The present invention relates to a phosphor monomolecular compound, an organic transistor using same, and a water splitting and hydrogen production photocatalytic system using same. More specifically, the present invention comprises a water-soluble monomolecular compound including 1,5-naphtyridine-2,6-dione structure as a phosphor monomolecular compound.

Disclosed herein are perovskite materials and methods of making an use thereof.

A composition having: titania aerogel having titania nanoparticles and copper nanoparticles. Each of the copper nanoparticles is in contact with more than one of the titania nanoparticles. A method of: providing a titania aerogel, and forming or depositing copper nanoparticles onto the surface of the titania aerogel.

An apparatus contains at least one pressure-rated apparatus shell and at least one modular framework system containing ceramic fiber composite materials and arranged within the apparatus shell. A modular lining apparatus includes the modular framework system and. refractory bricks. The apparatus can be used for high-temperature reactors, especially electrically heated high-temperature reactors.

Plasmonically-enhanced catalytic surfaces and accompanying optics are described herein. These elements facilitate efficient coupling of light energy into a photocatalytic system by way of a surface plasmon. Various compatible optical configurations are presented, with an emphasis on the broadband coupling of light into a single plasmon mode. In an example embodiment, dispersive optics are used to direct polychromatic light onto a grating-embossed SPR-active surface. Dispersive optics allow resonance to be achieved at a wide range of incident wavelengths. Energy then transfers from the excited plasmon to an adjacent photocatalyst. The plasmon mode thus acts as a “funnel” of broadband light energy to the catalytic materials. High-efficiency incoupling and outcoupling from the plasmon mode suggest overall enhancement of catalytic activity, and broad applicability is anticipated due to the inherent flexibility of the system. The catalytic surfaces and optical components can be fabricated as sheets or 3D arrays, justifying industrial-scale manufacturing.

Compositions of flame retardants and methods of enhancing char formation in a flame retardant-treated substrate. A base material is combined with a flame retardant to form the flame retardant-treated substrate. The flame retardant contains a sulfur copolymer prepared by the polymerization of sulfur monomers with organic monomers. The flame retardant can be deposited on a surface of the base material, coated on the base material, or mixed into the base material. When the flame resistant substrate is on fire, the flame retardant forms a charring layer on the flame retardant-treated substrate. The charring layer can extinguish and prevent the fire from spreading.

A method of operating an internal combustion engine having at least one combustion chamber and an actuator disposed therein being arranged to drive an output shaft of the engine, the method comprising: 5 (i) injecting a water containing fuel into the combustion chamber; (ii) flash boiling the water-containing fuel to form water vapour within the combustion chamber; (iii) thermolyzing the water vapour to form hydrogen gas and oxygen gas; and (iv) combusting the hydrogen gas to drive the actuator within the combustion chamber to 10 thereby drive the connected output shaft of the combustion engine.

Provided in this disclosure is an electrolysis system using voltage in a purely physical process, without resorting to passing current through an electrolyte in a chemical process. The present invention includes a tri-coil design resonant cavity transformer that utilizes the dielectric properties of a material acting as part of a “closed loop” electrical (Resistor, Inductor, Capacitor) RLC circuit. The tri-coil transformer (or TCT) is tuned to the dielectric properties of a suitable material, which can be water, liquid metals, or even ambient air. The TCT can be a tri-coil resonating cavity transformer employing either a Maxwell or Helmholtz tri-coil design. The present invention entails a physical approach to electrolysis based on voltage and not amperage to dissociate a selected dielectric medium, an approach that is 180 degrees out of phase from traditional Faraday electrolysis.

The present invention relates to a photocatalyst composition having visible light activity for hydrogen production through water splitting. More particularly, the present invention discloses a photocatalyst composition comprising a zinc oxide nanoparticles and a conjugated organic moiety selected from the group consisting of oligothiophenes, azo dyes, and perylenes.

The invention relates to a porous monolith comprising between 20 wt.-% and 70 wt.-% Ti0 2 relative to the total weight of the monolith, and between 30 wt.-% and 80 wt.-% a refractory oxide, selected from silica, alumina or silica-alumina, relative to the total weight of the monolith, characterized in that said porous monolith has a bulk density of less than 0.19 g/mL.