An electronic component includes an element body and external electrodes. The element body includes a dielectric and an internal electrode. Each of the external electrodes includes a base layer formed on multiple surfaces of the element body and an electrically-conducting material layer formed on the base layer, the base layer including a metal and co-material particles dispersed in the metal and being connected to the internal electrode. The co-material particles at an interface surface between the base layer and the electrically-conducting material layer have edges covered with the metal at the interface surface. The electrically-conducting material layer is in contact with the co-material particles at the interface surface and the metal covering the edges of the co-material particles at the interface surface.

Embodiments include a microelectronic package structure having a substrate with one or more substrate pads on a first side of the package substrate. A ball interconnect structure is on the substrate pad, the ball interconnect structure comprising at least 99.0 percent gold. A discrete component having two or more component terminals is on the ball interconnect structure.

A component built-in substrate includes a multilayer body and a substrate including a multilayer ceramic electronic component embedded therein. The multilayer ceramic electronic component includes a first connection portion that protrudes from the first external electrode, and a second connection portion that protrudes from the second external electrode. The substrate includes a core material. The multilayer ceramic electronic component including the first connection portion and the second connection portion includes a surface covered by the core material and embedded in the substrate. The first connection portion protrudes toward a surface of the substrate, and is not exposed at the surface of the substrate. The second connection portion protrudes toward the surface of the substrate, and is not exposed at the surface of the substrate.

A method for printed circuit board design rework utilizing two components in series, the method includes selecting a first chip component and a second chip component for placement on an original land location previously occupied by an original chip component. The method further includes placing the first chip component and the second chip component on a chip component support structure. The method further includes soldering a first end of the first chip component to a first end of the second chip component. Responsive to transferring the first chip component and the second chip component to the original land location, the method further includes soldering a second end of the first chip component to a first land of the original land location. The method further includes soldering a second end of the second chip component to a second land of the original land location.

An electronic device is downsized while suppressing performance degradation of the electronic device. In the electronic device, a power module including a power transistor is arranged in a first region on a back surface of a through hole board having a plurality of through hole vias having different sizes while a pre-driver including a control circuit is arranged in a second region on a front surface of the board. In this case, in a plan view, the first region and the second region have an overlapping region. The power module and the pre-driver are electrically connected to each other via a through hole via. The plurality of through hole vias include a through hole via having a first size, a through hole via which is larger than the first size and in which a cable can be inserted, and a through hole via in which a conductive member is embedded.

An electronic component includes: a capacitor body; a pair of external electrodes disposed on opposite end surfaces of the capacitor body, respectively; and a pair of metal frames respectively including a pair of connected portions connected to the pair of external electrodes, respectively, and a pair of mounted portions bent at and extending from one ends of the pair of connected portions, respectively, wherein corners of end portions of the pair of mounted portions facing each other have a curved surface.

An electronic component assembly is described which comprises a stack of electronic components wherein each electronic component comprises a face and external terminations. A component stability structure is attached to at least one face. A circuit board is provided wherein the circuit board comprises circuit traces arranged for electrical engagement with the external terminations. The component stability structure mechanically engages with the circuit board and inhibits the electronic device from moving relative to the circuit board.

A multilayer ceramic electronic component includes: a ceramic body including: an active part with dielectric layers interposed with a plurality of first and second internal electrodes; an upper cover part above the active part; a lower cover part below the active part and having a thickness greater than that of the upper cover part; and first and second external electrodes electrically connected to the first and second internal electrodes, respectively, wherein the first and second external electrodes are disposed on respective end surfaces of the ceramic body in a length direction and on a lower surface of the ceramic body in a thickness direction and are not disposed on an upper surface of the ceramic body in the thickness direction.

A printed substrate includes a land that is to be soldered. The land includes a plating film that defines a surface of the land. The plating film includes a metal as a main constituent and a pi-acceptor molecule that is dispersed in the plating film. The pi-acceptor molecule has pi-acceptability and causes ligand field splitting equal to or greater than that of 2,2′-bipyridyl in spectrochemical series. A content of the pi-acceptor molecule in the plating film is equal to or greater than 0.1 weight percent, in terms of carbon atoms, with respect to the metal of the plating film.

A multilayer ceramic capacitor may include: ceramic body including a plurality of dielectric layers and a plurality of internal electrodes, external electrodes including a connecting portion and band portion, terminal electrodes including upper and lower horizontal portion and vertical portion connecting end portion of the upper and lower horizontal portion and the conductive adhesive layers disposed to the upper surface of the band portion and upper horizontal portion.