The present disclosure generally relates to an apparatus for high density memory with integrated logic. A three terminal ReRAM device, which includes a p-n junction and a Schottky barrier, that can switch from a low resistive state to a high resistive state is provided. The Schottky transistor memory device includes a source region, a drain region, a first p-type or n-type oxide layer disposed between the source and drain regions, a second p-type or n-type oxide layer, and a gate electrode. As voltage is applied to the gate electrode, the Schottky barrier breaks down, leading to the formation of a filament. The filament is non-volatile and short-circuits the reverse-biased barrier, keeping the device in a low resistance state. Removing the filament by reversing the polarity of the voltage switches the device back to a high resistance state, allowing for the memory state to be readout through the gate electrode.

Apparatus and circuits with dual threshold voltage transistors and methods of fabricating the same are disclosed. In one example, a semiconductor structure is disclosed. The semiconductor structure includes: a substrate; a first layer comprising a first III-V semiconductor material formed over the substrate; a first transistor formed over the first layer, and a second transistor formed over the first layer. The first transistor comprises a first gate structure comprising a first material, a first source region and a first drain region. The second transistor comprises a second gate structure comprising a second material, a second source region and a second drain region. The first material is different from the second material.

Apparatus and circuits with dual threshold voltage transistors and methods of fabricating the same are disclosed. In one example, a semiconductor structure is disclosed. The semiconductor structure includes: a substrate; a first layer comprising a first III-V semiconductor material formed over the substrate; a first transistor formed over the first layer, and a second transistor formed over the first layer. The first transistor comprises a first gate structure comprising a first material, a first source region and a first drain region. The second transistor comprises a second gate structure comprising a second material, a second source region and a second drain region. The first material is different from the second material.

A monolithic integration of enhancement mode (E-mode) and depletion mode (D-mode) field effect transistors (FETs) comprises a compound semiconductor substrate overlaid by an epitaxial structure overlaid by source and drain electrodes. The epitaxial structure includes from bottom to top sequentially a buffer layer, a channel layer, a Schottky barrier layer, a first etch stop layer, and a first cap layer. The respective first gate metal layers of the D-mode and E-mode FET are in contact with the first etch stop layer. The D-mode and E-mode gate-sinking regions are beneath the respective first gate metal layers of the D-mode and E-mode gate electrode at least within the first etch stop layer. The first gate metal layer material of the D-mode is the same as that of the E-mode, where the first gate metal layer thickness of the E-mode is greater than that of the D-mode.

A monolithic integration of enhancement mode (E-mode) and depletion mode (D-mode) field effect transistors (FETs) comprises a compound semiconductor substrate overlaid by an epitaxial structure overlaid by source and drain electrodes. The epitaxial structure includes from bottom to top sequentially a buffer layer, a channel layer, a Schottky barrier layer, a first etch stop layer, and a first cap layer. The respective first gate metal layers of the D-mode and E-mode FET are in contact with the first etch stop layer. The D-mode and E-mode gate-sinking regions are beneath the respective first gate metal layers of the D-mode and E-mode gate electrode at least within the first etch stop layer. The first gate metal layer material of the D-mode is the same as that of the E-mode, where the first gate metal layer thickness of the E-mode is greater than that of the D-mode.

We disclose a III-nitride semiconductor based heterojunction power device comprising: a first heterojunction transistor formed on a substrate (4) and a second heterojunction transistor formed on the substrate. The first heterojunction transistor comprises: first III-nitride semiconductor region formed over the substrate, wherein the first III-nitride semiconductor region comprises a first heterojunction comprising at least one two dimensional carrier gas; a first terminal (8) operatively connected to the first III-nitride semiconductor region; a second terminal (9) laterally spaced from the first terminal and operatively connected to the first III-nitride semiconductor region; and a first gate region (10) over the first III-nitride semiconductor region between the first and second terminals. The second heterojunction transistor comprises: a second III-nitride semiconductor region formed over the substrate, wherein the second III-nitride semiconductor region comprises a second heterojunction comprising at least one two dimensional carrier gas; a third terminal (19) operatively connected to the second III-nitride semiconductor region; a fourth terminal (16) laterally spaced from the third terminal in the first dimension and operatively connected to the second III-nitride semiconductor region; a first plurality of highly doped semiconductor regions (18) of a first conductivity type formed over the second III-nitride semiconductor region, the first plurality of highly doped semiconductor regions being formed between the third terminal and the fourth terminal; and a second gate region (17) operatively connected to the first plurality of highly doped semiconductor regions. One of the first and second heterojunction transistors is an enhancement mode field effect transistor and the other of the first and second heterojunction transistors is a depletion mode field effect transistor.

