Performance of a semiconductor device is improved without increasing an area size of a semiconductor chip. For example, a source electrode of a power transistor and an upper electrode of a capacitor element have an overlapping portion. In other word, the upper electrode of the capacitor element is formed over the source electrode of the power transistor through a capacitor insulating film. That is, the power transistor and the capacitor element are arranged in a laminated manner in a thickness direction of the semiconductor chip. As a result, it becomes possible to add a capacitor element to be electrically coupled to the power transistor while suppressing an increase in planar size of the semiconductor chip.

A semiconductor device includes an active layer, a source electrode, a drain electrode, a gate electrode, a first insulating layer, a first source pad, and a first drain pad. The source electrode, the drain electrode, and the gate electrode are disposed, on an active region of the active layer. The first insulating layer is disposed on the source electrode, the drain electrode, and the gate electrode. The first source pad and the first drain pad are disposed on the first insulating layer and the active region. The first source pad includes a first source body and a first source branch. The first source branch is electrically connected to the first source body and disposed on the source electrode. The first drain pad includes a first drain body and a first drain branch. The first drain branch is electrically connected to the first drain body and disposed on the drain electrode.

The fabrication of field-effect transistor (FET) devices is described herein where the FET devices include one or more body contacts implemented between source, gate, drain (S/G/D) assemblies to improve the influence of a voltage applied at the body contact on the S/G/D assemblies. The FET devices can include source fingers and drain fingers interleaved with gate fingers. The source and drain fingers of a first S/G/D assembly can be electrically connected to the source and drain fingers of a second S/G/D assembly. The source fingers and the drain fingers can be arranged in alternating rows.

A radio-frequency (RF) device includes a main device on a substrate, a first port extending along a first direction adjacent to a first side of the main device, a second port extending along the first direction adjacent to a second side of the main device, a first shield structure adjacent to a third side of the main device, a second shield structure adjacent to a fourth side of the main device, a first connecting structure extending along a second direction to connect the first port and the main device, and a second connecting structure extending along the second direction to connect the second port and the main device.

A transistor package having four terminals includes a semiconductor transistor chip and a semiconductor diode chip. The semiconductor transistor chip includes a control electrode and a first load electrode on a first surface and a second load electrode on a second surface opposite the first surface. The semiconductor diode chip includes a first diode electrode on a first surface and a second diode electrode on a second surface opposite the first surface. The transistor package includes a first terminal electrically connected to the control electrode, a second terminal electrically connected to the first diode electrode, a third terminal electrically connected to the first load electrode and a fourth terminal electrically connected to the second load electrode. At least the first terminal, the second terminal and the third terminal protrude from one side of transistor package. The first terminal is arranged between the second terminal and the third terminal.

An ohmic contact includes a first semiconductor layer a second semiconductor layer, and a heterointerface between the first semiconductor layer and the second semiconductor layer. The second semiconductor layer has a two-dimensional electron sheet region in which a two-dimensional electron sheet is formed. The ohmic contact further includes a metal terminal covering the first semiconductor layer and filling a plurality of direct access pathways that provide direct lateral contact with the two-dimensional electron sheet region. The semiconductor device is fabricated by providing the semiconductor layers, etching the direct access pathways, and depositing metal material to fill the direct access pathways and cover the semiconductor layers. The ohmic contact may be part of a high-electron-mobility transistor that achieves low contact resistance with either no annealing at all (as-deposited metal), or at an anneal temperature that is much lower than industry-standard anneal temperatures to achieve sufficiently low contact resistance.

Circuit-Under-Pad (CUP) device topologies for high-current lateral power switching devices are disclosed, in which the interconnect structure and pad placement are configured for reduced source and common source inductance. In an example topology for a power semiconductor device comprising a lateral GaN HEMT, the source bus runs across a center of the active area, substantially centered between first and second extremities of source finger electrodes, with laterally extending tabs contacting the underlying source finger electrodes. The drain bus is spaced from the source bus and comprises laterally extending tabs contacting the underlying drain finger electrodes. The gate bus is centrally placed and runs adjacent the source bus. Preferably, the interconnect structure comprises a dedicated gate return bus to separate the gate drive loop from the power loop. Proposed CUP device structures provide for lower source and common source inductance and/or higher current carrying capability per unit device area.

RF transistor amplifiers include an RF transistor amplifier die having a semiconductor layer structure, a coupling element on an upper surface of the semiconductor layer structure, and an interconnect structure on an upper surface of the coupling element so that the RF transistor amplifier die and the interconnect structure are in a stacked arrangement. The coupling element includes a first shielded transmission line structure.

An ohmic contact includes a first semiconductor layer a second semiconductor layer, and a heterointerface between the first semiconductor layer and the second semiconductor layer. The second semiconductor layer has a two-dimensional electron sheet region in which a two-dimensional electron sheet is formed. The ohmic contact further includes a metal terminal covering the first semiconductor layer and filling a plurality of direct access pathways that provide direct lateral contact with the two-dimensional electron sheet region. The semiconductor device is fabricated by providing the semiconductor layers, etching the direct access pathways, and depositing metal material to fill the direct access pathways and cover the semiconductor layers. The ohmic contact may be part of a high-electron-mobility transistor that achieves low contact resistance with either no annealing at all (as-deposited metal), or at an anneal temperature that is much lower than industry-standard anneal temperatures to achieve sufficiently low contact resistance.

Disclosed is a semiconductor package. The semiconductor package may include a substrate a semiconductor chip mounted over a surface of the substrate such that an active surface of the semiconductor chip faces the surface of the substrate. The semiconductor chip and substrate may be configured for shielding or scattering electromagnetic waves.