A method of fabricating a contact hole and a fuse hole includes providing a dielectric layer. A conductive pad and a fuse are disposed within the dielectric layer. Then, a first mask is formed to cover the dielectric layer. Later, a first removing process is performed by taking the first mask as a mask to remove part the dielectric layer to form a first trench. The conductive pad is disposed directly under the first trench and does not expose through the first trench. Subsequently, the first mask is removed. After that, a second mask is formed to cover the dielectric layer. Then, a second removing process is performed to remove the dielectric layer directly under the first trench to form a contact hole and to remove the dielectric layer directly above the fuse by taking the second mask as a mask to form a fuse hole.

A microelectronic device includes a metal layer on a first dielectric layer. An etch stop layer is disposed over the metal layer and on the dielectric layer directly adjacent to the metal layer. The etch stop layer includes a metal oxide, and is less than 10 nanometers thick. A second dielectric layer is disposed over the etch stop layer. The second dielectric layer is removed from an etched region which extends down to the etch stop layer. The etched region extends at least partially over the metal layer. In one version of the microelectronic device, the etch stop layer may extend over the metal layer in the etched region. In another version, the etch stop layer may be removed in the etched region. The microelectronic device is formed by etching the second dielectric layer using a plasma etch process, stopping on the etch stop layer.

The present disclosure provides a display apparatus and a manufacturing method thereof. The display apparatus includes a silicon substrate, a plurality of metal data interfaces disposed on the silicon substrate, and a plurality of conductive patterns covering upper surfaces of the metal data interfaces respectively. The plurality of the conductive patterns is formed by enabling a semiconductor material to be conductive and the plurality of conductive patterns are not contacted with each other.

Provided are a packaging method and packaging structure for a semiconductor chip. The packaging method comprises: providing a wafer, the wafer being provided with multiple semiconductor chips, each semiconductor chip being provided with a functional area and solder pads arranged on a first surface; providing a protective substrate, multiple support units being provided on the protective substrate, openings being formed on the support units; aligning the solder pads to the openings and facing support units provided on the protective substrate to the first surface of the wafer, and pressing together the wafer and the protective substrate. The packaging method effectively prevents the support units from generating stress that acts on the solder pads in a subsequent reliability test, thus preventing cases of the solder pad being damaged or split into layers.

A method of fabricating a contact hole and a fuse hole includes providing a dielectric layer. A conductive pad and a fuse are disposed within the dielectric layer. Then, a first mask is formed to cover the dielectric layer. Later, a first removing process is performed by taking the first mask as a mask to remove part the dielectric layer to form a first trench. The conductive pad is disposed directly under the first trench and does not expose through the first trench. Subsequently, the first mask is removed. After that, a second mask is formed to cover the dielectric layer. Then, a second removing process is performed to remove the dielectric layer directly under the first trench to form a contact hole and to remove the dielectric layer directly above the fuse by taking the second mask as a mask to form a fuse hole.

The present invention provides a semiconductor structure and a method of fabricating the same. The method includes: providing a chip having conductive pads, forming a metal layer on the conductive pads, forming a passivation layer on a portion of the metal layer, and forming conductive pillars on the metal layer. Since the metal layer is protected by the passivation layer, the undercut problem is solved, the supporting strength of the conductive pillars is increased, and the product reliability is improved.

The present disclosure discloses a semiconductor structure having an insulating layer disposed on a wafer active surface of a semiconductor wafer for covering the wafer active surface. The insulating layer may be a protective layer in some embodiments and a cover layer in other embodiments. The insulating layer has via openings to expose contact pads for leading out electrical connections. In particular, the via openings are formed by a multi-step etching process (such as a two-step etching process) without damaging the contact pads. The two-step etching process includes a first laser etching process using normal pulse (P) and normal energy to form partial via openings in the cover layer. The second etching process includes either a laser etching process using low P and low E or a plasma etching process. The second etching process avoids damaging the contact pads.

An interposer according to an embodiment of the present invention includes a base layer having opposite first and second surfaces, a wiring structure on the first surface of the base layer, an interposer protective layer disposed on the second surface of the base layer and having a pad recess with a lower surface of the interposer protective layer positioned at a first vertical level and a bottom surface of the pad recess positioned at a second vertical level that is higher than the first vertical level, an interposer pad of which a portion fills the pad recess of the interposer protective layer and the remaining portion protrudes from the interposer protective layer, and an interposer through electrode extending through the base layer and the interposer protective layer to the interposer pad, the interposer through electrode electrically connecting the wiring structure to the interposer pad.

Disclosed is a display device and a method of manufacturing the same, wherein an end portion of a pad provided on a first substrate is spaced apart and separated from an upper surface of the first substrate, and a connection electrode electrically connected with the pad is in contact with a lateral surface of the pad and a lower surface of the pad.

Embodiments include semiconductor packages and a method of forming the semiconductor packages. A semiconductor package includes a resist layer disposed on a conductive layer. The semiconductor package also has a bump disposed on the conductive layer. The bump has a top surface and one or more sidewalls. The semiconductor package further includes a surface finish disposed on the top surface and the one or more sidewalls of the bump. The semiconductor package may have the surface finish surround the top surface and sidewalls of the bumps to protect the bumps from Galvanic corrosion. The surface finish may include a nickel-palladium-gold (NiPdAu) surface finish. The semiconductor package may also have a seed disposed on a top surface of the resist layer, and a dielectric disposed on the seed. The dielectric may surround the sidewalls of the bump. The semiconductor package may include the seed to be an electroless copper seed.