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 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: A method for preventing burnt fuse pads from further electrical connection suitable before the formation of bumps on the wafer. A dielectric layer is formed over the active surface of the wafer covering the bump pads and the fuse pads of the wafer, wherein a central region of the fuse pads is burnt to form a gap which allows the material of the dielectric layer to fill up the gap. Afterwards, either a part of the dielectric layer is removed and the part of the dielectric layer covering the fuse pads remainsor a part of the dielectric layer covering the bump pads is removed. Then, an under ball metallurgy layer is formed on the bump pads of the wafer so that the material of the under ball metallurgy layer does not cover the two sides of the fuse pad at the same time, or fill into the gap. As a result, the electrical isolation still remains.

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 solder ball attaching process for attaching solder balls to a wafer is provided. First, an under-ball-metallurgy layer is formed on the active surface of the wafer. Patterned masking layers are sequentially formed over the active surface of the wafer. The masking layers together form a step opening structure that exposes the under-ball-metallic layer. A solder ball is placed on the uppermost masking layer and allowed to roll so that the solder ball drops into the step opening structure by gravity. A reflow process is conducted to join the solder ball and the under-ball-metallurgy layer together. Finally, various masking layers are removed to expose the solder ball on the bonding pad of the wafer.

Abstract: A bump fabrication method is described. The method comprises the steps of providing a wafer having an active surface and a plurality of bonding pads formed on the active surface; respectively forming an under bump metallurgy layer onto the bonding pads, wherein the under bump metallurgy layer includes at least a wetting layer having an oxidized region and positioned at a top layer of the under bump metallurgy layer; patterning a masking layer on the active surface wherein the masking layer is provided with a plurality of openings to expose the wetting layers; removing the oxidized region of the wetting layer using ionic bombardment; fully forming a flux film on the active layer, wherein at least a portion of the flux film covers onto the wetting layer; filling a solder paste into the openings; performing a re-flow process to form a plurality of bumps after the solder paste melts so that the flux film removes the oxidized region of the wetting layer; and removing the masking layer.

Abstract: A bumping process wherein a substrate is first provided with many electrical connections. Subsequently, the bumps on the bump transfer substrate are pressed onto the electrical connections of the substrate accompanying a heating process and then the bumps are transferred onto the electrical connections of the substrate because the adhesion characteristic between the bumps and the electrical connections is better than that between the bumps and the release layer.

Abstract: A solder paste for fabricating bumps includes a flux and metallic alloy powder. The metallic alloy powder includes a plurality of low eutectic metallic alloy granules, and the size of these metallic alloy granules is 20-60 &mgr;m and the average size of the metallic granules is 35 &mgr;m to 45 &mgr;m.

Abstract: The present invention provides a bump fabrication process. After forming an under bump metallurgy (UBM) layer and bumps in sequence over the substrate, the under bump metallurgy layer that is not covered by the bumps is etched with an etchant. The etchant mainly comprises sulfuric acid and de-ionized water. The etchant can etch the nickel-vanadium layer of the UBM layer without damaging the bumps.

Abstract: A lead-free solder bump fabrication process for producing a plurality of lead-free solder bumps over a wafer is provided. The lead-free solder bump fabrication process includes forming a lead-free pre-formed solder bump over each bonding pad on the wafer and then forming a patterned solder mask layer over the active surface of the wafer. The openings in the solder mask layer expose the respective lead-free pre-formed solder bumps on the wafer. Thereafter, lead-free solder material is deposited into the opening. The material composition of the lead-free solder material differs from the material composition of the lead-free pre-formed solder bump. A reflow process is conducted so that the lead-free pre-formed solder bump fuses with the lead-free solder material to form a lead-free solder bump. Finally, the solder mask layer is removed.

Abstract: A bump fabrication process for forming a bump over a wafer having a plurality of bonding pads thereon is provided. A patterned solder mask layer having a plurality of openings that exposes the respective bonding pads is formed over a wafer. The area of the opening in a the cross-sectional area through a the bottom-section as well as through a the top-section of the opening is smaller than the area of the opening in a the cross-sectional area through a the mid-section of the opening. Solder material is deposited into the opening and then a reflow process is conducted fusing the solder material together to form a spherical bump inside the opening. Finally, the solder mask layer is removed. In addition, a pre-formed bump may form on the bonding pad of the wafer prior to forming the patterned solder mask layer over the wafer having at leastwith an opening that exposes the pre-formed bump.

