Abstract: A channel layer is grown over a substrate, and an active layer is grown over the channel layer, wherein the active layer has a band gap discontinuity with the channel layer. A dielectric layer is deposited over the active layer, and the dielectric layer is patterned to expose a portion of the active layer. A metal diffusion barrier is formed over the exposed portion of the active layer, and a gate is deposited over the metal diffusion barrier.

Abstract: A transistor includes a substrate, a channel layer over the substrate, an active layer over the channel layer, a metal diffusion barrier over the active layer, and a gate over the metal diffusion barrier. The active layer has a band gap discontinuity with the channel layer.

Abstract: A group III-V transistor device employing a novel layout for isolating and/or defining the active region is provided. A group III-V heterojunction is arranged over or within a substrate, and an inner drain electrode is arranged over the group III-V heterojunction. A gate has a ring shape and is arranged over the group III-V heterojunction around the inner drain electrode. An outer source electrode has a ring-shaped region arranged over the group III-V heterojunction around the gate. A method for manufacturing the group III-V transistor device is also provided.

Abstract: Some embodiments relate to a method of dicing a semiconductor wafer. The semiconductor wafer that includes a device structure that is formed within a device layer. The device layer is arranged within an upper surface the device layer. A crack stop is formed, which surrounds the device structure and reinforces the semiconductor wafer to prevent cracking during dicing. A laser is used to form a groove along a scribe line outside the crack stop. The groove extends completely through the device layer, and into an upper surface region of the semiconductor wafer. The semiconductor wafer is then cut along the grooved scribe line with a cutting blade to singulate the semiconductor wafer into two or more die. By extending the groove completely through the device layer, the method avoids damage to the device layer caused by the blade saw, and thus avoids an associated performance degradation of the device structure.

Abstract: A group III-V transistor device employing a novel layout for isolating and/or defining the active region is provided. A group III-V heterojunction is arranged over or within a substrate, and an inner drain electrode is arranged over the group III-V heterojunction. A gate has a ring shape and is arranged over the group III-V heterojunction around the inner drain electrode. An outer source electrode has a ring-shaped region arranged over the group III-V heterojunction around the gate. A method for manufacturing the group III-V transistor device is also provided.

Abstract: A semiconductor is fabricated on a silicon (Si) substrate. The semiconductor is III-nitride based. The Si substrate is partially isolated. Etching is directly processed from top on a chip for solving wire-width problem. The Si substrate does not need to be made thin. The chip can be large scaled and be prevented from bowing. Thus, the present invention simplifies producing procedure and reduces production cost. Besides, for a large-scaled chip, the breakdown voltage is enhanced; and, without making the Si substrate thin, the on-state current is remained the same and the heat problem is weakened.

Abstract: A semiconductor is fabricated on a silicon (Si) substrate. The semiconductor is III-nitride based. The Si substrate is partially isolated. Etching is directly processed from top on a chip for solving wire-width problem. The Si substrate does not need to be made thin. The chip can be large scaled and be prevented from bowing. Thus, the present invention simplifies producing procedure and reduces production cost. Besides, for a large-scaled chip, the breakdown voltage is enhanced; and, without making the Si substrate thin, the on-state current is remained the same and the heat problem is weakened.

Abstract: The present disclosure relates to a high electron mobility transistor compatible power lateral field-effect rectifier device. In some embodiments, the rectifier device has an electron supply layer located over a layer of semiconductor material at a position between an anode terminal and a cathode terminal. A layer of doped III-N semiconductor material is disposed over the electron supply layer. A layer of gate isolation material is located over the layer of doped III-N semiconductor material. A gate structure is disposed over layer of gate isolation material, such that the gate structure is separated from the electron supply layer by the layer of gate isolation material and the layer of doped III-N semiconductor material. The layer of doped III-N semiconductor material modulates the threshold voltage of the rectifier device, while the layer of gate isolation material provides a barrier that gives the rectifier device a low leakage.

Abstract: A transistor includes a substrate, a channel layer over the substrate, an active layer over the channel layer, a metal diffusion barrier over the active layer, and a gate over the metal diffusion barrier. The active layer has a band gap discontinuity with the channel layer.

Abstract: A Schottky diode structure and a method for fabricating the same, which are based on the principle of charge compensation, wherein a P-type gallium nitride layer is added to a Schottky diode structure, and wherein the PN junction of the P-type gallium nitride layer and the N-type gallium nitride layer decreases the non-uniformity of the surface electric field distribution, whereby the breakdown voltage of the element is raised.

Abstract: A Schottky diode structure and a method for fabricating the same, which are based on the principle of charge compensation, wherein a P-type gallium nitride layer is added to a Schottky diode structure, and wherein the PN junction of the P-type gallium nitride layer and the N-type gallium nitride layer decreases the non-uniformity of the surface electric field distribution, whereby the breakdown voltage of the element is raised.