Vertical etch heterolithic integrated circuit devices are described. A method of manufacturing NIP diodes is described in one example. A P-type substrate is provided, and an intrinsic layer is formed on the P-type substrate. An oxide layer is formed on the intrinsic layer, and one or more openings are formed in the oxide layer. One or more N-type regions are implanted in the intrinsic layer through the openings in the oxide layer. The N-type regions form cathodes of the NIP diodes. A dielectric layer deposited over the oxide layer is selectively etched away with the oxide layer to expose certain ranges of the intrinsic layer to define a geometry of the NIP diodes. The intrinsic layer and the P-type substrate are vertically etched away within the ranges to expose sidewalls of the intrinsic layer and the P-type substrate. The P-type substrate forms the anodes of the NIP diodes.

A method of manufacturing a diode structure includes forming a first stack on a silicon layer on a substrate. A first sidewall spacer extending along and covering a sidewall of the first stack is formed. The silicon layer is selectively etched to a first predetermined depth, thereby forming a second stack. The remaining silicon layer includes a silicon base. A second sidewall spacer extending along and covering a sidewall of the second stack is formed. The silicon base is selectively etched to form a third stack on the substrate. With the second sidewall spacer as a mask, lateral plasma ion implantation is performed. Defects at the interface between two adjacent semiconductor layers can be reduced by the method.

A diode of the present disclosure includes a stacked structure, and a first connection section and a second connection section provided at respective ends of the stacked structure in a length direction. The stacked structure includes a first structure and a second structure each having a nanowire structure or a nanosheet structure and stacked alternately in a thickness direction. The first connection section has a first conductivity type, and the second connection section has a second conductivity type. The diode A further includes a control electrode section formed to extend at least from a top portion to a side surface of the stacked structure and spaced apart from the first connection section and the second connection section. The first connection section and the control electrode section or the second connection section and the control electrode section are connected electrically.

A gallium nitride power device, including: a gallium nitride substrate; cathodes; a plurality of gallium nitride protruding structures arranged on the gallium nitride substrate and between the cathodes, a groove is formed between adjacent gallium nitride protruding structures; an electron transport layer, covering a top portion and side surfaces of each of the gallium nitride protruding structures; a gallium nitride layer, arranged on the electron transport layer and filling each of the grooves; a plurality of second conductivity type regions, where each of the second conductivity type regions extends downward from a top portion of the gallium nitride layer into one of the grooves, and the top portion of each of the gallium nitride protruding structures is higher than a bottom portion of each of the second conductivity type regions; and an anode, arranged on the gallium nitride layer and the second conductivity type regions.

Electronic devices and more particularly diamond-based electronic devices and corresponding contact structures are disclosed. Electrical contact structures to diamond layers, including n-type, phosphorus doped single-crystal diamond are disclosed. In particular, electrical contact structures are formed through an arrangement of one or more nanostructured carbon layers with high nitrogen incorporation that are provided between metal contacts and n-type diamond layers in diamond-based electronic devices. Nanostructured carbon layers may be configured to mitigate reduced phosphorus incorporation in n-type diamond layers, thereby providing low specific contact resistances for corresponding devices. Diamond p-i-n diodes for direct electron emission applications are also disclosed that include electrical contact structures with nanostructured carbon layers.

A semiconductor device with multiple zero differential transconductance includes: a conductive substrate; a first insulating layer and a second insulating layer disposed on the conductive substrate; a first semiconductor and a second semiconductor disposed on first portions of the first insulating layer and the second insulating layer, respectively; a first buffer layer and a second buffer layer disposed on electrode contact areas of the first semiconductor and the second semiconductor, respectively; and an anode electrode and a cathode electrode disposed on second portions, which are different from the first portions, of the first insulating layer and the second insulating layer and on the first buffer layer and the second buffer layer, respectively, wherein the first semiconductor and the second semiconductor are disposed in parallel with each other and connected by the anode electrode and the cathode electrode.

A semiconductor device according to the present disclosure includes: a semiconductor substrate with a first main surface and a second main surface; a drift layer of a first conductivity type formed in the semiconductor substrate; a first impurity diffusion layer of a second conductivity type formed on the drift layer to be closer to the first main surface; and a buffer layer of the first conductivity type formed on the drift layer to be closer to the second main surface and higher in peak impurity concentration than the drift layer. The drift layer has a first trap, a second trap, and a third trap, whose energy level each is lower than energy at a bottom of a conduction band by 0.246 eV, 0.349 eV, and 0.470 eV. The second trap has trap density of equal to or greater than 2.0×10.sup.11 cm.sup.−3.

Implementations of a diode may include a first electrode; a first dielectric layer coupled to the first electrode; a second dielectric layer coupled to the first dielectric layer; and a second electrode coupled to the second dielectric layer. The first dielectric layer may be one of silicon dioxide or aluminum oxide; and the second dielectric layer may be one of niobium oxide, tantalum oxide, zirconium oxide, hafnium oxide, or any combination thereof.

A semiconductor structure is provided. The semiconductor structure includes a substrate, a diode region, and a dummy stripe. The substrate has a first surface. The diode region is in the substrate. The diode region includes a first implant region of a first conductivity type approximate to the first surface, and a second implant region of a second conductivity type approximate to the first surface and surrounded by the first implant region. The dummy stripe is on the first surface and located between the first implant region and the second implant region. A method for manufacturing a semiconductor structure is also provided.

Various embodiments of the present disclosure are directed towards a semiconductor structure including a buffer layer disposed between an active layer and a substrate. The active layer overlies the substrate. The substrate and the buffer layer include a plurality of pillar structures that extend vertically from a bottom surface of the active layer in a direction away from the active layer. A top electrode overlies an upper surface of the active layer. A bottom electrode underlies the substrate. The bottom electrode includes a conductive body and a plurality of conductive structures that respectively extend continuously from the conductive body, along sidewalls of the pillar structures, to a lower surface of the active layer.