A semiconductor structure is provided. The semiconductor structure includes a base, a seed layer, a compound semiconductor layer, a gate structure, a source structure, a drain structure, and a conductive paste. The seed layer is disposed on the base. The compound semiconductor layer is disposed on the seed layer. The gate structure is disposed on the compound semiconductor layer. The source structure and the drain structure are disposed on both sides of the gate structure. In addition, the conductive paste is disposed between the base and a lead frame, and the conductive paste extends to the side surface of the base.

A semiconductor structure is provided. The semiconductor structure includes a base, a seed layer, a compound semiconductor layer, a gate structure, a source structure, a drain structure, and a conductive paste. The seed layer is disposed on the base. The compound semiconductor layer is disposed on the seed layer. The gate structure is disposed on the compound semiconductor layer. The source structure and the drain structure are disposed on both sides of the gate structure. In addition, the conductive paste is disposed between the base and a lead frame, and the conductive paste extends to the side surface of the base.

A semiconductor structure is provided. The semiconductor structure includes a base, a seed layer, a compound semiconductor layer, a gate structure, a source structure, a drain structure, and a conductive paste. The seed layer is disposed on the base. The compound semiconductor layer is disposed on the seed layer. The gate structure is disposed on the compound semiconductor layer. The source structure and the drain structure are disposed on both sides of the gate structure. In addition, the conductive paste is disposed between the base and a lead frame, and the conductive paste extends to the side surface of the base.

The invention relates to a method for electrically contacting a component (10) (for example a power component and/or a (semiconductor) component having at least one transistor, preferably an IGBT (insulated-gate bipolar transistor)) having at least one contact (40, 50), at least one open-pored contact piece (60, 70) is galvanically (electrochemically or free of external current) connected to at least one contact (40, 50). In this way, a component module is achieved. The contact (40, 50) is preferably a flat part or has a contact surface, the largest planar extent thereof being greater than an extension of the contact (40, 50) perpendicular to said contact surface. The temperature of the galvanic connection is at most 100° C., preferably at most 60° C., advantageously at most 20° C. and ideally at most 5° C. and/or deviates from the operating temperature of the component by at most 50° C., preferably by at most 20° C., in particular by at most 10° C. and ideally by at most 5° C., preferably by at most 2° C. The component (10) can be contacted by means of the contact piece (60, 70) with a further component, a current conductor and/or a substrate (90). Preferably, a component (10) having two contacts (40, 50) on opposite sides of the component (10) is used, wherein at least one open-pored contact piece (60, 70) is galvanically connected to each contact (40, 50).

The invention relates to a method for electrically contacting a component (10) (for example a power component and/or a (semiconductor) component having at least one transistor, preferably an IGBT (insulated-gate bipolar transistor)) having at least one contact (40, 50), at least one open-pored contact piece (60, 70) is galvanically (electrochemically or free of external current) connected to at least one contact (40, 50). In this way, a component module is achieved. The contact (40, 50) is preferably a flat part or has a contact surface, the largest planar extent thereof being greater than an extension of the contact (40, 50) perpendicular to said contact surface. The temperature of the galvanic connection is at most 100° C., preferably at most 60° C., advantageously at most 20° C. and ideally at most 5° C. and/or deviates from the operating temperature of the component by at most 50° C., preferably by at most 20° C., in particular by at most 10° C. and ideally by at most 5° C., preferably by at most 2° C. The component (10) can be contacted by means of the contact piece (60, 70) with a further component, a current conductor and/or a substrate (90). Preferably, a component (10) having two contacts (40, 50) on opposite sides of the component (10) is used, wherein at least one open-pored contact piece (60, 70) is galvanically connected to each contact (40, 50).

A semiconductor includes a semiconductor element, a connecting terminal electrically connected to the semiconductor element, and a case including an opening space for housing the semiconductor element, a frame which surrounds the opening space and in which the connecting terminal is partially embedded, and a terminal arrangement portion protruding from the frame towards the opening space. The connecting terminal includes an internal terminal portion that extends towards the opening space with respect to the frame, the internal terminal portion having a front surface that is electrically connected to the semiconductor element and exposed to the opening space, and a rear surface that is fixed to the terminal arrangement portion.

A semiconductor includes a semiconductor element, a connecting terminal electrically connected to the semiconductor element, and a case including an opening space for housing the semiconductor element, a frame which surrounds the opening space and in which the connecting terminal is partially embedded, and a terminal arrangement portion protruding from the frame towards the opening space. The connecting terminal includes an internal terminal portion that extends towards the opening space with respect to the frame, the internal terminal portion having a front surface that is electrically connected to the semiconductor element and exposed to the opening space, and a rear surface that is fixed to the terminal arrangement portion.

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 method of creating a bond between a first object and a second object. For example, at least one insert may be provided at a location in a space formed between the first object and the second object. In additional, a filler material may be provided proximal to the location. An inter-diffusion layer may be formed, wherein a first portion of the inter-diffusion layer is formed by diffusion between the filler material and the at least one insert, wherein a second portion of the inter-diffusion layer is formed between the filler material and the first object, wherein a third portion of the inter-diffusion layer is formed between the filler material and the second object, wherein the first portion is coadunate with each of the second portion and third portion.