A Schottky barrier diode includes a substrate, a first semiconductor layer formed on the substrate, a second semiconductor layer formed on the first semiconductor layer, and a metal layer formed on the second semiconductor layer to form a Schottky barrier, wherein the first semiconductor layer and the second semiconductor layer are formed of different materials, and a conduction band offset between the first semiconductor layer and the second semiconductor layer is less than a set value.

A P-i-N diode structure includes a group III-N semiconductor material disposed on a substrate. An n-doped raised drain structure is disposed on the group III-N semiconductor material. An intrinsic group III-N semiconductor material is disposed on the n-doped raised drain structure. A p-doped group III-N semiconductor material is disposed on the intrinsic group III-N semiconductor material. A first electrode is connected to the p-doped group III-N semiconductor material. A second electrode is electrically coupled to the n-doped raised drain structure. In an embodiment, a group III-N transistor is electrically coupled to the P-i-N diode. In an embodiment, a group III-N transistor is electrically isolated from the P-i-N diode. In an embodiment, a gate electrode and an n-doped raised drain structure are electrically coupled to the n-doped raised drain structure and the second electrode of the P-i-N diode to form the group III-N transistor.

Transistor connected diode structures are described. In an example, the transistor connected diode structure includes a group III-N semiconductor material disposed on substrate. A raised source structure and a raised drain structure are disposed on the group III-N semiconductor material. A mobility enhancement layer is disposed on the group III-N semiconductor material. A polarization charge inducing layer is disposed on the mobility enhancement layer, the polarization charge inducing layer having a first portion and a second portion separated by a gap. A gate dielectric layer disposed on the mobility enhancement layer in the gap. A first metal electrode having a first portion disposed on the raised drain structure, a second portion disposed above the second portion of the polarization charge inducing layer and a third portion disposed on the gate dielectric layer in the gap. A second metal electrode disposed on the raised source structure.

A nitride semiconductor device 1 includes a first transistor 3 which is constituted of a normally-off transistor and functions as a main transistor and a second transistor 4 which is constituted of a normally-on transistor and arranged to limit a gate current of the first transistor. The first transistor 3 includes a first electron transit layer 7A constituted of a nitride semiconductor and a first electron supply layer 8A which is formed on the first electron transit layer and constituted of a nitride semiconductor. The second transistor 4 includes a second electron transit layer 7B constituted of a nitride semiconductor and a second electron supply layer 8B which is formed on the second electron transit layer and constituted of a nitride semiconductor. A gate electrode 51 and a source electrode 44 of the second transistor 4 are electrically connected to a gate electrode 16 of the first transistor 3.

Described herein are methods for using remote plasma chemical vapor deposition (RP-CVD) and sputtering deposition to grow layers for light emitting devices. A method includes growing a light emitting device structure on a growth substrate, and growing a tunnel junction on the light emitting device structure using at least one of RP-CVD and sputtering deposition. The tunnel junction includes a p++ layer in direct contact with a p-type region, where the p++ layer is grown by using at least one of RP-CVD and sputtering deposition. Another method for growing a device includes growing a p-type region over a growth substrate using at least one of RP-CVD and sputtering deposition, and growing further layers over the p-type region. Another method for growing a device includes growing a light emitting region and an n-type region using at least one of RP-CVD and sputtering deposition over a p-type region.

Described herein are methods for using remote plasma chemical vapor deposition (RP-CVD) and sputtering deposition to grow layers for light emitting devices. A method includes growing a light emitting device structure on a growth substrate, and growing a tunnel junction on the light emitting device structure using at least one of RP-CVD and sputtering deposition. The tunnel junction includes a p++ layer in direct contact with a p-type region, where the p++ layer is grown by using at least one of RP-CVD and sputtering deposition. Another method for growing a device includes growing a p-type region over a growth substrate using at least one of RP-CVD and sputtering deposition, and growing further layers over the p-type region. Another method for growing a device includes growing a light emitting region and an n-type region using at least one of RP-CVD and sputtering deposition over a p-type region.

Described herein are methods for using remote plasma chemical vapor deposition (RP-CVD) and sputtering deposition to grow layers for light emitting devices. A method includes growing a light emitting device structure on a growth substrate, and growing a tunnel junction on the light emitting device structure using at least one of RP-CVD and sputtering deposition. The tunnel junction includes a p++ layer in direct contact with a p-type region, where the p++ layer is grown by using at least one of RP-CVD and sputtering deposition. Another method for growing a device includes growing a p-type region over a growth substrate using at least one of RP-CVD and sputtering deposition, and growing further layers over the p-type region. Another method for growing a device includes growing a light emitting region and an n-type region using at least one of RP-CVD and sputtering deposition over a p-type region.

The present invention disclose an Electrostatic doping (ED)-based graphene nanoribbon (GNR) tunneling field-effect transistor (TFET) with tri-gate design. This device uses hydrogen-passivated GNR heterojunction as a carrier path way and functions as a power switch providing a switching speed of .sup.0.3 ps.sup.1 an I.sub.ON/I.sub.OFF ratio as high as 10.sup.14 with the on-state current in the order of 10.sup.3 A/m. This disclosed invention consists of two electrode, two electrode extensions, six metallic gate regions, and six dielectric regions.

A P-i-N diode structure includes a group III-N semiconductor material disposed on a substrate. An n-doped raised drain structure is disposed on the group III-N semiconductor material. An intrinsic group III-N semiconductor material is disposed on the n-doped raised drain structure. A p-doped group III-N semiconductor material is disposed on the intrinsic group III-N semiconductor material. A first electrode is connected to the p-doped group III-N semiconductor material. A second electrode is electrically coupled to the n-doped raised drain structure. In an embodiment, a group III-N transistor is electrically coupled to the P-i-N diode. In an embodiment, a group III-N transistor is electrically isolated from the P-i-N diode. In an embodiment, a gate electrode and an n-doped raised drain structure are electrically coupled to the n-doped raised drain structure and the second electrode of the P-i-N diode to form the group III-N transistor.

A transistor connected diode structure is described. In an example, the transistor connected diode structure includes a group III-N semiconductor material disposed on substrate. A raised source structure and a raised drain structure are disposed on the group III-N semiconductor material. A mobility enhancement layer is disposed on the group III-N semiconductor material. A polarization charge inducing layer is disposed on the mobility enhancement layer, the polarization charge inducing layer having a first portion and a second portion separated by a gap. A gate dielectric layer disposed on the mobility enhancement layer in the gap. A first metal electrode having a first portion disposed on the raised drain structure, a second portion disposed above the second portion of the polarization charge inducing layer and a third portion disposed on the gate dielectric layer in the gap. A second metal electrode disposed on the raised source structure.