A semiconductor structure and a formation method thereof are provided. The semiconductor structure includes: a semiconductor substrate having a source region or drain region therein. The source region or drain region has a groove. The semiconductor structure can include a metal silicide layer arranged on a surface of a sidewall of the groove and an insulating layer arranged on a bottom surface of the groove. The edge of the insulating layer is in contact with a bottom surface of the metal silicide layer on the sidewall of the groove; and a conducting layer filled in the groove and arranged on the metal silicide layer and the insulating layer. The semiconductor structure of the present disclosure can prevent electric current from leaking into the semiconductor substrate at the bottom of the source/drain region.

Devices, systems, methods, computer-implemented methods, apparatus, and/or computer program products that can facilitate a suspended Majorana fermion device comprising an ion implant defined nanorod in a semiconducting device are provided. According to an embodiment, a quantum computing device can comprise a Majorana fermion device coupled to an ion implanted region. The quantum computing device can further comprise an encapsulation film coupled to the ion implanted region and a substrate layer. The encapsulation film suspends the Majorana fermion device in the quantum computing device.

A nanowire bonding interconnect for fine-pitch microelectronics is provided. Vertical nanowires created on conductive pads provide a debris-tolerant bonding layer for making direct metal bonds between opposing pads or vias. Nanowires may be grown from a nanoporous medium with a height between 200-1000 nanometers and a height-to-diameter aspect ratio that enables the nanowires to partially collapse against the opposing conductive pads, creating contact pressure for nanowires to direct-bond to opposing pads. Nanowires may have diameters less than 200 nanometers and spacing less than 1 μm from each other to enable contact or direct-bonding between pads and vias with diameters under 5 μm at very fine pitch. The nanowire bonding interconnects may be used with or without tinning, solders, or adhesives. A nanowire forming technique creates a nanoporous layer on conductive pads, creates nanowires within pores of the nanoporous layer, and removes at least part of the nanoporous layer to reveal a layer of nanowires less than 1 μm in height for direct bonding.

A method of fabricating a gate with a mini field plate includes forming a dielectric passivation layer over an epitaxy layer on a substrate, coating the dielectric passivation layer with a first resist layer, etching the first resist layer and the dielectric passivation layer to form a first opening in the dielectric passivation layer, removing the first resist layer; and forming a tri-layer gate having a gate foot in the first opening, the gate foot having a first width, a gate neck extending from the gate foot and extending for a length over the dielectric passivation layer on both sides of the first opening, the gate neck having a second width wider than the first width of the gate foot, and a gate head extending from the gate neck, the gate head having a third width wider than the second width of the gate neck.

A method for manufacturing an array substrate includes: forming a pixel defining layer having a plurality of accommodating wells over a substrate, and forming a hydrophobic material layer over the pixel defining layer. A side wall of each accommodating well comprises a hydrophilic side surface. The hydrophilic side surface is partially covered by the hydrophobic material layer to thereby form an overlapped region having a hydrophobic outer surface and an exposed region having a hydrophilic outer surface. The overlapped region is on a side of the exposed region distal to the substrate. The array substrate manufactured thereby allows an organic functional layer to be evenly fabricated in each accommodating well of the pixel defining layer via inkjet printing.

Disclosed herein are transistors including two-dimensional materials, as well as related methods and devices. In some embodiments, a transistor may include a first two-dimensional channel material and a second two-dimensional source/drain (S/D) material in a source/drain (S/D), and the first two-dimensional material and the second two-dimensional material may have different compositions or thicknesses. In some embodiments, a transistor may include a first two-dimensional material in a channel and a second two-dimensional material in a source/drain (S/D), wherein the first two-dimensional material is a single-crystal material, and the second two-dimensional material is a single-crystal material.

A method of fabricating a gate with a mini field plate includes forming a dielectric passivation layer over an epitaxy layer on a substrate, coating the dielectric passivation layer with a first resist layer, etching the first resist layer and the dielectric passivation layer to form a first opening in the dielectric passivation layer, removing the first resist layer, and forming a tri-layer gate having a gate foot in the first opening, a gate neck extending from the gate foot, and a gate head extending from the gate neck. The gate foot has a first width, and the gate neck has a second width that is wider than the first width. The gate neck extends for a length over the dielectric passivation layer on both sides of the first opening. The gate head has a third width wider than the second width of the gate neck.

A semiconductor structure and a formation method thereof are provided. The semiconductor structure includes: a semiconductor substrate having a source region or drain region therein. The source region or drain region has a groove. The semiconductor structure can include a metal silicide layer arranged on a surface of a sidewall of the groove and an insulating layer arranged on a bottom surface of the groove. The edge of the insulating layer is in contact with a bottom surface of the metal silicide layer on the sidewall of the groove; and a conducting layer filled in the groove and arranged on the metal silicide layer and the insulating layer. The semiconductor structure of the present disclosure can prevent electric current from leaking into the semiconductor substrate at the bottom of the source/drain region.

Disclosed are a semiconductor device and a manufacturing method thereof. The method includes: providing a semiconductor substrate; forming a first wordline trench structure; forming a first sacrificial layer at the bottom of the first wordline trench structure; filling the first wordline trench structure located in active regions by epitaxial growth; forming a first insulation layer covering the top of the semiconductor substrate and the first wordline trench structure; forming a second wordline trench structure and a fin-type structure in the active regions, a depth of the second wordline trench structure being less than that of the first wordline trench structure, and a projection of the second wordline trench structure in a vertical direction completely overlapping with a projection of the first sacrificial layer in the vertical direction; removing the first sacrificial layer; and filling the first wordline trench structure, the second wordline trench structure and the wordline tunnel.

A method for manufacturing an array substrate includes: forming a pixel defining layer having a plurality of accommodating wells over a substrate, and forming a hydrophobic material layer over the pixel defining layer. A side wall of each accommodating well comprises a hydrophilic side surface. The hydrophilic side surface is partially covered by the hydrophobic material layer to thereby form an overlapped region having a hydrophobic outer surface and an exposed region having a hydrophilic outer surface. The overlapped region is on a side of the exposed region distal to the substrate. The array substrate manufactured thereby allows an organic functional layer to be evenly fabricated in each accommodating well of the pixel defining layer via inkjet printing.