A microelectronic device is formed by forming a platinum-containing layer on a substrate of the microelectronic device. A cap layer is formed on the platinum-containing layer so that an interface between the cap layer and the platinum-containing layer is free of platinum oxide. The cap layer is etchable in an etch solution which also etches the platinum-containing layer. The cap layer may be formed on the platinum-containing layer before platinum oxide forms on the platinum-containing layer. Alternatively, platinum oxide on the platinum-containing layer may be removed before forming the cap layer. The platinum-containing layer may be used to form platinum silicide. The platinum-containing layer may be patterned by forming a hard mask or masking platinum oxide on a portion of the top surface of the platinum-containing layer to block the wet etchant.

A semiconductor storage device according to an embodiment includes: an array chip having a memory cell array; a circuit chip having a circuit electrically connected to a memory cell; and a metal pad bonding the array chip and the circuit chip together. The metal pad includes an impurity. A concentration of the impurity is lowered as separating in a depth direction apart from a surface in a thickness direction of the metal pad.

A semiconductor package includes a semiconductor chip comprising a first surface and a second surface, a redistribution layer on the first surface of the semiconductor chip, an under bump metal (UBM) layer on the redistribution layer, and a solder bump on the UBM layer, and the solder bump covers both outer side surfaces of the UBM layer.

A semiconductor structure and a method for forming the same are provided. The semiconductor structure includes: a semiconductor chip; a substrate facing an active surface of the semiconductor chip; and a conductive bump extending from the active surface of the semiconductor chip toward the substrate, wherein the conductive bump comprises: a plurality of bump segments comprising a first group of bump segments and a second group of bump segments, wherein each bump segment comprises the same segment height in a direction orthogonal to the active surface of the semiconductor chip, and each bump segment comprises a volume defined by the multiplication of the segment height with the average cross-sectional area of the bump segment; wherein the ratio of the total volume of the first group of bump segments to the total volume of the second group of bump segments is between about 0.03 and about 0.8.

A semiconductor structure includes a conductive structure over a first passivation layer; and a second passivation layer over the conductive structure and the first passivation layer. The second passivation layer has a first oxide film extending along a top surface of the first passivation layer, sidewalls and a top surface of the conductive structure, wherein a top surface of the first oxide film is planar. The second passivation layer further includes a second oxide film over a top surface of the first oxide film and a top surface of the conductive structure, wherein a top surface of the second oxide film is planar. The second passivation layer further includes a third oxide film extending along a top surface of the second oxide film, the sidewalls and the top surface of the conductive structure, wherein a top surface of the third oxide film is curved.

A method of making a semiconductor including soldering a conductor to an aluminum metallization is disclosed. In one example, the method includes substituting an aluminum oxide layer on the aluminum metallization by a substitute metal oxide layer or a substitute metal alloy oxide layer. Then, substitute metal oxides in the substitute metal oxide layer or the substitute metal alloy oxide layer are at least partly reduced. The conductor is soldered to the aluminum metallization using a solder material.

A method of making a semiconductor including soldering a conductor to an aluminum metallization is disclosed. In one example, the method includes substituting an aluminum oxide layer on the aluminum metallization by a substitute metal oxide layer or a substitute metal alloy oxide layer. Then, substitute metal oxides in the substitute metal oxide layer or the substitute metal alloy oxide layer are at least partly reduced. The conductor is soldered to the aluminum metallization using a solder material.

The present disclosure provides a driving substrate and a manufacturing method thereof, and a micro LED bonding method. The driving substrate includes: a base substrate; a driving function layer provided on the base substrate, and including a plurality of driving thin film transistors and a plurality of common electrode lines; a pad layer including a plurality of pads provided on a side of the driving function layer away from the base substrate, each pad including a pad body and a microstructure of hard conductive material provided on a side of the pad body away from the base substrate; and a plurality of buffer structures provided on the side of the driving function layer away from the base substrate, each buffer structure surrounding a portion of a corresponding microstructure close to the base substrate, and a height of the buffer structure being lower than a height of the microstructure.

A semiconductor structure includes a conductive structure over a first passivation layer. The semiconductor structure further includes a second passivation layer over the conductive structure and the first passivation layer. The second passivation layer has a first oxide film extending along a top surface of the first passivation layer, sidewalls and a top surface of the conductive structure. The second passivation layer further includes a second oxide film over a top surface of the first oxide film and a top surface of the conductive structure. The second passivation layer further includes a third oxide film extending along a top surface of the second oxide film, the sidewalls and the top surface of the conductive structure.

A semiconductor package includes a semiconductor chip comprising a first surface and a second surface, a redistribution layer on the first surface of the semiconductor chip, an under bump metal (UBM) layer on the redistribution layer, and a solder bump on the UBM layer, and the solder bump covers both outer side surfaces of the UBM layer.