Disclosed herein are embodiments of lead-free (Pb-free) or lead-bearing solder column devices that can include an inner core, an outer sleeve surrounding a portion of the inner core, at least one space along a length of the outer sleeve, and a second layer including a solder material coupled with a portion of the inner core within the at least one space. The inner core can be configured to support the solder column so as to prevent a collapse of the solder column at temperatures above a liquidus temperature of the outer sleeve's solder material and the second layer's solder material. The column serves as a heat-sink to conduct excessive heat away from a heat generating semiconductor chip. Moreover, the compliant solder column absorbs strain and mechanical stress caused by a difference in the coefficient of thermal expansion (CTE) connecting the semiconductor chip to a printed circuit board (PCB).

A printed wiring board includes a base insulating layer, a conductor layer formed on the base layer and including first and second pads, a solder resist layer formed on the base layer such that the solder resist layer has first opening exposing the first pad and second opening exposing the second pad with diameter smaller than diameter of the first opening, and bumps including a first bump on the first pad and a second bump on the second pad such that the second bump has diameter smaller than diameter of the first bump. The first bump has a base plating layer formed in the first opening and having raised portion, and a top plating layer formed on the base plating layer, and the second bump has a base plating layer formed in the second opening and having raised portion, and a top plating layer formed on the base plating layer.

An electronic component mounting substrate includes an electronic component and a substrate that are electrically connected at a plurality of places on a bottom surface of the electronic component. At least two places of the plurality of places are electrically connected by bonding using a conductive adhesive, and places other than the at least two places of the plurality of places are electrically connected by soldering using a paste solder.

A method of attaching a chip to the substrate with an outer layer comprising via pillars embedded in a dielectric such as solder mask, with ends of the via pillars flush with said dielectric, the method comprising the steps of: (o) optionally removing organic varnish, (p) positioning a chip having legs terminated with solder bumps in contact with exposed ends of the via pillars, and (q) applying heat to melt the solder bumps and to wet the ends of the vias with solder.

A disk having at least one electric connecting element is described. The disk has a substrate, and electrically conductive structure on a region of the substrate, a connecting element containing at least chromium-containing steel, and a layer of a soldering compound that electrically connects the connecting element to sub-regions of the electrically conductive structure.

A ceramic circuit substrate having high bonding performance and excellent thermal cycling resistance properties, having a circuit pattern provided on a ceramic substrate with a braze material layer interposed therebetween, and a protruding portion formed by the braze material layer protruding from the outer edge of the circuit pattern, wherein: the braze material layer includes Ag, Cu, Ti, and Sn or In; and an Ag-rich phase is formed continuously for 300 m or more, towards the inside, from an outer edge of the protruding portion, along a bonding interface between the ceramic substrate and the circuit pattern, and has a bonding void ratio of 1.0% or less.

A method of manufacturing an electronic board includes: preparing a substrate in which substrate-side solder parts are provided on electrodes; preparing a mounting sheet having a resin layer in which a plurality of voids is formed in accordance with positions of the electrodes; attaching the resin layer to at least one of a first electronic component and the substrate so that interfaces of the first electronic component or the substrate-side solder parts are located inside the respective voids; causing the interfaces and the substrate-side solder parts to face each other at positions of the respective voids; and melting the substrate-side solder parts by heating to join the interfaces and the electrodes.

A method of manufacturing an electronic board includes: preparing a substrate in which substrate-side solder parts are provided on electrodes; preparing a mounting sheet having a resin layer in which a plurality of voids is formed in accordance with positions of the electrodes; attaching the resin layer to at least one of a first electronic component and the substrate so that interfaces of the first electronic component or the substrate-side solder parts are located inside the respective voids; causing the interfaces and the substrate-side solder parts to face each other at positions of the respective voids; and melting the substrate-side solder parts by heating to join the interfaces and the electrodes.

A multilayer electronic component includes a capacitor body including a plurality of dielectric layers and a plurality of first and second internal electrodes and having first to sixth surfaces, the first and second internal electrodes being exposed through the third and fourth surfaces, respectively; first and second external electrodes including first and second connected portions respectively disposed on the third and fourth surfaces of the capacitor body and first and second band portions respectively extending from the first and second connected portions to portions of the first surface of the capacitor body, respectively; a first connection terminal disposed on the first band portion; and a second connection terminal disposed on the second band portion, wherein 0.05A1/A10.504, where A1 is an area of the first or second connection terminal in a thickness-width direction, and A2 is an area of the first or second band portion in a width-length direction.

An on-vehicle electronic circuit mounting board includes: a surface mount type package component including a plurality of electrode pads disposed along an outer periphery of a component bottom surface; and a printed wiring board having a plurality of lands disposed along the plurality of electrode pads on a top surface of the printed wiring board opposed to the component bottom surface, and in which each land is disposed to be opposed to the corresponding electrode pad and electrically connected to the electrode pad by soldered connection. An outer soldering slope and an inner soldering slope are formed between a land of the plurality of lands and an electrode pad corresponding to the land, and the land is shifted with respect to the corresponding electrode pad such that one of the outer soldering slope and the inner soldering slope faces the wiring board side and the other faces the component side.