Abstract: The present invention provides a bump fabrication process. After forming an under bump metallurgy (UBM) layer and bumps in sequence over the substrate, the under bump metallurgy layer that is not covered by the bumps is etched with an etchant. The etchant mainly comprises sulfuric acid and de-ionized water. The etchant can etch the nickel-vanadium layer of the UBM layer without damaging the bumps.

Abstract: A solder paste for fabricating bumps includes a flux and metallic alloy powder. The metallic alloy powder includes a plurality of low eutectic metallic alloy granules, and the size of these metallic alloy granules is 20-60 &mgr;m and the average size of the metallic granules is 35 &mgr;m to 45 &mgr;m.

Abstract: A bump fabrication method is described. The method comprises the steps of providing a wafer having an active surface and a plurality of bonding pads formed on the active surface; respectively forming an under bump metallurgy layer onto the bonding pads, wherein the under bump metallurgy layer includes at least a wetting layer having an oxidized region and positioned at a top layer of the under bump metallurgy layer; patterning a masking layer on the active surface wherein the masking layer is provided with a plurality of openings to expose the wetting layers; removing the oxidized region of the wetting layer using ionic bombardment; fully forming a flux film on the active layer, wherein at least a portion of the flux film covers onto the wetting layer; filling a solder paste into the openings; performing a re-flow process to form a plurality of bumps after the solder paste melts so that the flux film removes the oxidized region of the wetting layer; and removing the masking layer.

Abstract: A solder ball attaching process for attaching solder balls to a wafer is provided. First, an under-ball-metallurgy layer is formed on the active surface of the wafer. Patterned masking layers are sequentially formed over the active surface of the wafer. The masking layers together form a step opening structure that exposes the under-ball-metallic layer. A solder ball is placed on the uppermost masking layer and allowed to roll so that the solder ball drops into the step opening structure by gravity. A reflow process is conducted to join the solder ball and the under-ball-metallurgy layer together. Finally, various masking layers are removed to expose the solder ball on the bonding pad of the wafer.

Abstract: A bumping process wherein a substrate is first provided with many electrical connections. Subsequently, the bumps on the bump transfer substrate are pressed onto the electrical connections of the substrate accompanying a heating process and then the bumps are transferred onto the electrical connections of the substrate because the adhesion characteristic between the bumps and the electrical connections is better than that between the bumps and the release layer.

Abstract: A method for preventing burnt fuse pads from further electrical connection suitable before the formation of bumps on the wafer. A dielectric layer is formed over the active surface of the wafer covering the bump pads and the fuse pads of the wafer, wherein a central region of the fuse pads is burnt to form a gap which allows the material of the dielectric layer to fill up the gap. Afterwards, either a part of the dielectric layer is removed. and the part of the dielectric layer covering the fuse pads remainsor a part of the dielectric layer covering the bump pads is removed. Then, an under ball metallurgy layer is formed on the bump pads of the wafer so that the material of the under ball metallurgy layer does not cover the two sides of the fuse pad at the same time, or fill into the gap. As a result, the electrical isolation still remains.

Abstract: A lead-free solder bump fabrication process for producing a plurality of lead-free solder bumps over a wafer is provided. The lead-free solder bump fabrication process includes forming a lead-free pre-formed solder bump over each bonding pad on the wafer and then forming a patterned solder mask layer over the active surface of the wafer. The openings in the solder mask layer expose the respective lead-free pre-formed solder bumps on the wafer. Thereafter, lead-free solder material is deposited into the opening. The material composition of the lead-free solder material differs from the material composition of the lead-free pre-formed solder bump. A reflow process is conducted so that the lead-free pre-formed solder bump fuses with the lead-free solder material to form a lead-free solder bump. Finally, the solder mask layer is removed.

Abstract: A flip chip interconnection structure is formed over the active surface of a chip. The active surface of the chip includes a plurality of bonding pads. A redistribution trace layer, including at least a redistribution trace, is formed over the active surface in a manner to electrically connect to the bonding pads. A plurality of conductive posts, made of a tin-lead alloy having a tin to lead ratio greater than about 10:90, are formed on and connected to the redistribution trace structure. An insulating layer is formed over the redistribution trace layer to encompass the conductive posts. The insulating layer comprises a plurality of openings through which the conductive posts externally protrude.

Abstract: A wafer-level package structure, applicable to a flip-chip arrangement on a carrier, which comprises a plurality of contact points, is described. This wafer-level package structure is mainly formed with a chip and a conductive layer. The conductive layer is arranged on the bonding pads of the chip as contact points. The conductive layer can further be arranged at a region outside the bonding pads on the chip as a heat sink to enhance the heat dissipation ability of the package.