Abstract: A sampling plate (1) is provided comprising a sample zone (2) for receiving a liquid sample, and two drive electrodes (3, 4) with separate respective electrode terminals spaced by a spacing for receiving a the liquid sample within the sample zone for use in driving an electrical signal through the sample. Two sensing electrodes (5, 6) are provided with separate respective electrode terminals spaced between the electrode terminals of the two drive electrodes for use in sensing an electrical signal generated by the drive electrodes within a the sample. A sampling apparatus (15) is provided for use with the plate.

Abstract: An illustrative aqueous ozone delivery device for use with an aqueous ozone generator cartridge can be used for body part, tissue, and instrument sanitizing, including hand rinsing, hand sanitizing, and clinical treatment. One embodiment includes a hooded sanitizing chamber and spray devices directed to each hand of a user, a docketing station for pluggably receiving a replaceable ozone generator and sensor cartridge, and a controller for sensing hand position and orientation, delivering a desired ozone concentration and duration.

Abstract: An ozone generation system which is adaptable for supplying ozone to different medium and small application processes. The system has a source of feed gas, a corona discharge cell receiving the feed gas from the feed gas source and generating ozone for the application process, a flow controller measuring and managing the flow of the feed gas from the feed gas source to the corona discharge cell; and a regulator receiving gas from the corona discharge cell and sending the gas to the application process. The regulator maintains pressure in the corona discharge cell independent of the application process pressure.

Abstract: A solid state combinatorial synthesis of particulate diamond ranging in size from the macroscopic down to the nanoscale, which entails: a) forming a solution having a source of reactant atoms, a tetrahedranoidal compound reactant, and a solvent vehicle; b) forming liquid droplets of the solution; c) evaporating the solvent vehicle from the liquid droplets of the solution to form particles containing a homogenous solid mixture of the reactants; and d) exposing the particles of the homogeneous solid mixture to a high energy discharge thereby forming diamond particles.

Abstract: A flow reactor has a fluidic module with a first major outer surface. The module contains a fluid passage and has a transmittance through the first major outer surface to the fluid passage of at least 20% over a range of wavelengths. The reactor has an illumination module comprising one or more radiation sources, which can emit within the range, positioned within an enclosure. The enclosure has a back wall and a side wall and an opening opposite the back wall. An edge of the side wall surrounds the opening. The illumination module is positioned such that the opening of the illumination module faces the first major outer surface of the fluidic module. The side wall comprises a telescoping portion such that a distance from the back wall of the enclosure to the edge of the side wall is adjustable.

Abstract: An apparatus for exposing a bulk volume of particles, such as free-flowing or semi-flowable grains, ore, or powders, or a non-flowing mass such as sewage or wet-chopped bio-mass so all of the particles receive near-uniform exposure to a radio frequency (RF) electric and/or magnet (EM) field, preferably without any preference of exposure to a surface or side of particulate. The invention relates to an antenna that can be metallic or plasma for transmitting RF EM radiation into a mechanical mechanism used to convey, or preferably to mix a bulk volume of particles. Embodiments of the apparatus include the ability to adjust the level of EM radiation comprised of one or more frequencies between 30 Hz and 30 EHz to regulate either or both the magnitude of temperature rise and the rate of temperature rise, or to regulate either or both the magnitude of chemical reaction, or rate of reaction.

Abstract: Ozone generating machine for generating ozone in a ship, including: an ozone generator (OG), a liquid cooling circuit portion, a frame, comprising a base (B) for laying on the ground, a top subframe (TSF) supporting the ozone generator (OG), and at least one pair of pillars (P) arranged between the base (B) and the top subframe (TSF), characterized in that the frame comprises: at least one pair of cross-brace beams (CB), for linking the pillars (P) and a plurality of dampers (D) attached to a bottom of the base (8).

Abstract: Systems and methods for plasma based synthesis of graphitic materials. The system includes a plasma forming zone configured to generate a plasma from radio-frequency radiation, an interface element configured to transmit the plasma from the plasma forming zone to a reaction zone, and the reaction zone configured to receive the plasma. The reaction zone is further configured to receive feedstock material comprising a carbon containing species, and convert the feedstock material to a product comprising the graphitic materials in presence of the plasma.

Abstract: A system and method for the electromagnetic energization of packed content, in which the system includes at least one container filled with at least one fluid, at least one energization element, at least one grounding element, at least one containment element, one or more alignment elements, one or more contact elements, at least one grounding connection element, at least one grounding element, and optionally at least one movement element. Additionally, a corresponding apparatus is provided.

Abstract: An apparatus for preparing graphene by means of laser irradiation in liquid, comprising a laser generating system, and further comprising a computer control system, a cleaning and drying system, and a workpiece auxiliary system. The light spot diameter of the laser emitted from a pulse laser unit (26) is increased by means of a beam expander (24), and the laser is reflected and split by a beam splitter to form two laser beams; a first laser beam (19) shocks the right vertical plane of a graphite solid target (18) by means of a focusing lens, and a second laser beam (17) shocks the left vertical plane of the graphite solid target (18) by means of the focusing lens, so as to grow graphene on a copper foil (5) substrate.

