A semiconductor device includes: a first semiconductor chip having a metal layer on a top surface; a first wiring member arranged to face the metal layer; a sintered-metal layer arranged between the metal layer and the first wiring member, having a first region and a plurality of second regions provided inside the first region, the second regions having lower tensile strength than the first region; and a metallic member arranged inside the sintered-metal layer, wherein the second regions of the sintered-metal layer have lower tensile strength than the metal layer of the first semiconductor chip.

A semiconductor device includes: a first semiconductor chip having a metal layer on a top surface; a first wiring member arranged to face the metal layer; a sintered-metal layer arranged between the metal layer and the first wiring member, having a first region and a plurality of second regions provided inside the first region, the second regions having lower tensile strength than the first region; and a metallic member arranged inside the sintered-metal layer, wherein the second regions of the sintered-metal layer have lower tensile strength than the metal layer of the first semiconductor chip.

In one example, a semiconductor device comprises an electronic component comprising a component face side, a component base side, a component lateral side connecting the component face side to the component base side, and a component port adjacent to the component face side, wherein the component port comprises a component port face. A clip structure comprises a first clip pad, a second clip pad, a first clip leg connecting the first clip pad to the second clip pad, and a first clip face. An encapsulant covers portions of the electronic component and the clip structure. The encapsulant comprises an encapsulant face, the first clip pad is coupled to the electronic component, and the component port face and the first clip face are exposed from the encapsulant face. Other examples and related methods are also disclosed herein.

In one example, a semiconductor device comprises an electronic component comprising a component face side, a component base side, a component lateral side connecting the component face side to the component base side, and a component port adjacent to the component face side, wherein the component port comprises a component port face. A clip structure comprises a first clip pad, a second clip pad, a first clip leg connecting the first clip pad to the second clip pad, and a first clip face. An encapsulant covers portions of the electronic component and the clip structure. The encapsulant comprises an encapsulant face, the first clip pad is coupled to the electronic component, and the component port face and the first clip face are exposed from the encapsulant face. Other examples and related methods are also disclosed herein.

The present disclosure provides a semiconductor device. The semiconductor device includes a substrate, amounting layer, switching elements, a moisture-resistant layer and a sealing resin. The substrate has a front surface facing in a thickness direction. The mounting layer is electrically conductive and disposed on the front surface. Each switching element includes an element front surface facing in the same direction in which the front surface faces along the thickness direction, a back surface facing in the opposite direction of the element front surface, and a side surface connected to the element front surface and the back surface. The switching elements are electrically bonded to the mounting layer with their back surfaces facing the front surface. The moisture-resistant layer covers at least one side surface. The sealing resin covers the switching elements and the moisture-resistant layer. The moisture-resistant layer is held in contact with the mounting layer and the side surface so as to be spanned between the mounting layer and the side surface in the thickness direction.

The present disclosure provides a semiconductor device. The semiconductor device includes a substrate, amounting layer, switching elements, a moisture-resistant layer and a sealing resin. The substrate has a front surface facing in a thickness direction. The mounting layer is electrically conductive and disposed on the front surface. Each switching element includes an element front surface facing in the same direction in which the front surface faces along the thickness direction, a back surface facing in the opposite direction of the element front surface, and a side surface connected to the element front surface and the back surface. The switching elements are electrically bonded to the mounting layer with their back surfaces facing the front surface. The moisture-resistant layer covers at least one side surface. The sealing resin covers the switching elements and the moisture-resistant layer. The moisture-resistant layer is held in contact with the mounting layer and the side surface so as to be spanned between the mounting layer and the side surface in the thickness direction.

A semiconductor module includes a semiconductor element having one and the other surface, a lead terminal connected electrically and thermally to the semiconductor element, a first solder which bonds the lead terminal and the one surface of the semiconductor element together, a circuit layer over which the semiconductor element is disposed and a second solder which bonds the other surface of the semiconductor element and the circuit layer together. The inequality
(A/B)<1 holds, where A and B are the tensile strength of the first and second solder, respectively. As a result, even if the lead terminal which thermally expands because of heat generated by the semiconductor element expands or contracts toward the semiconductor element, a stress applied by the lead terminal is absorbed and relaxed by the first solder. This prevents damage to the surface electrode of the semiconductor element by suppressing the occurrence of cracks.

A clip for a semiconductor package includes a first portion and a second portion. The first portion includes a first surface, a second surface opposite to the first surface and configured to contact a first electrically conductive component, and a stepped region between the first surface and the second surface such that the second surface has a smaller area than the first surface. The second portion is coupled to the first portion and configured to contact a second electrically conductive component. The second portion includes a third surface aligned with the first surface.

A solid top terminal for discrete power devices. In one embodiment, an apparatus is formed that includes a first die comprising a transistor, which in turn includes a first electrode such as an emitter. The apparatus also includes a first conductor sintered to an electroplated second conductor such as a solid top terminal. Importantly, the first conductor is electrically coupled to the first electrode.

A solid top terminal for discrete power devices. In one embodiment, an apparatus is formed that includes a first die comprising a transistor, which in turn includes a first electrode such as an emitter. The apparatus also includes a first conductor sintered to an electroplated second conductor such as a solid top terminal. Importantly, the first conductor is electrically coupled to the first electrode.