A microelectronic device is formed by dispensing discrete amounts of a mixture of photoresist resin and solvents from droplet-on-demand sites onto a wafer to form a first photoresist sublayer, while the wafer is at a first temperature which allows the photoresist resin to attain less than 10 percent thickness non-uniformity. The wafer moves under the droplet-on-demand sites in a first direction to form the first photoresist sublayer. A portion of the solvents in the first photoresist sublayer is removed. A second photoresist sublayer is formed on the first photoresist sublayer using the droplet-on-demand sites while the wafer is at a second temperature to attain less than 10 percent thickness non-uniformity in the combined first and second photoresist sublayers. The wafer moves under the droplet-on-demand sites in a second direction for the second photoresist sublayer, opposite from the first direction.

A microelectronic device is formed by dispensing discrete amounts of a mixture of photoresist resin and solvents from droplet-on-demand sites onto a wafer to form a first photoresist sublayer, while the wafer is at a first temperature which allows the photoresist resin to attain less than 10 percent thickness non-uniformity. The wafer moves under the droplet-on-demand sites in a first direction to form the first photoresist sublayer. A portion of the solvents in the first photoresist sublayer is removed. A second photoresist sublayer is formed on the first photoresist sublayer using the droplet-on-demand sites while the wafer is at a second temperature to attain less than 10 percent thickness non-uniformity in the combined first and second photoresist sublayers. The wafer moves under the droplet-on-demand sites in a second direction for the second photoresist sublayer, opposite from the first direction.

A semiconductor device includes a silicon substrate, a first layer, a second layer, a barrier metal, and a gate pad. The first layer is formed of an oxide film provided on an upper surface of the silicon substrate. The second layer is a layer at least selectively having a projecting and recessed part on an upper surface of the first layer, the projecting and recessed part having a projection and recess deeper than a projection and recess occurring when the layer is formed in a planar shape. The barrier metal is formed on an upper surface of the second layer according to a shape of the projecting and recessed part. The gate pad is in close contact with the silicon substrate via the barrier metal.

A multi-pin wafer level chip scale package is achieved. One or more solder pillars and one or more solder blocks are formed on a silicon wafer wherein the one or more solder pillars and the one or more solder blocks all have a top surface in a same horizontal plane. A pillar metal layer underlies the one or more solder pillars and electrically contacts the one or more solder pillars with the silicon wafer through an opening in a polymer layer over a passivation layer. A block metal layer underlies the one or more solder blocks and electrically contacts the one or more solder pillars with the silicon wafer through a plurality of via openings through the polymer layer over the passivation layer wherein the block metal layer is thicker than the pillar metal layer.

A power semiconductor device includes a semiconductor body and a first terminal at the semiconductor body. The first terminal has a first side for adjoining an encapsulation and a second side for adjoining the semiconductor body. The first terminal includes, at the first side, a top layer; and, at the second side, a base layer coupled with the top layer, wherein a sidewall of the top layer and/or a sidewall of the base layer is arranged in an angle smaller than 85° with respect to a plane.

An array substrate, a method for fabricating the same, and a display device are provided. The method includes: forming a passivation layer on an array substrate, wherein the array substrate includes a thin film transistor and a conductive pad, and the passivation layer covers the thin film transistor and the conductive pad; forming a full-surface carbon film on the passivation layer; and patterning the carbon film and the passivation layer to remove the passivation layer and the carbon film corresponding to the conductive pad by a patterning process to obtain the array substrate.

A method of manufacturing a redistribution layer includes: forming an insulating layer on a wafer, delimited by a top surface and a bottom surface in contact with the wafer; forming a conductive body above the top surface of the insulating layer; forming a first coating region extending around and above the conductive body, in contact with the conductive body, and in contact with the top surface of the insulating layer in correspondence of a bottom surface of the first coating region; applying a thermal treatment to the wafer in order to modify a residual stress of the first coating region, forming a gap between the bottom surface of the first coating region and the top surface of the insulating layer; forming, after applying the thermal treatment, a second coating region extending around and above the first coating region, filling said gap and completely sealing the first coating region.

A semiconductor package includes a substrate, a first semiconductor chip disposed on the substrate, and a second semiconductor chip disposed on a top surface of the first semiconductor chip. The first semiconductor chip includes a conductive pattern disposed on the top surface of the first semiconductor chip and a first protective layer covering the top surface of the first semiconductor chip and at least partially surrounds the conductive pattern. The second semiconductor chip includes a first pad that contacts a first through electrode on a bottom surface of the second semiconductor chip. A second protective layer surrounds the first pad and covers the bottom surface of the second semiconductor chip. A third protection layer fills a first recess defined in the second protective layer to face the inside of the second protective layer. The first protective layer and the third protective layer contact each other.

To improve reliability of a semiconductor device. There are provided the semiconductor device and a method of manufacturing the same, the semiconductor including a pad electrode that is formed over a semiconductor substrate and includes a first conductive film and a second conductive film formed over the first conductive film, and a plating film that is formed over the second conductive film and used to be coupled to an external connection terminal (TR). The first conductive film and the second conductive film contains mainly aluminum. The crystal surface on the surface of the first conductive film is different from the crystal surface on the surface of the second conductive film.

To improve reliability of a semiconductor device. There are provided the semiconductor device and a method of manufacturing the same, the semiconductor including a pad electrode that is formed over a semiconductor substrate and includes a first conductive film and a second conductive film formed over the first conductive film, and a plating film that is formed over the second conductive film and used to be coupled to an external connection terminal (TR). The first conductive film and the second conductive film contains mainly aluminum. The crystal surface on the surface of the first conductive film is different from the crystal surface on the surface of the second conductive film.