Abstract: Disclosed herein are embodiments of a method to form quantum dot field-effect transistors (QD FETs) having little to no bias-stress effect. Bias-stress effect can be reduced or eliminated through, as an example, the use of a gas or liquid to remove ligands and/or reduce charge trapping on the QD FETs, followed by deposition of an inorganic or organic matrix around the QDs in the FET.

Abstract: Disclosed are hydroxyl radial generating devices, comprising: a substrate layer; and a pyrite layer configured to produce hydroxyl radicals. Another aspect relates to a method for producing a hydroxyl radical generating device, comprising: providing a polymeric substrate layer; placing a layer of pyrite on a surface of the polymeric substrate layer to form a multi-layer structure; and applying heat to the multi-layer structure such that at least the surface of the polymeric substrate layer contracts; wherein the layer of pyrite contracts to a lesser extent than the surface of the polymeric substrate layer providing a textured surface comprising the pyrite layer. Also disclosed is a method of analysis, comprising: placing a solution comprising a biological substance on a sample site of a hydroxyl generating device comprising a surface of pyrite; incubating the solution; and analyzing a sample including proteolytic fragments of the biological substance.

Abstract: A method of increasing the band gap of iron pyrite by alloying with oxygen is disclosed. According to one embodiment, a method comprises alloying iron pyrite (FeS2) with oxygen to form an iron pyrite and oxygen alloy (FeS2?xOx). The iron pyrite and oxygen alloy (FeS2?xOx) has a band gap greater than iron pyrite (FeS2).

Abstract: Disclosed are hydroxyl radial generating devices, comprising: a substrate layer; and a pyrite layer configured to produce hydroxyl radicals. Another aspect relates to a method for producing a hydroxyl radical generating device, comprising: providing a polymeric substrate layer; placing a layer of pyrite on a surface of the polymeric substrate layer to form a multi-layer structure; and applying heat to the multi-layer structure such that at least the surface of the polymeric substrate layer contracts; wherein the layer of pyrite contracts to a lesser extent than the surface of the polymeric substrate layer providing a textured surface comprising the pyrite layer. Also disclosed is a method of analysis, comprising: placing a solution comprising a biological substance on a sample site of a hydroxyl generating device comprising a surface of pyrite; incubating the solution; and analyzing a sample including proteolytic fragments of the biological substance.

Abstract: Disclosed herein are embodiments of a method to form quantum dot field-effect transistors (QD FETs) having little to no bias-stress effect. Bias-stress effect can be reduced or eliminated through, as an example, the use of a gas or liquid to remove ligands and/or reduce charge trapping on the QD FETs, followed by deposition of an inorganic or organic matrix around the QDs in the FET.

Abstract: A method of increasing the band gap of iron pyrite by alloying with oxygen is disclosed. According to one embodiment, a method comprises alloying iron pyrite (FeS2) with oxygen to form an iron pyrite and oxygen alloy (FeS2?xOx). The iron pyrite and oxygen alloy (FeS2?xOx) has a band gap greater than iron pyrite (FeS2).

Abstract: Nanoribbons and nanowires having diameters less than the wavelength of light are used in the formation and operation of optical circuits and devices. Such nanostructures function as subwavelength optical waveguides which form a fundamental building block for optical integration. The extraordinary length, flexibility and strength of these structures enable their manipulation on surfaces, including the precise positioning and optical linking of nanoribbon/wire waveguides and other nanoribbon/wire elements to form optical networks and devices. In addition, such structures provide for waveguiding in liquids, enabling them to further be used in other applications such as optical probes and sensors.

Abstract: Systems and methods are provided for the fabrication and manufacture of efficient, low-cost p-n heterojunction pyrite solar cells. The p-n heterojunction pyrite solar cells can include a pyrite thin cell component, a window layer component, and a top surface contact component. The pyrite thin cell component can be fabricated from nanocrystal paint deposited onto metal foils or microcrystalline pyrite deposited onto foil by chemical vapor deposition. A method of synthesizing colloidal pyrite nanocrystals is provided. Methods of manufacturing the efficient, low-cost p-n heterojunction pyrite solar cells are also provided.

Abstract: Nanoribbons and nanowires having diameters less than the wavelength of light are used in the formation and operation of optical circuits and devices. Such nanostructures function as subwavelength optical waveguides which form a fundamental building block for optical integration. The extraordinary length, flexibility and strength of these structures enable their manipulation on surfaces, including the precise positioning and optical linking of nanoribbon/wire waveguides and other nanoribbon/wire elements to form optical networks and devices. In addition, such structures provide for waveguiding in liquids, enabling them to further be used in other applications such as optical probes and sensors.