To provide electronic component in which bonding strength between external electrode and plating layer and bonding strength between external electrode and internal conductor can be increased. Electronic component according to present disclosure includes element body, interlayer connection conductor provided inside element body so as to extend to main surface of element body, external electrode formed on main surface of element body so as to cover interlayer connection conductor, and plating layer covering external electrode. Plating layer includes impregnation part that is impregnated into interlayer connection conductor.

A multilayered capacitor according to an embodiment includes a capacitor body including a dielectric layer, and a first internal electrode and a second internal electrode with the dielectric layer interposed therebetween, and an external electrode on one surface of the capacitor body. The first internal electrode has a first through-portion penetrating the first internal electrode, a dielectric of the dielectric layer is disposed in at least a portion of the first through-portion, and the first through-portion is disposed in a region where the first internal electrode is not overlapped with the second internal electrode.

A ceramic electronic device includes an element body and an external electrode. The element body is formed by laminating a ceramic layer and an internal electrode layer. The external electrode is electrically connected to at least one end of the internal, electrode layer. The element body includes a boundary layer at an end of the ceramic layer. The ceramic layer includes a perovskite compound represented by ABO.sub.3 as a main component. The boundary layer includes Ba and Ti as a main component. The boundary layer includes 0.27-0.40 parts by mol of Ba, provided that a total of Ba and Ti included in the boundary layer is 1 part by mol.

A ceramic capacitor which is low in ESL and suitable for being built into a substrate has a dimension in a length direction of a lowermost surface of a third external electrode which is in contact with a capacitor main body denoted by e1 and a dimension in the length direction of the uppermost surface of the third external electrode denoted by e2, and a relationship of e1<e2 is satisfied.

A ceramic capacitor that has low ESL and is suitable to be built into a substrate includes a first external electrode including a first portion extending from a portion located on a first principal surface to a portion of a first end surface, a second portion extending from a portion located on a second principal surface to a portion of the first end surface, a third portion extending from a portion located on a first side surface to a portion of the first end surface, and a fourth portion extending from a portion located on a second side surface to a portion of the first end surface. The first external electrode includes an outermost layer that is a Cu plated layer.

A ceramic capacitor which is low in ESL and suitable for being built into a substrate includes a first external electrode, a second external electrode and a third external electrode. Each of the first, second and third external electrodes include a sputtering electrode film. Each of the outermost layers of the first, second and third external electrodes contains Cu.

A multilayer component is disclosed. In an embodiment, a multilayer component includes a fully active stack comprising a plurality of dielectric layers, internal electrodes and two external electrodes arranged on opposite sides of the stack, wherein at least one portion of the internal electrode layers are coated.

A method can be used for producing a fully active stack. A stack has the sides A, B, C and D running along the stacking direction. The method includes combining and temporarily making contact with the internal electrodes that make contact with the respective side on one of the sides B or D, such that the internal electrodes that make contact with the respective side can be electrically driven selectively. The electrically driven internal electrodes are electrochemically coated on the sides A and C. The stack is singulated to form a fully active stack with the electrochemically coated internal electrodes on the sides A and C. A method for producing a multilayer component comprising the fully active stack and a fully active multilayer component producible according to the method are furthermore proposed.

A method for manufacturing a conductive paste includes preparing a first solution including a metal particle and a first solvent, preparing a second solvent, preparing a surfactant including a core particle and an organic material disposed on a surface of the core particle, and mixing the first solution, the second solvent, and the surfactant to form a mixed solution.

In a planar view of a ceramic capacitor that has low ESL and is embeddable into a substrate, lengths of first and second external electrodes are L1, lengths from portions of the first and second external electrodes farthest from a capacitor main body to portions closer to the capacitor main body by about 40% of a thickness of the first or second external electrode in a laminating direction are L2, a ratio L2/L1 is about 80% or more and about 90% or less. In the planar view, a length of a third external electrode is L3, a length from a portion of the third external electrode farthest from the capacitor main body to a portion closer to the capacitor main body by about 40% of a thickness of the third external electrode in the laminating direction is L4, a ratio L4/L3 is about 80% or more.