A method, apparatus, and system for forming a semiconductor structure. A first oxide layer located on a set of group III nitride layers formed on a silicon carbide substrate is bonded to a second oxide layer located on a carrier substrate to form an oxide layer located between the carrier substrate and the set of group III nitride layers. The silicon carbide substrate has a doped layer. The silicon carbide substrate having the doped layer is etched using a photo-electrochemical etching process, wherein a doping level of the doped layer is such that the doped layer is removed and a silicon carbide layer in the silicon carbide substrate remains unetched. The semiconductor structure is formed using the silicon carbide layer and the set of group III nitride layers.

A mesa structure includes a substrate. A mesa protrudes out of the substrate. The mesa includes a slope and a top surface. The slope surrounds the top surface. A lattice damage area is disposed at inner side of the slope. The mesa can optionally further includes an insulating layer covering the lattice damage area. The insulating layer includes an oxide layer or a nitride layer.

Semiconductor structures with reduced parasitic capacitance between interconnects and ground, for example, are described. In one case, a semiconductor structure includes a substrate and a low dielectric constant material region in the substrate. The low dielectric constant material region is positioned between a first device area in the semiconductor structure and a second device area in the semiconductor structure. The semiconductor structure also includes a III-nitride material layer over the substrate. The III-nitride material layer extends over the substrate in the first device area, over the low dielectric constant material region, and over the substrate in the second device area. The semiconductor structure can also include a first device formed in the III-nitride material layer in the first device area, a second device in the III-nitride material layer in the second device area, and an interconnect formed over the low dielectric constant material region. The interconnect can provide a continuous conductive path of metal from the first device area, over the low dielectric constant material region, and to the second device area.

A semiconductor device includes an enhancement mode high electron mobility transistor (HEMT) with an active region and an isolation region. The HEMT includes a substrate, a group III-V body layer, a group III-V barrier layer, a group III-V gate structure and a group III-V patterned structure. The group III-V body layer and the group III-V barrier layer are disposed on the substrate. The group III-V gate structure is disposed on the group III-V barrier layer within the active region. The group III-V patterned structure is disposed on the group III-V barrier layer within the isolation region. The composition of the group III-V patterned structure is the same as the composition of the group III-V gate structure.

The present disclosure relates to an integrated chip. The integrated chip includes a substrate. A doped isolation region is disposed within the substrate and includes a horizontally extending segment and one or more vertically extending segments extending outward from the horizontally extending segment. The substrate includes a first sidewall and a second sidewall separated from the first sidewall a non-zero distance. The non-zero distance is directly over the one or more vertically extending segments.

According to one aspect of the present disclosure, a semiconductor device includes a substrate; a drift layer of a first conductivity type provided on the substrate; a base layer of a second conductivity type provided above the drift layer on the substrate; a source layer of the first conductivity type provided on an upper surface side of the base layer; a first electrode electrically connected to the source layer; a second electrode provided on the rear surface of the substrate; a gate electrode; a trench gate extending from an upper surface of the substrate to the drift layer; and a first bottom layer of the second conductivity type provided below the trench gate in the drift layer, wherein a first distance between a portion of the first bottom layer where an impurity concentration peaks in a thickness direction and the trench gate is larger than 1 μm.

A transistor device includes a semiconductor substrate and a gate structure formed over the substrate. Forming the gate structure may include steps of forming a multi-layer dielectric stack over the substrate, performing an anisotropic dry etch of the multi-layer dielectric stack to form a gate channel opening, forming a conformal dielectric layer over the substrate, performing an anisotropic dry etch of the conformal dielectric layer to form dielectric sidewalls in the gate channel opening, etching portions of dielectric layers in a gate channel region, and forming gate metal in the gate channel region. Dielectric spacers may be similarly formed in a field plate channel opening prior to formation of a field plate of the transistor. By forming dielectric spacers in the gate channel opening, the length of the gate structure can be advantageously decreased.

A semiconductor device includes a first nitride-based semiconductor layer, a second nitride-based semiconductor layer, a gate electrode, a source electrode, a drain electrode, and a group of negatively-charged ions. The gate electrode is located between the source and drain electrodes to define a drift region between the gate and drain electrodes. A group of negatively-charged ions are implanted into the drift region and over the 2DEG region and spaced apart from the gate and drain electrodes and spaced apart from an area directly beneath the gate and drain electrodes. The gate electrode is closer to the negatively-charged ions than the drain electrode, such that the negatively-charged ions deplete at least one portion of the 2DEG region which is near the gate electrode.

A nitride-based semiconductor device includes a first nitride-based semiconductor layer, a lattice layer, a third nitride-based semiconductor layer, a first source electrode and a second electrode, and a gate electrode. The second nitride-based semiconductor layer is disposed over the first nitride-based semiconductor layer. The lattice layer is disposed between the first and second nitride-based semiconductor layers and doped to the first conductivity type. The lattice layer comprises a plurality of first III-V layers and a plurality of second III-V layers alternatively stacked. Each of the first III-V layers has a high resistivity region and a current aperture enclosed by the high resistivity region. The high resistivity region comprises more metal oxides than the current aperture. Interfaces formed between the high resistivity regions and the current apertures among the first III-V layers align with each other. The gate electrode aligns with the current aperture.

A method of wafer scale packaging acoustic resonator devices and an apparatus therefor. The method including providing a partially completed semiconductor substrate comprising a plurality of single crystal acoustic resonator devices, each having a first electrode member, a second electrode member, and an overlying passivation material. At least one of the devices to be configured with an external connection, a repassivation material overlying the passivation material, an under metal material overlying the repassivation material. Copper pillar interconnect structures are then configured overlying the electrode members, and solder bump structures are form overlying the copper pillar interconnect structures.