A semiconductor device includes: a semiconductor element that includes an element main body having an element main surface and an element back surface facing opposite sides to each other in a thickness direction, and a first electrode arranged on the element main surface; an insulator that has an annular shape overlapping an outer peripheral edge of the first electrode when viewed in the thickness direction and is arranged over the first electrode and the element main surface; a first metal layer arranged over the first electrode and the insulator; and a second metal layer laminated on the first metal layer and overlapping both the first electrode and the insulator when viewed in the thickness direction.

A semiconductor package including a semiconductor die having multiple bond pads is provided. The package further includes an electrically conducting clip including, at a first side thereof, at least one pin for mounting the package to an external board and includes, at a second side opposite to the first side, a connecting portion connecting the clip to at least two bond pads of the multiple bond pads. The connection portion includes at least two elongated connecting strips spaced apart from each other at a distance in such a manner that each strip extends over at least one of the at least two bond pads and is connected thereto.

To improve reliability of a semiconductor device. There are provided the semiconductor device and a method of manufacturing the same, the semiconductor including a pad electrode that is formed over a semiconductor substrate and includes a first conductive film and a second conductive film formed over the first conductive film, and a plating film that is formed over the second conductive film and used to be coupled to an external connection terminal (TR). The first conductive film and the second conductive film contains mainly aluminum. The crystal surface on the surface of the first conductive film is different from the crystal surface on the surface of the second conductive film.

A semiconductor device provided with first and second semiconductor element each having an obverse and a reverse surface with a drain electrode, source electrode and gate electrode provided on the obverse surface. The semiconductor device is also provided with a control element electrically connected to the gate electrodes of the respective semiconductor elements, and with a plurality of leads, which include a first lead carrying the first semiconductor element, a second lead carrying the second semiconductor element, and a third lead carrying the control element. The first and second leads overlap with each other as viewed in a first direction perpendicular to the thickness direction of the semiconductor device, and the third lead overlaps with the first and second leads as viewed in a second direction perpendicular to the thickness direction and the first direction.

A semiconductor device includes at least one semiconductor element having a switching function; a conductive member that forms a path of a current switched by the semiconductor element, and that is made of a first material; and a covering layer that covers at least a portion of the conductive member, and that is made of a second material. The second material satisfies at least one of the following three requirements: (a) having a magnetic permeability higher than the first material; (b) having an electrical resistivity higher than the first material; and (c) having a dielectric loss tangent larger than zero.

A semiconductor device manufacturing method, includes: a preparing process for preparing a conductive plate, a semiconductor chip arranged over the conductive plate with a first bonding material therebetween, and a connection terminal including a bonding portion arranged over the semiconductor chip with a second bonding material therebetween; a first jig arrangement process for arranging a first guide jig, through which a first guide hole pierces, over the conductive plate, such that the first guide hole corresponds to the bonding portion in a plan view of the semiconductor device; and a first pressing process for inserting a pillar-shaped pressing jig, which includes a pressing portion at a lower end portion thereof, into the first guide hole, and pressing the bonding portion of the connection terminal to a side of the conductive plate with the pressing portion.

A semiconductor device includes metal connector plate having a first lower surface, facing an electrode of a semiconductor chip, a first end surface, a second end surface, and a second lower surface connecting the first end surface and the second end surface. In a first direction parallel to the semiconductor chip, an end surface of the electrode is located between the positions of the first end surface and the second end surface. A distance from the second lower surface to the electrode is greater than a distance from the first lower surface to the electrode. A joining component has a first portion between the first lower surface and the electrode and a second portion between the second lower surface and the electrode.

A method for producing a semiconductor package includes providing a lead frame and a bond pad with a space therebetween. The frame is provided with a die bonded thereon and a die pad. The die, the pad, a part of the frame, a part of the bond pad and the space between the frame and the bond pad are encapsulated. Part of the first encapsulation is removed to create a cavity having a bottom surface including an exposed surface of the die, an exposed surface of the pad, an exposed surface of the bond pad and a connecting region between the exposed surface of the pad and the bond pad. The cavity is partly filled with an electrically conductive paste. The electrically conductive paste is cured to obtain an interconnect between the die pad and the bond pad. The interconnect is encapsulated.

Various teachings of the present disclosure include a method for welding an attachment piece to a semiconductor metallization using laser welding. The method may include: arranging an attachment piece having a flat side with a thin point so the flat side faces the semiconductor metallization; and welding the flat side to the semiconductor metallization. The flat side rests against a flat side of the semiconductor metallization over an entire surface area of the flat side. The thin point is formed with a cup shape of the attachment piece. The cup shape is open in the direction away from the semiconductor metallization.

A bus bar for a power semiconductor module arrangement includes a first end, and a second end. The first end is configured to be arranged inside a housing of the power semiconductor module arrangement. The second end is configured to be arranged outside of the housing and to be electrically contacted by an external bus bar. The second end includes a structured area that includes a plurality of protrusions. A height of each of the protrusions is between 10 μm and 1000 μm.