In some embodiments, a semiconductor structure includes a first device and a second device. The first device has a first surface. The first device includes a first active region defined by a first material system. The second device has a second surface. The second surface is coplanar with the first surface. The second device includes a second active region defined by a second material system. The second material system is different from the first material system.

Microelectronic structures embodying the present invention include a field effect transistor (FET) having highly conductive source/drain extensions. Formation of such highly conductive source/drain extensions includes forming a passivated recess which is back filled by epitaxial deposition of doped material to form the source/drain junctions. The recesses include a laterally extending region that underlies a portion of the gate structure. Such a lateral extension may underlie a sidewall spacer adjacent to the vertical sidewalls of the gate electrode, or may extend further into the channel portion of a FET such that the lateral recess underlies the gate electrode portion of the gate structure. In one embodiment the recess is back filled by an in-situ epitaxial deposition of a bilayer of oppositely doped material. In this way, a very abrupt junction is achieved that provides a relatively low resistance source/drain extension and further provides good off-state subthreshold leakage characteristics. Alternative embodiments can be implemented with a back filled recess of a single conductivity type.

A semiconductor disolator device is provided. The device may include a silicon-on-insulator (SOI) substrate, a body layer disposed on the SOI substrate, a first p-type well disposed on the body layer, a first n-type well disposed on the first p-type well to form a first p-n junction, and a second p-type well that is spaced a predetermined distance from at least one of the first p-type well and first n-type well.

A manufacturable and economically viable edge termination structure allows a semiconductor device to withstand a very high reverse blocking voltage (for example, 8500 volts) without suffering breakdown. A P type peripheral aluminum diffusion region extends around the bottom periphery of a thick die. The peripheral aluminum diffusion region extends upward from the bottom surface of the die, extending into N type bulk silicon. A deep peripheral trench extends around the upper periphery of the die. The deep trench extends from the topside of the die down toward the peripheral aluminum diffusion region. A P type sidewall doped region extends laterally inward from the inner sidewall of the trench, and extends laterally outward from the outer sidewall of the trench. The P type sidewall doped region joins with the P type peripheral aluminum diffusion region, thereby forming a separation edge diffusion structure that surrounds the active area of the die.

A horizontal current bipolar transistor comprises a substrate of first conductivity type, defining a wafer plane parallel to said substrate; a collector drift region above said substrate, having a second, opposite conductivity type, forming a first metallurgical pn-junction with said substrate; a collector contact region having second conductivity type above said substrate and adjacent to said collector drift region; a base region comprising a sidewall at an acute angle to said wafer plane, having first conductivity type, and forming a second metallurgical pn-junction with said collector drift region; and a buried region having first conductivity type between said substrate and said collector drift region forming a third metallurgical pn-junction with the collector drift region. An intercept between an isometric projection of said base region on said wafer plane and an isometric projection of said buried region on said wafer plane is smaller than said isometric projection of said base region.

A device includes a semiconductor substrate, a buried doped isolation layer disposed in the semiconductor substrate to isolate the device, a drain region disposed in the semiconductor substrate and to which a voltage is applied during operation, and a depletion region disposed in the semiconductor substrate and having a conductivity type in common with the buried doped isolation barrier and the drain region. The depletion region reaches a depth in the semiconductor substrate to be in contact with the buried doped isolation layer. The depletion region establishes an electrical link between the buried doped isolation layer and the drain region such that the buried doped isolation layer is biased at a voltage level lower than the voltage applied to the drain region.

A semiconductor device includes a P-type semiconductor substrate, a plurality of N-type buried diffusion layers that are arranged in the semiconductor substrate, an N-type first semiconductor layer that is arranged in a first region on a first buried diffusion layer, an N-type second semiconductor layer that is arranged in a second region on a second buried diffusion layer, an N-type first impurity diffusion region that surrounds the first region in plan view, a P-type second impurity diffusion region that is arranged in the second semiconductor layer, an N-type third impurity diffusion region that is arranged in the second semiconductor layer, an N-type fourth impurity diffusion region that is arranged in the first semiconductor layer. The second region is a region in which an N-type impurity diffusion region that has a higher impurity concentration than the second semiconductor layer cannot be arranged.

The present invention discloses an electronic device using a group III nitride substrate fabricated via the ammonothermal method. By utilizing the high-electron concentration of ammonothermally grown substrates having the dislocation density less than 10.sup.5 cm.sup.2, combined with a high-purity active layer of Ga.sub.1-x-yAl.sub.xIn.sub.yN (0x1, 0y1) grown by a vapor phase method, the device can attain high level of breakdown voltage as well as low on-resistance. To realize a good matching between the ammonothermally grown substrate and the high-purity active layer, a transition layer is optionally introduced. The active layer is thicker than a depletion region created by a device structure in the active layer.

A semiconductor device of an embodiment includes a first layer, a second layer provided on the first layer, the second layer forming a two-dimensional electron gas in the first layer; a source electrode provided on the second layer, a drain electrode provided on the second layer, a gate electrode provided between the source electrode and the drain electrode on the second layer and a first insulating layer provided between the gate electrode and the drain electrode on the second layer. The first insulating layer includes a first film, a second film having a higher oxygen density than the first film and a first region provided between the first film and the second film. The first region contains at least one first element selected from the group consisting of F, H, and D, the first region having a first peak of concentration of the first element.

A semiconductor device with a substrate, a low defect layer formed in a fixed position relative to the substrate, and a barrier layer comprising III-N semiconductor material formed on the low-defect layer and forming an electron gas in the low-defect layer. The device also has a source contact, a drain contact, and a gate contact for receiving a potential, the potential for adjusting a conductive path in the electron gas and between the source contact and the drain contact. Lastly, the device has a one-sided PN junction between the barrier layer and the substrate.