A strip of semiconductor devices includes a plurality of leadframes electrically isolated from each other, a plurality of semiconductor chips, and an encapsulation material. Each leadframe has a first surface and a second surface opposite to the first surface. At least one semiconductor chip of the plurality of semiconductor chips is electrically coupled to the first surface of each leadframe. The encapsulation material encapsulates each semiconductor chip and at least portions of each leadframe.

An integrated circuit (IC) device may include a leadframe and an IC die having a first surface coupled to the lead frame and a second surface opposite the first surface. The IC device may further include a conductive clip including a first portion coupled to the second surface of the IC die, a second portion coupled to the first portion and extending laterally away from the IC die, and at least one flexible lead coupled to the second portion and looping back under the second portion toward the leadframe. Furthermore, a package may be over the leadframe, IC die, and conductive clip and have an opening therein exposing the at least one flexible lead.

An integrated circuit (IC) device may include a leadframe and an IC die having a first surface coupled to the lead frame and a second surface opposite the first surface. The IC device may further include a conductive clip including a first portion coupled to the second surface of the IC die, a second portion coupled to the first portion and extending laterally away from the IC die, and at least one flexible lead coupled to the second portion and looping back under the second portion toward the leadframe. Furthermore, a package may be over the leadframe, IC die, and conductive clip and have an opening therein exposing the at least one flexible lead.

Improvement in yield of a semiconductor device is obtained. In addition, increase in service life of a socket terminal is obtained. A projecting portion PJ1 and a projecting portion PJ2 are provided in an end portion PU of a socket terminal STE1. Thus, it is possible to enable contact between a lead and the socket terminal STE in which a large current is caused to flow, at two points by a contact using the projecting portion PJ1 and by a contact using the projecting portion PJ2, for example. As a result, the current flowing from the socket terminal STE1 to the lead flows by being dispersed into a path flowing in the projecting portion PJ1 and a path flowing in the projecting portion PJ2. Accordingly, it is possible to suppress increase of temperature of a contact portion between the socket terminal STE1 and the lead even in a case where the large current is caused to flow between the socket terminal STE1 and the lead.

Improvement in yield of a semiconductor device is obtained. In addition, increase in service life of a socket terminal is obtained. A projecting portion PJ1 and a projecting portion PJ2 are provided in an end portion PU of a socket terminal STE1. Thus, it is possible to enable contact between a lead and the socket terminal STE in which a large current is caused to flow, at two points by a contact using the projecting portion PJ1 and by a contact using the projecting portion PJ2, for example. As a result, the current flowing from the socket terminal STE1 to the lead flows by being dispersed into a path flowing in the projecting portion PJ1 and a path flowing in the projecting portion PJ2. Accordingly, it is possible to suppress increase of temperature of a contact portion between the socket terminal STE1 and the lead even in a case where the large current is caused to flow between the socket terminal STE1 and the lead.

A semiconductor package fabrication method comprises the steps of providing a wafer, applying a seed layer, forming a photo resist layer, plating a copper layer, removing the photo resist layer, removing the seed layer, applying a grinding process, forming metallization, and applying a singulation process. A semiconductor package comprises a silicon layer, an aluminum layer, a passivation layer, a polyimide layer, a copper layer, and metallization. In one example, an area of a contact area of a gate clip is smaller than an area of a gate copper surface. The area of the contact area of the gate clip is larger than a gate aluminum surface. In another example, an area of a contact area of a gate pin is larger than an area of a gate copper surface. The area of the contact area of the gate pin is larger than a gate aluminum surface.

A semiconductor package fabrication method comprises the steps of providing a wafer, applying a seed layer, forming a photo resist layer, plating a copper layer, removing the photo resist layer, removing the seed layer, applying a grinding process, forming metallization, and applying a singulation process. A semiconductor package comprises a silicon layer, an aluminum layer, a passivation layer, a polyimide layer, a copper layer, and metallization. In one example, an area of a contact area of a gate clip is smaller than an area of a gate copper surface. The area of the contact area of the gate clip is larger than a gate aluminum surface. In another example, an area of a contact area of a gate pin is larger than an area of a gate copper surface. The area of the contact area of the gate pin is larger than a gate aluminum surface.

A molded semiconductor package arrangement may comprise a die pad configured to support a semiconductor; a set of leads; and a mold structure that is formed to enclose the semiconductor and the die pad within the mold structure. The set of leads and the die pad may be formed from a same piece of conductive material. An electrical contact plane of the set of leads may be offset from a bottom surface of the die pad. The mold structure may include a molded standoff that is beneath the die pad. A bottom surface of the molded standoff may extend below the electrical contact plane of the set of leads by a threshold distance that corresponds to a thickness of the molded standoff.

A molded semiconductor package arrangement may comprise a die pad configured to support a semiconductor; a set of leads; and a mold structure that is formed to enclose the semiconductor and the die pad within the mold structure. The set of leads and the die pad may be formed from a same piece of conductive material. An electrical contact plane of the set of leads may be offset from a bottom surface of the die pad. The mold structure may include a molded standoff that is beneath the die pad. A bottom surface of the molded standoff may extend below the electrical contact plane of the set of leads by a threshold distance that corresponds to a thickness of the molded standoff.

A semiconductor device encompasses a cooler made of ceramics, having a first main face and a second main face, being parallel and opposite to the first main face, defined by two opposite side faces perpendicular to the first and second main faces, a plurality of conductive-pattern layers delineated on the first main face, a semiconductor chip mounted on the first main face via one of the plurality of conductive-pattern layers, and a seal member configured to seal the semiconductor chip.