Described are electrochemical systems and methods for the generation of high purity hydride gases, e.g. for delivery to semiconductor fabrication reactors.

An electrochemical reactor comprising an electrolyte compartment wherein at least one of the side walls of the electrolyte compartment is an electrode and an opposite side wall comprises a separator element. Further there is a plurality of electrically conductive granules forming a working electrode for a electrochemical main reaction in the electrolyte compartment and enclosed in the electrolyte compartment. The granules comprise a first material exhibiting at least a first activation overpotential for an electrochemical side reaction within a distance d from the separator element. The electrochemical reactor comprises a spacer element for maintaining the granules at least at a distance d from the separator element on the electrolyte-facing side of the separator element. The spacer element is electrically conductive and comprises a second material exhibiting a second activation overpotential for the electrochemical side reaction within a distance d from the separator element and is larger than the first activation overpotential.

An electrochemical reactor comprising an electrolyte compartment wherein at least one of the side walls of the electrolyte compartment is an electrode and an opposite side wall comprises a separator element. Further there is a plurality of electrically conductive granules forming a working electrode for a electrochemical main reaction in the electrolyte compartment and enclosed in the electrolyte compartment. The granules comprise a first material exhibiting at least a first activation overpotential for an electrochemical side reaction within a distance d from the separator element. The electrochemical reactor comprises a spacer element for maintaining the granules at least at a distance d from the separator element on the electrolyte-facing side of the separator element. The spacer element is electrically conductive and comprises a second material exhibiting a second activation overpotential for the electrochemical side reaction within a distance d from the separator element and is larger than the first activation overpotential.

The present invention relates to a photo-electrochemical device for production of a gas, liquid or solid using concentrated electromagnetic irradiation. The device comprises a photovoltaic component configured to generate charge carriers from the concentrated electromagnetic irradiation; and an electrochemical component configured to carry out electrolysis of a reactant. The photovoltaic component contacts the electrochemical component at a solid interface to form an integrated photo-electrochemical device; and further includes at least one reactant channel or a plurality of reactant channels extending between the photovoltaic component and the electrochemical component to transfer heat and the reactant from the photovoltaic component to the electrochemical component. The integrated photo-electrochemical device and auxiliary devices (such as concentrator, flow controllers) build a system which can flexibly react to changes in operating condition and guarantee best performance.

The invention relates to an electrolysis device and method for producing molecular hydrogen, the device comprising a negative electrode compartment for reducing H2O into H2 and a positive electrode compartment comprising circulating supercapacitive particles in contact with a conductive substrate. Such a device or method advantageously comprises a power supply provided by one or more photovoltaic cells.

Provided is a system for continuous generation of gases, the system including an electrochemical device and an active- material regeneration device.

Provided is a system for continuous generation of gases, the system including an electrochemical device and an active- material regeneration device.

The invention is directed to a process to convert carbon dioxide to methane by contacting an aqueous solution comprising dissolved carbon dioxide with an electron charged packed bed comprising of a carrier, suitably activated carbon granules, and a biofilm of microorganisms under anaerobic conditions, wherein more than 90 mol % of the dissolved carbon dioxide in the aqueous solution is present as a bicarbonate ion and/or as a carbonate ion.

An electrolytic dye reduction method comprises preparing a catholyte by dispersing a dye in a leucodye comprising electrolyte. In a preferred method the leucodye like leucoindigo is the sole dispersing aid.

An electrolytic dye reduction method comprises preparing a catholyte by dispersing a dye in a leucodye comprising electrolyte. In a preferred method the leucodye like leucoindigo is the sole dispersing aid.