Embodiments may relate to a microelectronic package comprising: a die and a package substrate coupled to the die with a first interconnect on a first face. The package substrate comprises: a second interconnect and a third interconnect on a second face opposite to the first face; a conductive signal path between the first interconnect and the second interconnect; a conductive ground path between the second interconnect and the third interconnect; and an electrostatic discharge (ESD) protection material coupled to the conductive ground path. The ESD protection material comprises a first electrically-conductive carbon allotrope having a first functional group, a second electrically-conductive carbon allotrope having a second functional group, and an electrically-conductive polymer chemically bonded to the first functional group and the second functional group permitting an electrical signal to pass between the first and second electrically-conductive carbon allotropes.

The semiconductor device includes a supporting member, a conductive member, and a semiconductor element. The supporting member has a supporting surface facing in a thickness direction. The conductive member has an obverse surface facing the same side as the supporting surface faces in the thickness direction, and a reverse surface opposite to the obverse surface. The conductive member is bonded to the supporting member such that the reverse surface faces the supporting surface. The semiconductor element is bonded to the obverse surface. The semiconductor device further includes a first metal layer and a second metal layer. The first metal layer covers at least a part of the supporting surface. The second metal layer covers the reverse surface. The first metal layer and the second layer are bonded to each other by solid phase diffusion.

An interconnect structure may include a graphene-metal barrier on a substrate and a conductive layer on the graphene-metal barrier. The graphene-metal barrier may include a plurality of graphene layers and metal particles on grain boundaries of each graphene layer between the plurality of graphene layers. The metal particles may be formed at a ratio of 1 atom % to 10 atom % with respect to carbon of the plurality of graphene layers.

The present application discloses a semiconductor chip, a semiconductor device and an electrostatic discharge (ESD) protection method for a semiconductor device. The semiconductor chip includes an electrical contact, an application circuit, and an ESD protection unit. The application circuit performs operations according to a one signal received by the electrical contact. The ESD protection unit is coupled to the electrical contact. The capacitance of the ESD protection unit is adjustable.

The present invention relates to a chip-on film type semiconductor package including an integrated circuit chip, a printed circuit board layer, an outer lead bonder pad, and a graphite layer, in which the integrated circuit chip is connected to one surface of the printed circuit board layer directly or by means of a mounting element, the outer lead bonder pad is located on one surface of the printed circuit board layer, and the graphite layer is laminated on an opposite surface of the printed circuit board layer and a display device including the same.

A leadframe for a semiconductor device includes an array of electrically-conductive leads. The electrically-conductive leads have mutually opposed lateral (vertical) surfaces. An electrically-insulating material is formed over the mutually lateral opposed surfaces to prevent short circuits between adjacent leads. The electrically-insulating material may further be provided at one or more of the opposed bottom and top surfaces of the electrically-conductive leads of the leadframe.

A semiconductor package carrier board, a method for fabricating the same, and an electronic package having the same are provided. The method includes forming on a circuit structure a graphene layer that acts as an insulation heat dissipating layer. Since the heat conductivity of the graphene layer is far greater than the heat conductivity of ink (about 0.4 W/m.Math.k), which is used as solder resist, the heat of the semiconductor package carrier board can be conducted quickly, and thus can avoid the problem that the heat will be accumulated on the semiconductor package carrier board.

According to one embodiment, an interconnection substrate includes an insulating layer. A first interconnection layer is on a first side of the insulating layer. A second interconnection layer is on a second side of the insulating layer, which is opposite the first side. A first film comprising carbon covers at least part of the first and second interconnection layers.

There is provided a semiconductor device including: a semiconductor element; a support substrate configured to support the semiconductor element; an intermediate metal layer interposed between the semiconductor element and the support substrate in a thickness direction of the support substrate, wherein the semiconductor element and the intermediate metal layer are bonded by solid phase diffusion bonding; and a first positioning portion including a portion of the semiconductor element and a first portion of the intermediate metal layer and configured to suppress relative movement between the semiconductor element and the intermediate metal layer.

Embodiments of the disclosure are in the field of advanced integrated circuit structure fabrication. In an example, an integrated circuit structure includes a single dielectric layer above a substrate. A plurality of conductive lines is in an upper portion of the single dielectric layer above a lower portion of the single dielectric layer. A carbon dopant region is in the upper portion of the single dielectric layer, the carbon dopant region between adjacent ones of the plurality of conductive lines.