Abstract: This disclosure provides systems, methods, and apparatus related to boron nitride nanomaterials. In one aspect, a method includes generating a directed flow of plasma. A boron-containing species is introduced to the directed flow of the plasma. Boron nitride nanostructures are formed in a chamber. In another aspect, a method includes generating a directed flow of plasma using nitrogen gas. A boron-containing species is introduced to the directed flow of the plasma. The boron-containing species can consist of boron powder, boron nitride powder, and/or boron oxide powder. Boron nitride nanostructures are formed in a chamber, with a pressure in the chamber being about 3 atmospheres or greater.

Abstract: An ozone generating device including an excimer lamp having an arc tube containing a luminescent gas, a first electrode, and a second electrode. The arc tube has a first end portion and a second end portion, a first diameter-reduced portion provided continuously from the first end portion, a diameter of which decreases as a distance from the first end portion increases, and a second diameter-reduced portion provided continuously from the second end portion, a diameter of which decreases as a distance from the second end portion increases, the first electrode is provided for an outer periphery surface of the first end portion, the second electrode is provided for an outer periphery surface of the second end portion, the arc tube is fixed via the cylindrical portion, and the first electrode is not provided over the first diameter-reduced portion, and/or the second electrode is not provided over the second diameter-reduced portion.

Abstract: A gas processing device includes: a casing that includes a first end having a first opening region constituting an intake port, a second end having a second opening region constituting an exhaust port, and a main body portion on the inside of which is formed a hollow portion; a discharge lamp that has a tube body which is disposed in the hollow portion and which has a shape extending in the first direction, a first electrode, and a second electrode, the discharge lamp that emits ultraviolet rays from the tube body; a power supply unit arranged outside the casing; and a first power supply line and a second power supply line that are wired so as to pass through a side closer to the first end than the main body portion, and that electrically connect the power supply unit to the first electrode and the second electrode.

Abstract: Surface modification device forms a discharge area E1 between a discharge electrode 6 and a counter electrode 4, supplies substitution gas to the discharge area E1, and modifies the surface of the base material to be processed. The surface modification device comprises; a slit-shaped substitution gas passage; and cover members 7, 8 that form curtain passages 22, 23 in spaces facing the discharge electrode. While the substitution gas is being supplied to the discharge area E1, gas injected from the curtain passages 22, 23 prevent the inflow of an entrained flow a and the outflows b1, b2 of the substitution gas, thereby maintaining the concentration of substitution gas inside the discharge area E1.

Abstract: A shaft member has the same polarity as discharge electrodes. Each of the discharge electrodes has an electrode body and a tip end which is formed at an end of the electrode body facing an inner peripheral surface of a counter electrode. The discharge electrodes extend such that the tip ends and the electrode bodies are misaligned with each other in an axial direction of the shaft body. A streamer discharge travels from the tip ends of the discharge electrodes toward the inner peripheral surface of the counter electrode.

Abstract: Described is a system and corresponding method for remediating liquid waste streams. The system includes an electro-oxidation (EO) chamber, an electro-deposition (ED) chamber, and an electro-adsorption (EA) chamber. In the method, a waste stream is subjected to electro-oxidation, followed by electro-deposition and/or electro-adsorption. The method removes both organic and inorganic pollutants, as well as metals present as free ions or bound into organic or inorganic complexes.

Abstract: Electrochemically aligned and compacted molecules, nanoparticles and microparticles with ampholytic nature, such as collagen, elastin, keratin and charged nanoparticle materials, methods of making and using the materials and associated production-related devices. In one embodiment, a device for producing continuous electrochemically aligned strands, threads or fibers is disclosed. In a further embodiment, fabrication of compositionally and geometrically complex anatomical forms by 3D-electrochemical compaction of biomolecules is disclosed. In yet another embodiment, methods for fabricating patterned lattice structures, in particular having controlled pore size and morphology, and the lattice structures themselves are also disclosed.

Abstract: An ozone generation device includes an inverter, an ozone generator, and a reactor. The inverter turns on and off a switching element by pulse width modulation (PWM) control to convert DC power into AC power. In the ozone generator, voltage of the AC power is applied to a dielectric electrode, and discharge is generated in raw material gas flowing in a discharge gap between the dielectric electrode and a metal electrode, so that ozone is generated by the discharge. The reactor is connected in series to a dielectric electrode, and reduces an inrush current that flows through the dielectric electrode when the switching element is switched from off to on by the PWM control by the inverter.

Abstract: Design advances for improving the performance of a plasma torch. The use of one or more of various advances described herein can improve the efficiency and effectiveness of the torch, the reactor and the manufacturing process. The use of the torch with hydrogen plasma gas, natural gas feedstock, and carbon black production are also described.

Abstract: Method for producing single wall carbon nanotubes, including obtaining a vapor containing nanoparticles of a catalytic substance in an evaporation chamber; obtaining a working mixture in a mixing node at 650-1,400° C. by delivering the vapor to the mixing node from the evaporation chamber in a carrier gas flow, and introducing gaseous hydrocarbons into the mixing node so that the working mixture includes the carrier gas, hydrocarbons, and the nanoparticles, with the nanoparticles having an average size of 1-10 nm, and single wall carbon nanotubes forming on the nanoparticles; feeding the working mixture at 650-1,400° C. to the reaction chamber, the reaction chamber having a distance of at least 0.5 m between its opposite walls; discharging the single wall carbon nanotubes from the reaction chamber in a stream of gaseous products of hydrocarbon decomposition; filtering the single wall carbon nanotubes from the gaseous products of hydrocarbon decomposition.