Abstract: The present disclosure relates to structures and methods of quantum devices. A quantum device comprises a substrate with an insulation surface and at least one quantum component disposed on the insulation surface of the substrate. The at least one quantum component may comprise multiple plateau members and at least one quantum dot. Each plateau member is disposed at an angle against an adjacent plateau member. Each quantum dot is formed within an insulation body and disposed at an included-angle location of two adjacent plateau members of the multiple plateau members. In addition, the at least one quantum component is operable under high temperature, such as above 4 K.

Abstract: The invention provides a self-organized quantum dot semiconductor structure. The quantum dot semiconductor structure includes: a conductive ridge on a substrate; an insulative layer covering the substrate and the conductive ridge, wherein the insulative layer includes a top portion and two sidewalls over the conductive ridge; a semiconductor mechanism of etching back and thermal oxidation, implemented on a semiconductor-alloyed layer set on the insulative layer; a plurality of quantum dots respectively embedded within a plurality of silicon dioxide spacer islands based on the semiconductor mechanism, the quantum dots and the silicon dioxide spacer islands adhered to the sidewalls of the insulative layer; and a plurality of conductive ledges adhered to the silicon dioxide spacer islands, wherein each of the conductive ledges is a portion of an electrode self-alignment to the quantum dot.

Abstract: The invention provides a quantum dot manufacturing method and related quantum dot semiconductor structure. The quantum dot semiconductor structure includes: a conductive ridge on a substrate; an insulative layer covering the substrate and the conductive ridge, wherein the insulative layer includes a top portion and two sidewalls over the conductive ridge; a plurality of quantum dots respectively embedded within a plurality of silicon dioxide spacer islands, which are adhered to the sidewalls of the insulative layer; and a plurality of conductive ledges adhered to the silicon dioxide spacer islands, wherein each of the conductive ledges is a portion of an electrode with alignment to the corresponding quantum dot.

Abstract: The invention provides a quantum dot manufacturing method and related quantum dot semiconductor structure. The quantum dot semiconductor structure includes: a conductive ridge on a substrate; an insulative layer covering the substrate and the conductive ridge, wherein the insulative layer includes a top portion and two sidewalls over the conductive ridge; a plurality of quantum dots respectively embedded within a plurality of silicon dioxide spacer islands, which are adhered to the sidewalls of the insulative layer; and a plurality of conductive ledges adhered to the silicon dioxide spacer islands, wherein each of the conductive ledges is a portion of an electrode with alignment to the corresponding quantum dot.

Abstract: A method for manufacturing a metal-oxide-semiconductor (MOS) gate stack structure in an insta-MOS field-effect-transistor (i-MOSFET) includes the following steps of: forming a silicon nitride layer over a silicon substrate; forming a nanopillar structure including a silicon-germanium alloy layer in contact with the silicon nitride layer; and performing a thermal oxidation process on the nanopillar structure to cause germanium atoms in the silicon-germanium alloy layer to penetrate the underneath silicon nitride layer to form a silicon-germanium shell layer in contact with the silicon substrate and a germanium nanosphere located over the silicon germanium shell layer, and to form a separating layer between the silicon-germanium shell layer and the germanium nanosphere by oxidizing silicon atoms from the silicon nitride layer or the silicon substrate, thereby forming a germanium/silicon dioxide/silicon-germanium i-MOS gate stack structure capable of solving interfacial issues between silicon and germanium and b

Abstract: A method for manufacturing a metal-oxide-semiconductor (MOS) gate stack structure in an insta-MOS field-effect-transistor (i-MOSFET) includes the following steps of: forming a silicon nitride layer over a silicon substrate; forming a nanopillar structure including a silicon-germanium alloy layer in contact with the silicon nitride layer; and performing a thermal oxidation process on the nanopillar structure to cause germanium atoms in the silicon-germanium alloy layer to penetrate the underneath silicon nitride layer to form a silicon-germanium shell layer in contact with the silicon substrate and a germanium nanosphere located over the silicon germanium shell layer, and to form a separating layer between the silicon-germanium shell layer and the germanium nanosphere by oxidizing silicon atoms from the silicon nitride layer or the silicon substrate, thereby forming a germanium/silicon dioxide/silicon-germanium i-MOS gate stack structure capable of solving interfacial issues between silicon and germanium and b

Abstract: A method for forming a thermoelectric film having a micro groove includes the following steps: A) forming a plurality of parallel sacrificing wires by electrospinning, a diameter of each sacrificing wire being 100-500 nm; B) coating a thermoelectric film having a thickness of 80-200 nm on a part of a surface of each sacrificing wire; and C) removing the sacrificing wires from the thermoelectric films and thus obtaining the thermoelectric films each having the micro groove, a radio side of each thermoelectric film being open to the surroundings. The thermoelectric films finally prepared can have higher size uniformity without the disadvantage of catalyst residual. Further, the thermoelectric films each have a size smaller than the mean free path of phonons in one dimension, and thus the thermoelectric properties of the thermoelectric films can be improved.

Abstract: The present invention discloses a method for simultaneously removing from a silicon surface polymeric films and damaged silicon layers by exposing the surface to a cleaning solution that contains amine or ethanolamine for a length of time that is sufficient to remove all such unwanted materials. The method is effective in cleaning away damaged silicon layers having a thickness between about 20 Å and about 60 Å in a period of time between about 2 minutes and about 20 minutes. In a preferred embodiment, the cleaning solution is a water solution of ethanolamine and gallic acid.

Abstract: The present invention is a method of manufacturing crown shape capacitors for use in DRAM semiconductor memory. The method includes the steps of forming a first polysilicon layer, patterning a photoresist on the first polysilicon layer, etching the first polysilicon layer, using oxygen plasma to strip the photoresist, forming a side wall polymer onto the side walls of the first polysilicon layer, using the side wall polymer as a mask to etch back the first polysilicon layer to form a crown shape structure, removing the side wall polymer, depositing a dielectric layer onto the first polysilicon layer, and depositing a second polysilicon layer onto the dielectric layer.

Abstract: A method for fabricating small contact openings in the polysilicon/metal 1 dielectric (PMD) layer on semiconductor substrates using polymer sidewall spacers was achieved. This extends the current photoresist resolution limits while simplifying the manufacturing process. The method involves depositing a polysilicon layer on the PMD layer and using a photoresist mask having openings over device contact areas in the substrate. The polysilicon layer is then patterned to form openings with vertical sidewalls to the PMD insulating layer. The contact openings are then anisotropically plasma etched in a gas mixture that simultaneously forms polymer sidewall spacers on the sidewalls in the openings in the polysilicon layer. These sidewall spacers further reduce the contact opening size. The remaining photoresist layer and polymer sidewall spacers are simultaneously removed to complete the narrow contact openings. This method eliminates the need to use an additional deposition and etch-back step to form the sidewalls.