Methods and systems for generation and deployment of a structurally altered gas molecules derived from water are provided. An example method includes combining purified water with a compound mixture. The compound mixture is non-reactive with the water and a conductor of an electric field and a magnetic field. The method includes applying the magnetic field and the electric field to the combination of the purified water and the compound mixture to cause generation of the structurally altered gas molecules. The structurally altered gas molecules have a higher probability of attraction of electrons into areas adjunct to the structurally altered gas molecules than molecules of the purified water. The method further includes introducing the structurally altered gas molecules into an environment of a chemical process. The structurally altered gas molecules facilitate electron transfers during the chemical process, thereby increasing output of the chemical process.

An efficient oxyhydrogen generation device for medical care has a housing, an upper cover and a bottom cover which form a main frame. The housing is composed of a front part and a rear part, the bottom cover being fastened at the bottom of the housing to form a space for accommodating an electrolytic cell, a water supply tank, a water supply tank upper cover and a secondary water tank. The upper cover is fastened on the upper part of the housing and is provided with an atomized gas circulation part, a supply part for supplying water to the water supply tank, and a control panel for controlling the operation of an electrolyzing water hydrogen-oxygen generator. The oxyhydrogen generated by electrolysis sequentially enters the water supply tank and the secondary water tank by means of a gas guide plate and is cleaned. discharged from a gas circulation part.

A method of producing hydrogen gas comprises introducing gaseous water to an electrolysis cell comprising a positive electrode, a negative electrode, and a proton-conducting membrane between the positive electrode and the negative electrode. The proton-conducting membrane comprises an electrolyte material having an ionic conductivity greater than or equal to about 10.sup.?2 S/cm at one or more temperatures within a range of from about 150? C. to about 650? C. The gaseous water is decomposed using the electrolysis cell. A hydrogen gas production system and an electrolysis cell are also described.

A method of producing hydrogen gas comprises introducing gaseous water to an electrolysis cell comprising a positive electrode, a negative electrode, and a proton-conducting membrane between the positive electrode and the negative electrode. The proton-conducting membrane comprises an electrolyte material having an ionic conductivity greater than or equal to about 10.sup.?2 S/cm at one or more temperatures within a range of from about 150? C. to about 650? C. The gaseous water is decomposed using the electrolysis cell. A hydrogen gas production system and an electrolysis cell are also described.

A multi-chamber assembly safely stores enhancement gas for efficient and complete combustion of a carbonaceous fuel is presented. The multi-chamber assembly safely stores the enhancement gas, for example, for use by the internal combustion engine such as an internal combustion engine of a vehicle and/or a generator.

A multi-chamber assembly safely stores enhancement gas for efficient and complete combustion of a carbonaceous fuel is presented. The multi-chamber assembly safely stores the enhancement gas, for example, for use by the internal combustion engine such as an internal combustion engine of a vehicle and/or a generator.

In some implementations, a method may include generating, by a solar power generator, DC power, wherein the solar power generator may have a flat-on-ground configuration. The method may include receiving, by one or more electrolyzers, the DC power. The method may include generating, by the one or more electrolyzers and via an electrolysis process, oxyhydrogen (HHO) using the DC power.

In some implementations, a method may include generating, by a solar power generator, DC power, wherein the solar power generator may have a flat-on-ground configuration. The method may include receiving, by one or more electrolyzers, the DC power. The method may include generating, by the one or more electrolyzers and via an electrolysis process, oxyhydrogen (HHO) using the DC power.

A system for efficient combustion of a carbonaceous fuel is presented. An ultra low quantity of enhancement gas may be introduced to an internal combustion engine to improve at least one operating metric of the internal combustion engine such as fuel economy and/or reduce engine-out emissions, for example in a vehicle or generator.

A system for efficient combustion of a carbonaceous fuel is presented. An ultra low quantity of enhancement gas may be introduced to an internal combustion engine to improve at least one operating metric of the internal combustion engine such as fuel economy and/or reduce engine-out emissions, for example in a vehicle or generator.