A semiconductor structure includes a semiconductor device (e.g., an e-fuse or photonic device) and a metallic heating element adjacent thereto. The heating element has a lower portion within a middle of the line (MOL) dielectric layer adjacent to the semiconductor device and an upper portion with a tapered top end that extends into a back end of the line (BEOL) dielectric layer. A method of forming the semiconductor structure includes forming a cavity such that it has both a lower section, which extends from a top surface of a MOL dielectric layer downward toward a semiconductor device, and an upper section, which extends from the top surface of the MOL dielectric layer upward and which is capped by an area of a BEOL dielectric layer having a concave bottom surface. A metallic fill material can then be deposited into the cavity (e.g., through via openings) to form the heating element.

A semiconductor structure includes a semiconductor device (e.g., an e-fuse or photonic device) and a metallic heating element adjacent thereto. The heating element has a lower portion within a middle of the line (MOL) dielectric layer adjacent to the semiconductor device and an upper portion with a tapered top end that extends into a back end of the line (BEOL) dielectric layer. A method of forming the semiconductor structure includes forming a cavity such that it has both a lower section, which extends from a top surface of a MOL dielectric layer downward toward a semiconductor device, and an upper section, which extends from the top surface of the MOL dielectric layer upward and which is capped by an area of a BEOL dielectric layer having a concave bottom surface. A metallic fill material can then be deposited into the cavity (e.g., through via openings) to form the heating element.

In order to reduce costs as well as to effectively dissipate heat in certain RF circuits, a semiconductor device of the circuit can include one or more active devices such as transistors, diodes, and/or varactors formed of a first semiconductor material system integrated onto (e.g., bonded to) a base substrate formed of a second semiconductor material system that includes other circuit components. The first semiconductor material system can, for example, be the III-V or III-N semiconductor system, and the second semiconductor material system can, for example be silicon.

In order to reduce costs as well as to effectively dissipate heat in certain RF circuits, a semiconductor device of the circuit can include one or more active devices such as transistors, diodes, and/or varactors formed of a first semiconductor material system integrated onto (e.g., bonded to) a base substrate formed of a second semiconductor material system that includes other circuit components. The first semiconductor material system can, for example, be the III-V or III-N semiconductor system, and the second semiconductor material system can, for example be silicon.

An apparatus is provided which comprises: one or more pads comprising metal on a first substrate surface, the one or more pads to couple with contacts of an integrated circuit die, one or more substrate layers comprising dielectric material, one or more conductive contacts on a second substrate surface, opposite the first substrate surface, the one or more conductive contacts to couple with contacts of a printed circuit board, one or more inductors on the one or more substrate layers, the one or more inductors coupled with the one or more conductive contacts and the one or more pads, and highly thermally conductive material between the second substrate surface and a printed circuit board surface, the highly thermally conductive material contacting the one or more inductors. Other embodiments are also disclosed and claimed.

A method of forming a semiconductor device includes applying an adhesive material in a first region of an upper surface of a substrate, where applying the adhesive material includes: applying a first adhesive material at first locations of the first region; and applying a second adhesive material at second locations of the first region, the second adhesive material having a different material composition from the first adhesive material. The method further includes attaching a ring to the upper surface of the substrate using the adhesive material applied on the upper surface of the substrate, where the adhesive material is between the ring and the substrate after the ring is attached.

Methods and apparatus for a cooling plate for solid state power amplifiers are provided herein. In some embodiments, a cooling plate of a solid state power amplifier includes a body having a rectangular shape, a first sidewall opposite a second sidewall, and a third sidewall opposite a fourth sidewall; a plurality of holes disposed on a first side of the body configured to mount a plurality of heat generating microelectronic components; and a channel having a plurality of segments disposed within the body and extending from a first port disposed on the first sidewall to a second port disposed on the first sidewall.

Methods and apparatus for a cooling plate for solid state power amplifiers are provided herein. In some embodiments, a cooling plate of a solid state power amplifier includes a body having a rectangular shape, a first sidewall opposite a second sidewall, and a third sidewall opposite a fourth sidewall; a plurality of holes disposed on a first side of the body configured to mount a plurality of heat generating microelectronic components; and a channel having a plurality of segments disposed within the body and extending from a first port disposed on the first sidewall to a second port disposed on the first sidewall.

Provided are a semiconductor device and an inverter device with a decrease in yield being suppressed by preventing the adhesive from leaking into the inside of the semiconductor device. A heat sink, a wiring board provided on the heat sink, a semiconductor chip provided on the wiring board, a case housing provided on the heat sink so as to surround the wiring board and the semiconductor chip, an adhesive that adheres a lower surface joint portion of the case housing and an upper surface joint portion of the heat sink, a sealing material that fills the case housing and covers the wiring board and the semiconductor chip, and a convex portion provided on the lower surface joint portion of the case housing or the upper surface joint portion of the heat sink, that separates the adhesive from the sealing material are included.

A semiconductor package includes an interposer including first and second surfaces opposite to each other. The semiconductor package also includes a heat dissipation layer disposed on the first surface of the interposer and a first semiconductor die mounted on the first surface of the interposer. The semiconductor package additionally includes a stack of second semiconductor dies mounted on the second surface of the interposer. The semiconductor package further includes a thermally conductive connection part for transferring heat from the stack of the second semiconductor dies to the heat dissipation layer.