Various embodiments of the present disclosure are directed towards an integrated circuit (IC) chip comprising a semiconductor device that is inverted and that overlies a dielectric region inset into a top of a semiconductor substrate. An interconnect structure overlies the semiconductor substrate and the dielectric region and further comprises an intermetal dielectric (IMD) layer. The IMD layer is bonded to the top of the semiconductor substrate and accommodates a pad. A semiconductor layer overlies the interconnect structure, and the semiconductor device is in the semiconductor layer, between the semiconductor layer and the interconnect structure. The semiconductor device comprises a first source/drain electrode overlying the dielectric region and further overlying and electrically coupled to the pad. The dielectric region reduces substrate capacitance to decrease substrate power loss and may, for example, be a cavity or a dielectric layer. A contact extends through the semiconductor layer to the pad.

An apparatus comprising a substrate having conductive traces and associated integral terminal pads on a surface thereof, the terminal pads having an irregular surface topography formed in a thickness of a single material of the conductive traces and integral terminal pads. Solder balls may be bonded to the terminal pads, and one or more microelectronic components operably coupled to conductive traces of the substrate on a side thereof opposite the terminal pads. Methods of fabricating terminal pads on a substrate, and electronic systems including substrates having such terminal pads are also disclosed.

An integrated circuit chip includes an SOI substrate having a structure in which a bulk substrate, a buried insulating film, and a semiconductor body layer are sequentially stacked, a conductive ion implantation region formed at a position adjacent to the buried insulating film in the bulk substrate, an integrated circuit portion formed on an active surface of the semiconductor body layer, and a penetrating electrode portion arranged at a position spaced apart from the integrated circuit portion in a horizontal direction, the penetrating electrode portion penetrating the semiconductor body layer and the buried insulating layer in a vertical direction, and the penetrating electrode portion connected to the conductive ion implantation region. An integrated circuit package and a display device include the integrated circuit chip.

An integrated circuit chip includes an SOI substrate having a structure in which a bulk substrate, a buried insulating film, and a semiconductor body layer are sequentially stacked, a conductive ion implantation region formed at a position adjacent to the buried insulating film in the bulk substrate, an integrated circuit portion formed on an active surface of the semiconductor body layer, and a penetrating electrode portion arranged at a position spaced apart from the integrated circuit portion in a horizontal direction, the penetrating electrode portion penetrating the semiconductor body layer and the buried insulating layer in a vertical direction, and the penetrating electrode portion connected to the conductive ion implantation region. An integrated circuit package and a display device include the integrated circuit chip.

The present disclosure relates integrated chip structure. The integrated chip structure includes one or more interconnects disposed within a dielectric structure over a substrate. A bond pad having a top surface is arranged along a top surface of the dielectric structure. The top surface of the bond pad includes a plurality of discrete top surface segments that are laterally separated from one another by non-zero distances that extend between interior sidewalls of the bond pad, as viewed in a cross-sectional view. The dielectric structure is disposed directly between the interior sidewalls of the bond pad.

A wafer level chip scale package includes a semiconductor substrate having a first thickness, an input-output pad formed on the semiconductor substrate, a front metal layer having a second thickness formed on the input-output pad, a back metal layer having a third thickness formed on a bottom of the semiconductor substrate, and a metal bump formed on the semiconductor substrate.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a first semiconductor structure and a first connecting structure, wherein the first connecting structure includes a first connecting insulating layer positioned on the first semiconductor structure, two first conductive layers positioned in the first connecting insulating layer, and a first porous layer positioned between the two first conductive layers. A porosity of the first porous layer is between about 25% and about 100%. The first semiconductor structure includes a plurality of first composite conductive features, wherein at least one of the plurality of first composite conductive features includes a first protection liner, a first graphene liner in the first protection liner and a first core conductor in the first graphene liner.

A display backboard and a manufacturing method thereof, and a display device are provided. The display backboard includes: a driving substrate; a plurality of driving electrodes on the driving substrate; and a plurality of connection structures respectively on the plurality of driving electrodes. The connection structure includes: at least one conductive component on the driving electrode; and a restriction component on a side of the driving electrodes provided with the at least one conductive component and in at least a part of a peripheral region of the at least one conductive component. The restriction component protrudes from the driving electrode and has a first height in a direction perpendicular to the driving substrate.

Even in a case where a pad becomes smaller, solder connection strength is improved. A semiconductor device includes a pad, a diffusion layer, and a melting layer. The pad included by the semiconductor device includes a concave portion on a surface at which solder connection is to be performed. The diffusion layer included by the semiconductor device is disposed at the concave portion and constituted with a metal which remains on the surface of the pad while diffusing into solder upon the solder connection. The melting layer included by the semiconductor device is disposed adjacent to the diffusion layer and constituted with a metal which diffuses and melts into the solder upon the solder connection.

Various embodiments of the present application are directed towards a pad with high strength and bondability. In some embodiments, an integrated chip comprises a substrate, an interconnect structure, a pad, and a conductive structure. The interconnect structure adjoins the substrate and comprises wires and vias. The wires and the vias are stacked between the pad and the substrate. The conductive structure (e.g., a wire bond) extends through the substrate to the pad. By arranging the wires and the vias between the pad and the substrate, the pad may be inset into a passivation layer of the interconnect structure and the passivation layer may absorb stress on the pad. Further, the pad may contact the wires and the vias at a top wire level. A thickness of the top wire level may exceed a thickness of other wire levels, whereby the top wire level may be more tolerant to stress.