deposited into the openings and then a solder block is disposed into each of the openings. A reflow process is carried out so that the solder block bonds with the metallic layer. Finally, the flux material and the photoresist layer are removed.

Abstract: The present invention provides a method of forming a plurality of bumps over a wafer. The wafer has a plurality of contact pads and a passivation layer thereon and the passivation layer exposes the contact pads. An adhesion layer is formed over the active surface of the wafer and covers both the contact pads and the passivation layer. A metallic layer is formed over the adhesion layer. The patterned adhesion layer and patterned metallic layer remain on top of the contact pads. A photoresist layer having a plurality of openings that expose the metallic layer is formed on the active surface of the wafer. A flux material is deposited into the openings and then a solder block is disposed into each of the openings. A reflow process is performed to bond the solder block with the metallic layer. Finally, the flux material and the photoresist layer are removed.

Abstract: A method of modifying the tin to lead ratio of a tin-lead bump forms a patterned solder mask over a substrate that comprises a first tin-lead bump formed thereon, the patterned solder mask having an opening that exposes the tin-lead bump. A solder material including tin and lead is filled in the opening of the solder mask over the first tin-lead bump. The solder material has a tin to lead ratio that differs from that of the first tin-lead bump. The solder material is reflowed to fuse with the first tin-lead bump, which forms a second tin-lead bump. The tin to lead ratio of the second tin-lead bump is thereby different from that of the first tin-lead bump.

Abstract: A method of forming a bump on an active surface of a wafer is disclosed. The method of the invention forms an under ball metallurgy (UBM) onto the active surface of the wafer. Then, the UBM is partially removed until a portion of the active surface of the wafer is exposed. At least one conductive stud is bonded onto the non-removed UBM by wire bonding.

Abstract: A method for mounting a passive component on a wafer. A passivation layer is disposed on a wafer having at least one first metal pad and at least one second metal pad thereon, which substantially exposes the first and second metal pads. A capping layer is formed on the exposed first metal pad, and an under ball metallurgy (UBM) layer is formed on the exposed second metal pad. A photoresist pattern layer is formed overlying the wafer to cover the capping layer and the passivation layer and expose the UBM layer. A solder bump is formed on the exposed UBM layer. After the photoresist pattern layer and the capping layer are successively removed, a passive component is mounted on the wafer through the solder bump.

Abstract: A method for forming a solder bump structure with increased height. A substrate having at least one metal bonding pad thereon is provided. A passivation layer is formed on the substrate, which substantially exposes the metal bonding pad. An under ball metallurgy (UBM) layer is formed on the exposed metal bonding pad. A dielectric layer and a resist layer are successively formed on the passivation layer, wherein the dielectric layer has a first opening to expose the UBM layer and the resist layer a second opening over the first opening. A solder bump is formed on the UBM layer in the first and second openings, and the resist layer is then removed.

Abstract: A solder ball fabricating process for forming solder balls over a wafer having an active layer is provided. A patterned solder mask layer is formed over the active surface of the wafer. The patterned solder mask layer has an opening that exposes a bonding pad on the wafer. Solder material is deposited into the opening over the bonding pad. A reflow process is conducted to form a pre-solder body. The aforementioned steps are repeated so that various solder materials are fused together to form a solder ball over the bonding pad.

Abstract: A method of enhancing the adhesion between photoresist material and a substrate that can be applied to fabricate bumps on the substrate is provided. The bump fabrication process uses at least photoresist materials each having a different viscosity. A photoresist material having a smaller viscosity, that is, a higher fluidity, is permitted to contact a passivation layer so that all the gaps on the surface of the passivation layer are completely filled and a strong bond is formed between the photoresist layer and the passivation layer. With all the gaps on the substrate completely filled, solder material is prevented from filling the gaps to form a conductive bridge between neighboring bonding pads in a subsequent bump fabrication process.

Abstract: A chip structure comprising a chip, a spacing pad, a passivation layer, an under-bump metallic (UBM) layer and a conductive bump is provided. A plurality of bonding pads is disposed on the active surface of the chip. The spacing pad is disposed between the bonding pad and the UBM layer for reducing the possibility of broken circuit caused by the electro-migration between the bonding pad and the UBM layer. The base of the conductive bump is connected to the UBM layer so that the conductive bump can serve as a conductive structure for connecting with an external circuit.

Abstract: An under bump metallurgic (UBM) layer which is adapted for a chip is disclosed. The UMM layer alleviate the loss of electromigration resulting from current crowing effect at the corner of UBM layer near the transmission line. By increasing the thickness of the UBM layer at the particular region which is close to the transmission line, losses of the UBM layer due to electromigration can be compensated. The life time of the chip is, therefore, enhanced.

Abstract: A bump fabrication process is provided. A substrate having a plurality of openings of various widths thereon is provided. The substrate is dipped into an electrolytic solution. A step current that increases gradually is provided to the solution to perform an electroplating operation so that the conductive material is deposited inside the openings to form bumps with uniform thickness.

Abstract: A wafer bump fabrication process is provided in the present invention. A wafer with multiple bonding pads and a passivation layer, which exposes the bonding pads, is provided. The surface of each bonding pad has an under bump metallurgy layer. A patterned photoresist layer with a plurality of opening is formed which openings expose the under bump metallurgy layer. Afterwards a curing process is performed to cure the patterned photoresist layer. Following a solder paste fill-in process is performed to fill a solder paste into the openings. A reflow process is performed to form bumps from the solder paste in the openings. The patterned photoresist layer is removed.

Abstract: A chip structure can reduce the phenomenon of overcrowding current at the conventional circular opening of the passivation layer and further causing electromigration when the current flows to the bonding pad via the transmission line. The improved structure for the side profile of the opening of the passivation layer is about a circular profile, but the portion near to the transmission line is a straight line or a curving line. When the current flows through this opening, the current density can be uniformly distributed along the straight line or the curving line, and whereby the phenomenon of overcrowding current can be reduced.

Abstract: A bonding pad structure is suitable for a chip to improve conventional current density crowding at the bonding location between a bonding pad and an UBM layer, at which a current can not smoothly flow through due to the turning angle of the bonding location is overlarge. Therefore, an improvement structure of the bonding pad is formed by including a protruding pad on the top surface of the bonding pad. The turning angle of side profile of the protruding pad connected to the top surface of the bonding pad is less than 90 degrees, so as to smooth the turning angle when the current passes through.