A method includes preparing a circuit board that includes a first metal pattern over a first face side of the substrate, a first electrode in a periphery of the first metal pattern, a second electrode over a second face side of the substrate, and a second metal pattern thermally connected to the first metal pattern and in which an electronic device is fixed on the first metal pattern and an electronic component is electrically connected to the second electrode, and connecting the first electrode and a third electrode of the electronic device by a bonding wire with the electronic device being heated. By a board support stage, the electronic device is heated by transferring heat to the electronic device via the second and then first metal pattern with the circuit board being supported to form a space including the electronic component between the second face and the board support stage.

Embodiments herein relate to creating a high-aspect ratio opening in a package. Embodiments may include applying a first laminate layer on a side of a substrate, applying a seed layer to at least part of the laminate layer, building up one or more copper pads on the seed layer, etching the seed layer to expose a portion of the first laminate layer, applying a second laminate layer to fill in around the sides of one or more copper pads, and removing part of the buildup copper pads. Other embodiments may be described and/or claimed.

Embodiments herein relate to creating a high-aspect ratio opening in a package. Embodiments may include applying a first laminate layer on a side of a substrate, applying a seed layer to at least part of the laminate layer, building up one or more copper pads on the seed layer, etching the seed layer to expose a portion of the first laminate layer, applying a second laminate layer to fill in around the sides of one or more copper pads, and removing part of the buildup copper pads. Other embodiments may be described and/or claimed.

A conductor structure includes a first metal layer, a second metal layer, and a controlling layer. The second metal layer is disposed on the first metal layer. A material of the first metal layer and a material of the second metal layer include at least one identical metal element. The controlling layer is disposed between the first metal layer and the second metal layer. A thickness of the controlling layer is less than a thickness of the first metal layer, and the thickness of the controlling layer is less than a thickness of the second metal layer.

Disclosed is a method for manufacturing a thin film transistor. The method includes steps of etching a second metal layer and a semiconductor layer to form a boundary region of a thin film transistor; etching the second metal layer again to form a source, a drain and a back channel region of the thin film transistor; removing residual photoresist via an ashing procedure; and etching the semiconductor layer again to form a conductive channel of the thin film transistor. According to the method, the electric leakage problem of thin film transistor due to diffusion of copper and contamination of organic stripping liquid can be eliminated.

An interconnect element 130 can include a dielectric layer 116 having a top face 116b and a bottom face 116a remote from the top face, a first metal layer defining a plane extending along the bottom face and a second metal layer extending along the top face. One of the first or second metal layers, or both, can include a plurality of conductive traces 132, 134. A plurality of conductive protrusions 112 can extend upwardly from the plane defined by the first metal layer 102 through the dielectric layer 116. The conductive protrusions 112 can have top surfaces 126 at a first height 115 above the first metal layer 132 which may be more than 50% of a height of the dielectric layer. A plurality of conductive vias 128 can extend from the top surfaces 126 of the protrusions 112 to connect the protrusions 112 with the second metal layer.

A printed circuit board and a method of manufacturing a printed circuit board are provided. The printed circuit board includes an insulating layer, a circuit layer embedded in the insulating layer, a solder resist layer disposed on one surface of the insulating layer, the solder resist layer having a cavity of a through-hole shape to expose a part of the circuit layer from the insulating layer, and a metal post embedded in the solder resist layer and exposed to outside via an opening of the solder resist layer, and the metal post includes a first post metal layer, a post barrier layer, and a second post metal layer disposed in that order.

A circuit board according to an embodiment includes an insulating layer; a first circuit pattern disposed on a first surface of the insulating layer; a first solder resist disposed on the first surface of the insulating layer; and a first barrier layer including a first-first portion disposed between the first solder resist and the first circuit pattern, and a first-second portion disposed between the insulating layer and the first circuit pattern; wherein the firs-first portion of the first barrier layer includes: a first-first gold (Au) layer disposed under a lower surface of the first circuit pattern; and a first-first palladium (Pd) layer disposed under a lower surface of the first-first gold (Au) layer; wherein the first-second portion of the first barrier layer includes: a first-second gold (Au) layer disposed to surround a side surface and an upper surface of the first circuit pattern; and a first-second palladium (Pd) layer disposed to surround the first-second gold (Au) layer; and wherein the first circuit pattern is not in contact with the first solder resist and the insulating layer by the first-first portion and the first-second portion of the first barrier layer.

Disclosed are a printed circuit board and a method for manufacturing the same. The printed circuit board includes a core insulating layer, at least one via formed through the core insulating layer, an inner circuit layer buried in the core insulating layer, and an outer circuit layer on a top surface or a bottom surface of the core insulating layer, wherein the via includes a first part, a second part below the first part, a third part between the first and second parts, and at least one barrier layer including a metal different from a metal of the first to third parts. The inner circuit layer and the via are simultaneously formed so that the process steps are reduced. Since odd circuit layers are provided, the printed circuit board has a light and slim structure.

An interconnect element 130 can include a dielectric layer 116 having a top face 116b and a bottom face 116a remote from the top face, a first metal layer defining a plane extending along the bottom face and a second metal layer extending along the top face. One of the first or second metal layers, or both, can include a plurality of conductive traces 132, 134. A plurality of conductive protrusions 112 can extend upwardly from the plane defined by the first metal layer 102 through the dielectric layer 116. The conductive protrusions 112 can have top surfaces 126 at a first height 115 above the first metal layer 132 which may be more than 50% of a height of the dielectric layer. A plurality of conductive vias 128 can extend from the top surfaces 126 of the protrusions 112 to connect the protrusions 112 with the second metal layer.