A radiation-assisted (typically solar-assisted) electrolyzer cell and panel for high-efficiency hydrogen production comprises a photoelectrode and electrode pair, with said photoelectrode comprising either a photoanode electrically coupled to a cathode shared with an anode, or a photocathode electrically coupled to an anode shared with a cathode; electrolyte; gas separators; all within a container divided into two chambers by said shared cathode or shared anode, and at least a portion of which is transparent to the electromagnetic radiation required by said photoanode (or photocathode) to apply photovoltage to a shared cathode (or anode) that increases the electrolysis current and hydrogen production.

An electrolytic cell built in the form of a capacitor of cylindrical plates. The cylindrical plates include electrodes of the electrolytic cell formed using tubes arranged in a substantially concentric way within each other defining a central electrode, an outer electrode and a space between electrodes. The central electrode corresponds to an anode of the capacitor. The outer electrode corresponds to the cathode of the capacitor. The cell includes an electrolyte corresponding to a dielectric of the capacitor.

An electrolytic cell built in the form of a capacitor of cylindrical plates. The cylindrical plates include electrodes of the electrolytic cell formed using tubes arranged in a substantially concentric way within each other defining a central electrode, an outer electrode and a space between electrodes. The central electrode corresponds to an anode of the capacitor. The outer electrode corresponds to the cathode of the capacitor. The cell includes an electrolyte corresponding to a dielectric of the capacitor.

A system preferably including a carbon dioxide reactor. A method for carbon dioxide reactor control, preferably including selecting carbon dioxide reactor aspects based on a desired output composition, running a carbon dioxide reactor under controlled process conditions to produce a desired output composition, and/or altering the process conditions to alter the output composition.

A system preferably including a carbon dioxide reactor. A method for carbon dioxide reactor control, preferably including selecting carbon dioxide reactor aspects based on a desired output composition, running a carbon dioxide reactor under controlled process conditions to produce a desired output composition, and/or altering the process conditions to alter the output composition.

A wind turbine includes a generator, a base, a nacelle, a tower having a first end mounted to the base and a second end supporting the nacelle, and an electrolytic unit electrically powered by the generator to produce hydrogen from an input fluid, in particular water, wherein the electrolytic unit is electrically coupled to the generator by an electric connection, wherein the electrolytic unit is housed in a housing, wherein the housing includes a pressure-relief section configured to detach from the housing in the event of an explosion inside the housing or when the pressure inside the housing exceeds a predetermined pressure.

A single fuel cell according to the present disclosure includes a power generation section, a power non-generation section which does not include the power generation section, and an oxygen-ion-insulating gas seal film arranged so as to cover the surface of the power non-generation section, and the gas seal film is configured by a structure formed by firing a material containing MTiO.sub.3 (M: alkaline earth metal element) and metal oxide. The structure may include a first structure and a second structure which are different in composition, the first structure may include components derived from MTiO.sub.3 in larger amounts than the second structure, the second structure may include a metal element contained in the metal oxide in a larger amount than the first structure, and the area ratio of the second structure in the structure may be not less than 1% and not more than 50%.

An electrode including a metal coil and a metal wire is provided. The metal coil includes a metal selected from copper, silver, gold, nickel and aluminium. The turns of the metal coil are separated by a gap. At least part of the metal wire is arranged inside the metal coil. The metal wire and the metal coil are in electrical contact. The metal wire includes a metal selected from copper, silver, gold, nickel and aluminum. The metal wire and the metal coil are made of a same metal. The metal coil has a plurality of turns forming an elongated coil body with a central channel along a central axis of the metal coil. The metal wire extends longitudinally inside the central channel from one end of the metal coil to an other end of the metal coil along the central axis of the metal coil.

An electrode including a metal coil and a metal wire is provided. The metal coil includes a metal selected from copper, silver, gold, nickel and aluminium. The turns of the metal coil are separated by a gap. At least part of the metal wire is arranged inside the metal coil. The metal wire and the metal coil are in electrical contact. The metal wire includes a metal selected from copper, silver, gold, nickel and aluminum. The metal wire and the metal coil are made of a same metal. The metal coil has a plurality of turns forming an elongated coil body with a central channel along a central axis of the metal coil. The metal wire extends longitudinally inside the central channel from one end of the metal coil to an other end of the metal coil along the central axis of the metal coil.

Enzymatic polynucleotide synthesis with a template-independent polymerase is used to create multiple polynucleotides having different, arbitrary sequences on the surface of an array. The array provides a spatially-addressable substrate for solid-phase synthesis. Blocking groups are attached to the 3′ ends of polynucleotides on the array. Prior to polynucleotide extension, the blocking groups are removed at a selected location on the array. In an implementation, the blocking groups are acyl groups removed with a negative voltage created at an electrode. The array is then incubated with the polymerase and a single species of nucleotide. Nucleotides are incorporated onto the 3′ ends of the polynucleotides without blocking groups. Washing removes the polymerase and free nucleotides. To create polynucleotides with different sequences at different locations on the array, the location where the blocking groups are removed and the species of nucleotide may be changed during repeated cycles of synthesis.