A semiconductor power package includes a pre-molded chip housing and an electrically conducting chip carrier cast-in-place in the pre-molded chip housing. The semiconductor power package further includes a power semiconductor chip bonded on the electrically conducting chip carrier. A covering material is provided to embed the power semiconductor chip. The covering material has an elastic modulus less than an elastic modulus of a material of the pre-molded chip housing and/or a thermal conductivity greater than a thermal conductivity of the material of the pre-molded chip housing and/or a temperature stability greater than a temperature stability of the pre-molded chip housing.

In described examples, a microelectronic device includes a microelectronic die with a die attach surface. The microelectronic device further includes a nanoparticle layer coupled to the die attach surface. The nanoparticle layer may be in direct contact with the die attach surface, or may be coupled to the die attach surface through an intermediate layer, such as an adhesion layer or a contact metal layer. The nanoparticle layer includes nanoparticles having adjacent nanoparticles adhered to each other. The microelectronic die is attached to a package substrate by a die attach material. The die attach material extends into the nanoparticle layer and contacts at least a portion of the nanoparticles.

In described examples, a microelectronic device includes a microelectronic die with a die attach surface. The microelectronic device further includes a nanoparticle layer coupled to the die attach surface. The nanoparticle layer may be in direct contact with the die attach surface, or may be coupled to the die attach surface through an intermediate layer, such as an adhesion layer or a contact metal layer. The nanoparticle layer includes nanoparticles having adjacent nanoparticles adhered to each other. The microelectronic die is attached to a package substrate by a die attach material. The die attach material extends into the nanoparticle layer and contacts at least a portion of the nanoparticles.

The present disclosure is directed to a high throughput clip bonding tool or system which is flexible and easily adapts to different clip bond pitches or sizes. The clip bonding system may be an integrated system with various modules, including a clip singulation module, a feeder module, a transfer module and a clip attach module within a shared footprint. For example, an incoming clip source may be fed to the clip singulation module for clip singulation before the singulated clips are transferred by the feeder and transfer modules to a clip presentation area for clip alignment before pickup. A pickup tool of the clip attach module is configured to facilitate pickup and attachment of clips onto the semiconductor packages to be clip bonded. For example, the pickup head is programmable to facilitate clip bonding process of different applications which may require clips and packages with different sizes.

The present disclosure is directed to a high throughput clip bonding tool or system which is flexible and easily adapts to different clip bond pitches or sizes. The clip bonding system may be an integrated system with various modules, including a clip singulation module, a feeder module, a transfer module and a clip attach module within a shared footprint. For example, an incoming clip source may be fed to the clip singulation module for clip singulation before the singulated clips are transferred by the feeder and transfer modules to a clip presentation area for clip alignment before pickup. A pickup tool of the clip attach module is configured to facilitate pickup and attachment of clips onto the semiconductor packages to be clip bonded. For example, the pickup head is programmable to facilitate clip bonding process of different applications which may require clips and packages with different sizes.

A signal block and a double-faced cooling power module that uses the signal block is provided. The signal block includes a plurality of signal clips that are formed in a ribbon shape to connect a first signal pad formed on a semiconductor chip and a second signal pad formed on a signal lead frame. An insulator fixes the position of the plurality of signal clips while spacing the signal clips apart from each other.

A signal block and a double-faced cooling power module that uses the signal block is provided. The signal block includes a plurality of signal clips that are formed in a ribbon shape to connect a first signal pad formed on a semiconductor chip and a second signal pad formed on a signal lead frame. An insulator fixes the position of the plurality of signal clips while spacing the signal clips apart from each other.

An integrated circuit (IC) that includes a circuit substrate having a front side surface and an opposite back side surface. Active circuitry is located on the front side surface. An inductive structure is located within a deep trench formed in the circuit substrate below the backside surface. The inductive structure is coupled to the active circuitry.

An integrated circuit (IC) that includes a circuit substrate having a front side surface and an opposite back side surface. Active circuitry is located on the front side surface. An inductive structure is located within a deep trench formed in the circuit substrate below the backside surface. The inductive structure is coupled to the active circuitry.

A method of manufacturing a chip module comprises a step of disposing a first electronic element 13 on a first jig 500, a step of disposing a first connector 60 on the first electronic element 13 via a conductive adhesive 5, a step of disposing a second electronic element 23 on the first connector 60 via a conductive adhesive 5, a step of disposing a second connector 70 on a second jig 550, a step of reversing the second jig in a state where the second connector 70 is fixed to the second jig 550 and disposing the second connector 70 on the second electronic element 23 via a conductive adhesive 5, and a step of curing the conductive adhesives 5.