A semiconductor package includes: a leadframe having first, second and third die pads and leads, each die pad having upper and lower surfaces; first and second power semiconductor devices; a control semiconductor device; and a mold compound. The upper surface of each die pad is arranged within the mold compound. The lower surface of the second die pad is spaced apart from a side face of the semiconductor package by a distance that is greater than a length of the individual leads. The first power semiconductor device is mounted on the upper surface of the first die pad and electrically coupled to the second die pad by one or more first connectors extending between the first device and the upper surface of the second die pad. The upper surface of the second die pad is occupied by the one or more connectors or in direct contact with the mold compound.

An integrated circuit (IC) package incorporating controlled induced warping is disclosed. The IC package includes an electronic substrate having an active side upon which semiconducting dies and functional circuits have been lithographed or otherwise fabricated, leading to an inherent warping in the direction of the active side. One or more corrective layers may be deposited to the opposing, or inactive, side of the semiconducting die via thin film deposition (TFD) instrumentation and techniques in order to induce corrective warping of the electronic substrate back toward the horizontal (e.g., in the direction of the inactive side) to a desired degree.

Representative techniques and devices, including process steps may be employed to mitigate undesired dishing in conductive interconnect structures and erosion of dielectric bonding surfaces. For example, an embedded layer may be added to the dished or eroded surface to eliminate unwanted dishing or voids and to form a planar bonding surface. Additional techniques and devices, including process steps may be employed to form desired openings in conductive interconnect structures, where the openings can have a predetermined or desired volume relative to the volume of conductive material of the interconnect structures. Each of these techniques, devices, and processes can provide for the use of larger diameter, larger volume, or mixed-sized conductive interconnect structures at the bonding surface of bonded dies and wafers.

An integrated circuit (IC) package incorporating controlled induced warping is disclosed. The IC package includes an electronic substrate having an active side upon which semiconducting dies and functional circuits have been lithographed or otherwise fabricated, leading to an inherent warping in the direction of the active side. One or more corrective layers may be deposited to the opposing, or inactive, side of the semiconducting die via thin film deposition (TFD) instrumentation and techniques in order to induce corrective warping of the electronic substrate back toward the horizontal (e.g., in the direction of the inactive side) to a desired degree.

A semiconductor device comprising a first and second doped semiconductor layer wherein the first layer is a monosilicon layer and the second layer is a polysilicon layer, an oxide layer covering the first and second layer, and an interconnect which electrically connects the first and second layer comprises a metal alloy which has a first part in contact with the first layer and a second part in contact with the second layer, wherein a part of the metal alloy between the first and the second part crosses over a sidewall of the second layer; at least one electronic component is formed in the first and/or second layer; the semiconductor device moreover comprises a stoichiometric passivation layer which covers the first and second layer and the oxide layer.

The present disclosure provides a semiconductor package structure having a semiconductor die having an active surface, a conductive bump on the active surface, configured to electrically couple the semiconductor die to an external circuit, the conductive bump having a bump height, a dielectric encapsulating the semiconductor die and the conductive bump, and a plurality of fillers in the dielectric, each of the fillers comprising a diameter, wherein a maximum diameter of the fillers is smaller than the bump height.

An apparatus including a transistor device including a channel disposed on a substrate between a source and a drain, a gate electrode disposed on the channel, wherein the channel includes a length dimension between source and drain that is greater than a length dimension of the gate electrode such that there is a passivated underlap between an edge of the gate electrode and an edge of the channel relative to each of the source and the drain. A method including forming a channel of a transistor device on a substrate; forming first and second passivation layers on a surface of substrate on opposite sides of the channel; forming a gate stack on the channel between first and second passivation layers; and forming a source on the substrate between the channel and the first passivation layer and a drain on the substrate between the channel and the second passivation layer.

An encapsulated integrated circuit includes an integrated circuit (IC) die. An encapsulation material encapsulates the IC die. Within the encapsulation material, a phononic bandgap structure is configured to have a phononic bandgap with a frequency range approximately equal to a range of frequencies of thermal phonons produced by the IC die when the IC die is operating.

A transistor is provided that comprises a source region overlying a base structure, a drain region overlying the base structure, and a block of semiconducting material overlying the base structure and being disposed between the source region and the drain region. The block of semiconducting material comprises a gate controlled region adjacent the source region, and a drain access region disposed between the gate controlled region and the drain region. The drain access region is formed of a plurality of semiconducting material ridges spaced apart from one another by non-channel trench openings, wherein at least a portion of the non-channel trench openings being filled with a doped material to provide a depletion region to improve breakdown voltage of the transistor.

The present disclosure provides a semiconductor package structure having a semiconductor die having an active surface, a conductive bump on the active surface, configured to electrically couple the semiconductor die to an external circuit, the conductive bump having a bump height, a dielectric encapsulating the semiconductor die and the conductive bump, and a plurality of fillers in the dielectric, each of the fillers comprising a diameter, wherein a maximum diameter of the fillers is smaller than the bump height.