This disclosure provides a composition of matter nucleated from a homogenous nucleation to form a self-assembled binder-less mesoporous carbon-based particle. In some implementations, the composition includes: a plurality of electrically conductive 3D aggregates formed of graphene sheets and sintered together to define a 3D hierarchical open porous structure comprising mesoscale structuring with micron-scale fractal structuring and configured to provide an electrical conduction between contact points of the graphene sheets. A porous arrangement is formed in the 3D hierarchical open porous structure and is arranged to contain a liquid electrolyte configured to provide ion transport through a plurality of interconnected porous channels in the 3D hierarchical open porous structure. A respective porous channel of the plurality of porous channels includes: a first portion configured to provide tunable ion conduits; a second portion configured to facilitate rapid ion transport; and, a third portion configured to at least partially confine active material.

Aspects of the present disclosure involve a plasma system for practicing various methods of synthesizing solid-state electrolyte materials and precursors for solid-state electrolyte materials.

Bacteriophage is covalently attached to a substrate by (a) combining (i) substrate with (ii) bacteriophage, wherein prior to or during the combining (i) or (ii) or both (i) and (ii) are activated, and wherein (b) during the combining the bacteriophage is contained within a liquid droplet of average diameter 150 microns or less.

A reactor system and a method for the production and/or treatment of particles in an oscillating process gas stream. The reactor system includes a reaction unit and a pulsation device. A pulsation that has a pulsation frequency and a pulsation pressure amplitude can be imposed on the process gas by means of the pulsation device. The pulsation device can adapt a pulation frequency and/or pulsation pressure amplitude of the pulsation to one of the inherent resonance frequencies of a resonator.

The invention relates to a pressure loss production device (1) having a process gas inflow (2) that has a process gas inflow inlet (5), a process gas inflow outlet (6), a process gas inflow longitudinal center axis (A-A), and a process gas inflow cross-sectional surface (7), having a process gas distributor (3) that has a process gas distributor longitudinal center axis (B-B), a process gas distributor cross-sectional surface (8), a process gas distributor inlet (10) arranged on a first end face (9) and a process gas distributor outlet (12) arranged on a second end face (11), and having a process gas outflow (4) that comprises a process gas outflow inlet (13), a process gas outflow outlet (14), a process gas outflow longitudinal center axis (C-C), and a process gas outflow cross-sectional surface (15), wherein the process gas inflow (2) is connected with the first end face (9) of the process gas distributor (3), and the second end face (11) of the process gas distributor (3) is connected with the process gas outflow (4), in such a manner that a continuous flow path (16) is formed, wherein the process gas inflow (2) and process gas outflow (4) are arranged, relative to one another, in such a manner that the process gas inflow longitudinal center axis (A-A) and the process gas outflow longitudinal center axis (C-C) are arranged offset from one another, and to its use in a reactor system (31).

The present disclosure provides a supercritical fluid gasification system. In some embodiments, the system includes a reactor having a reactor shell including sidewalls that extend between a top reactor cover and a bottom reactor cover, where the sidewalls, the top cover, and the bottom cover enclosing a reactor shell channel. In some embodiments, the reactor includes a thermal shield positioned within the reactor shell channel, the thermal shield having sidewalls that extend between a top thermal shield cover and a bottom thermal shield cover, where the sidewalls, the top thermal shield cover, and the bottom thermal shield cover enclosing a thermal shield channel. In some embodiments, the reactor includes a fluid feed supply conduit in fluid communication with the thermal shield channel, a supercritical fluid conduit in fluid communication with the thermal shield channel, and a product conduit in fluid communication with the thermal shield channel.

Presently disclosed is a multi-layered carbon-based scaffolded structure having a conductive substrate. A first film is deposited on the conductive substrate and includes: a first concentration of three-dimensional (3D) carbon-based particles comprising: a plurality of conductive 3D aggregates formed of graphene sheets that are sintered together to define a 3D hierarchical open porous structure with mesoscale structuring in combination with micron-scale fractal structuring that is also configured to provide conduction between contact points of the graphene sheets. A porous arrangement is formed in the 3D hierarchical open porous structure and contains a liquid electrolyte configured to provide ion transport through a plurality of interconnected porous channels. The first film is configured to provide a first conductivity. A second film is deposited on the first film and comprising a second concentration of 3D carbon-based particles. The second film configured to provide a second conductivity lower than the first conductivity.

The present invention relates to methods and devices for providing microbial control and/or disinfection/remediation of an environment. The methods generally comprise: generating a Purified Hydrogen Peroxide Gas (PHPG) that is substantially free of, e.g., hydration, ozone, plasma species, and/or organic species; and directing the gas comprising primarily PHPG into the environment such that the PHPG acts to provide microbial control and/or disinfection/remediation in the environment, preferably both on surfaces and in the air.

The invention relates to a method for producing syngas by means of solar radiation, in which the reactor of a receiver-reactor is periodically heated via an aperture provided in the same for solar radiation by means of the solar radiation to an upper reduction temperature for a reduction process and subsequently cooled to a lower oxidation temperature for an oxidation process in the presence of an oxidation gas, wherein the sunlight is guided through an absorption chamber onto an absorber configured as a reactor, which includes a reducible/oxidizable material, and wherein a gas that absorbs the black-body radiation of the absorber is guided through the absorption chamber and the absorption chamber is configured so that the back radiation of the absorber through the aperture is essentially absorbed by the gas. Radiation losses caused by back radiation of the black-body radiation exiting the optical aperture are thus avoided in accordance with the invention. The heat of the back radiation, however, can be utilized directly in the heat-transporting fluid and is available for a flexible usage. The receiver-reactor has a simple design and is suitable as a low-cost receiver-reactor.

The present invention relates to methods and devices for providing microbial control and/or disinfection/remediation of an environment. The methods generally comprise: generating a Purified Hydrogen Peroxide Gas (PHPG) that is substantially free of, e.g., hydration, ozone, plasma species, and/or organic species; and directing the gas comprising primarily PHPG into the environment such that the PHPG acts to provide microbial control and/or disinfection/remediation in the environment, preferably both on surfaces and in the air.