A fault tolerant design for large area nitride semiconductor devices is provided, which facilitates testing and isolation of defective areas. A transistor comprises an array of a plurality of islands, each island comprising an active region, source and drain electrodes, and a gate electrode. Electrodes of each island are electrically isolated from electrodes of neighboring islands in at least one direction of the array. Source, drain and gate contact pads are provided to enable electrical testing of each island. After electrical testing of islands to identify defective islands, overlying electrical connections are formed to interconnect source electrodes in parallel, drain electrodes in parallel, and to interconnect gate electrodes to form a common gate electrode of large gate width Wg. Interconnections are provided selectively to good islands, while electrically isolating defective islands. This approach makes it economically feasible to fabricate large area GaN devices, including hybrid devices.

A fault tolerant design for large area nitride semiconductor devices is provided, which facilitates testing and isolation of defective areas. A transistor comprises an array of a plurality of islands, each island comprising an active region, source and drain electrodes, and a gate electrode. Electrodes of each island are electrically isolated from electrodes of neighboring islands in at least one direction of the array. Source, drain and gate contact pads are provided to enable electrical testing of each island. After electrical testing of islands to identify defective islands, overlying electrical connections are formed to interconnect source electrodes in parallel, drain electrodes in parallel, and to interconnect gate electrodes to form a common gate electrode of large gate width Wg. Interconnections are provided selectively to good islands, while electrically isolating defective islands. This approach makes it economically feasible to fabricate large area GaN devices, including hybrid devices.

Devices and systems comprising high current/high voltage GaN semiconductor devices are disclosed. A GaN die, comprising a lateral GaN transistor, is sandwiched between an overlying header and an underlying composite thermal dielectric layer. Fabrication comprises providing a conventional GaN device structure fabricated on a low cost silicon substrate (GaN-on-Si die), mechanically and electrically attaching source, drain and gate contact pads of the GaN-on-Si die to corresponding contact areas of conductive tracks of the header, then entirely removing the silicon substrate. The exposed substrate-surface of the epi-layer stack is coated with the composite dielectric thermal layer. Preferably, the header comprises a ceramic dielectric support layer having a CTE matched to the GaN epi-layer stack. The thermal dielectric layer comprises a high dielectric strength thermoplastic polymer and a dielectric filler having a high thermal conductivity. This structure offers improved electrical breakdown resistance and effective thermal dissipation compared to conventional GaN-on-Si device structures.

Devices and systems comprising high current/high voltage GaN semiconductor devices are disclosed. A GaN die, comprising a lateral GaN transistor, is sandwiched between an overlying header and an underlying composite thermal dielectric layer. Fabrication comprises providing a conventional GaN device structure fabricated on a low cost silicon substrate (GaN-on-Si die), mechanically and electrically attaching source, drain and gate contact pads of the GaN-on-Si die to corresponding contact areas of conductive tracks of the header, then entirely removing the silicon substrate. The exposed substrate-surface of the epi-layer stack is coated with the composite dielectric thermal layer. Preferably, the header comprises a ceramic dielectric support layer having a CTE matched to the GaN epi-layer stack. The thermal dielectric layer comprises a high dielectric strength thermoplastic polymer and a dielectric filler having a high thermal conductivity. This structure offers improved electrical breakdown resistance and effective thermal dissipation compared to conventional GaN-on-Si device structures.