A semiconductor device includes a nitride semiconductor layer, an insulating layer provided on a surface of the nitride semiconductor layer, and a metal electrode in contact with the surface through an opening penetrating the insulating layer. The insulating layer includes a first SiN film having a concentration of chlorine (Cl) of 1×10.sup.20 [atoms/cm.sup.3] or more and a thickness of 30 nm or less, and a second SiN film having a concentration of chlorine (Cl) of 1×10.sup.19 [atoms/cm.sup.3] or less.

A semiconductor device includes a nitride semiconductor laminated structure formed on a substrate, a source electrode formed on the nitride semiconductor laminated structure, a drain electrode and a gate electrode, and a surface protection film covering the nitride semiconductor laminated structure. the nitride semiconductor laminated structure includes: a first nitride semiconductor layer formed on the substrate; and a second nitride semiconductor layer formed on the first nitride semiconductor layer and having a composition different from the first nitride semiconductor layer. The surface protection film includes: a first insulating film formed to have contact with the gate electrode; and a second insulating film formed adjacent to the first insulating film and having a higher carbon concentration than the first insulating film.

A semiconductor device includes a channel layer, a barrier layer, and at least one contact layer. The channel layer includes a GaN-based material. The barrier layer includes an AlInN-based material in which a composition ratio of In is higher than 18%, and is provided on the channel layer. The at least one contact layer includes a conductive-type semiconductor material and is provided to penetrate the barrier layer and reach the channel layer.

A high electron mobility transistor and a method of manufacturing the same are disclosed. The high electron mobility transistor includes a channel layer, a channel supplying layer causing generation of a two-dimensional electron gas (2DEG) in the channel layer, a source electrode and a drain electrode provided on respective sides of the channel supplying layer, a depletion forming layer provided on the channel supplying layer to form a depletion region in the 2DEG, a gate electrode provided on a portion of the depletion forming layer, and a current limiting layer provided to contact the gate electrode on another portion of the depletion forming layer. The current limiting layer limits a current flow from the gate electrode to the depletion forming layer according to a voltage applied to the gate electrode.

A method of fabricating a device involves forming a plurality of structures, such that each structure of the plurality includes a substrate and an epitaxial layer on the substrate. The epitaxial layer and the substrate have a lattice mismatch. The method further includes forming an electrical contact on the epitaxial layer of a selected structure of the plurality of structures and performing a current leakage measurement quality control test for the selected structure of the plurality of structures through the electrical contact. The method also involves forming a device on each of the remaining structures of the plurality of structures if the selected structure passed the leakage measurement quality control test or discarding each of the remaining structures of the plurality of structures if the selected structure did not pass the leakage measurement quality control test.

Embedded die packaging for high voltage, high temperature operation of power semiconductor devices is disclosed, wherein a power semiconductor die is embedded in package body comprising dielectric layers and electrically conductive layers, and where an external dielectric coating, such as a solder resist coating is provided on one or both external sides of the package body. The solder resist coating is patterned to avoid inside corners, e.g. the solder resist does not extend around or between electrical contact areas and thermal pads. It is observed that in conventional solder resist coatings, during thermal cycling, cracks tend to initiate at high stress points, such as at sharp inside corners. A solder resist layout which omits inside corners, and comprises outside corners only, is demonstrated to provide significantly improved resistance to initiation and propagation of cracks. Where inside corners are unavoidable, they are appropriately radiused to reduce stress.

The present disclosure provides a high electron mobility transistor including a channel layer; a barrier layer on the channel layer and configured to induce formation of a 2-dimensional electron gas (2DEG) to the channel layer; a p-type semiconductor layer on the barrier layer; a first passivation layer on the barrier layer and including a quaternary material of Al, Ga, O, and N; a gate electrode on the p-type semiconductor layer; and a source electrode and a drain electrode provided on both sides of the barrier layer and separated from the gate electrode.

A semiconductor device (100, 100′, 100″) and a method for manufacturing a semiconductor device (100, 100′, 100″). The semiconductor device (100, 100′, 100″) includes a substrate (104, 106), a GaN layer (112), and an AlGaN layer (114). The GaN layer (112) is located between the substrate (104, 106) and the AlGaN layer (114). The device further includes at least one contact (130, 132, 134), comprising a central portion (150) and an edge portion (152), and a passivation layer (160) located at least between the edge portion (152) of the contact (130, 132, 134) and the AlGaN layer (114). The edge portion (152) is spaced apart from an upper surface of the passivation layer (160). The edge portion (152) may be spaced apart from the passivation layer (160) by a further layer (170) or by an air gap (172).

A manufacturing method of an HEMT includes: forming a heterostructure; forming a first gate layer of intrinsic semiconductor material on the heterostructure; forming a second gate layer, containing dopant impurities of a P type, on the first gate layer; removing first portions of the second gate layer so that second portions, not removed, of the second gate layer form a doped gate region; and carrying out a thermal annealing of the doped gate region so as to cause a diffusion of said dopant impurities of the P type in the first gate layer and in the heterostructure, with a concentration, in the heterostructure, that decreases as the lateral distance from the doped gate region increases.

A semiconductor device includes a carrier generation layer disposed on a channel layer, a source contact and a drain contact disposed on the carrier generation layer, and a gate contact disposed between the source contact and the drain contact. The semiconductor device further includes a number N of conductive stripes disposed directly on the carrier generation layer in an area between the drain contact and the gate contact, and a number M of conductive transverse stripes disposed directly on the carrier generation layer in the area between the drain contact and the gate contact. Each of the N conductive stripes extends from and is electrically coupled to the drain contact. Each of the M conductive transverse stripes is aligned non-parallel to the N conductive stripes and is not in direct physical contact with the N conductive stripes.