This invention provides opportunity for diamond and bi-wafer microstructures to be implemented in advanced ICs and advanced IC packages to form a new breed of ICs and SiPs that go beyond the limitations of silicon at the forefront of IC advancement due primarily to diamond's extreme heat dissipating ability. Establishing the diamond and bi-wafer microstructure capabilities and implementing them in advanced ICs and advanced IC packages gives IC and package architects and designers an extra degree of design freedom in achieving extreme IC performance, particularly when thermal management presents a challenge. Diamond's extreme heat spreading ability can be used to dissipate hotspots in processors and other high-power chips such as GaN HEMT, resulting in performance and reliability enhancement for IC and package applications covering HPC, AI, photonics, 5G RF/mmWave, power and IoT, and at the system level propelling the migration from traditional computing to near-memory computing and in-memory computing.

A semiconductor module arrangement includes: a housing; a substrate arranged in or forming a bottom of the housing; a bus bar including a first end and a second end opposite the first end, the first end being arranged inside the housing and the second end extending to outside of the housing; and at least one connecting element mechanically and electrically coupled to a top surface of the substrate. The first end of the bus bar is arranged distant from the substrate in a vertical direction. The vertical direction is a direction perpendicular to the top surface of the substrate. The first end of the bus bar is electrically coupled to at least one of the at least one connecting element by one or more electrical connections.

A method of forming one or more semiconductor packages includes mounting one or more semiconductor dies on the metal strip such that the one or more semiconductor dies are in a flip chip arrangement whereby terminals of the one or more semiconductor dies face the upper surface of the metal strip, forming an electrically insulating encapsulant material on the upper surface of the metal strip that encapsulates the one or more semiconductor dies, and forming package terminals that are electrically connected with the terminals of the one or more semiconductor dies, wherein the package terminals are formed from the metal strip or from metal that is deposited after removing the metal strip.

A method of fabricating integrated passive device dies includes forming a first plurality of integrated passive devices on a substrate, forming a plurality of micro-bumps on the first plurality of integrated passive devices such that the plurality of micro-bumps act as electrical connections to the integrated passive devices, and dicing the substrate to form an integrated passive device die including a second plurality of integrated passive devices. The micro-bumps may be formed in an array or staggered configuration and may have a pitch that is in a range from 20 microns to 100 microns. The integrated passive devices may each include a seal ring and the integrated passive device die may have an area that is a multiple of an integrated passive device area. The method may further include dicing the substrate in various ways to generate integrated passive device dies having different sizes and numbers of integrated passive devices.

A semiconductor device is provided. The semiconductor device comprises a semiconductor die comprising a semiconductor substrate and a plurality of transistors arranged at a front side of the semiconductor substrate. Further, the semiconductor die comprises a first electrically conductive structure extending from the front side of the semiconductor substrate to a backside of the semiconductor substrate and a second electrically conductive structure extending from the front side of the semiconductor substrate to the backside of the semiconductor substrate. The semiconductor device further comprises an interposer directly attached to the backside of the semiconductor substrate. The interposer comprises a first trace electrically connected to the first electrically conductive structure of the semiconductor die. Further the interposer comprises the first trace or a second trace electrically connected to the second electrically conductive structure of the semiconductor die.

A package includes a semiconductor die disposed on a lead frame. A source contact pad is disposed on the semiconductor die. The package further includes a lead post shared by a plurality of leads that form external terminals of the package. The lead post has a clip-locking feature. A clip connects the source contact pad to the lead post. The clip has a key structure coupled to the clip-locking feature in the lead post.