Methods and systems for generation and deployment of a structurally altered gas molecules derived from water are provided. An example system includes a first container for combining purified water with a compound mixture being non-reactive with the water and a conductor of an electric field and a magnetic field. The system includes a magnetic field generator and an electric field generator designed to apply 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 having a higher probability of attraction of electrons into areas adjunct to the structurally altered gas molecules than molecules of the purified water. The system further includes a second container for introducing the structurally altered gas molecules into an environment of a chemical process to facilitate electron transfers during the chemical process, thereby increasing output of the chemical process.

Methods and systems for generation and deployment of a structurally altered gas molecules derived from water are provided. An example system includes a first container for combining purified water with a compound mixture being non-reactive with the water and a conductor of an electric field and a magnetic field. The system includes a magnetic field generator and an electric field generator designed to apply 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 having a higher probability of attraction of electrons into areas adjunct to the structurally altered gas molecules than molecules of the purified water. The system further includes a second container for introducing the structurally altered gas molecules into an environment of a chemical process to facilitate electron transfers during the chemical process, thereby increasing output of the chemical process.

A thixotropically molded product that generates hydrogen by contact with an aqueous solution includes: a matrix portion containing Mg as a main component; and a first particle portion dispersed in the matrix portion and containing, as a main component, any one of Fe, Ni, Co, Cu, and a compound containing at least one of the elements. An average particle diameter of the first particle portion in a cross section is 30.0 ?m or less, and an area fraction of the first particle portion in the cross section is 0.5% or more and 20.0% or less.

A thixotropically molded product that generates hydrogen by contact with an aqueous solution includes: a matrix portion containing Mg as a main component; and a first particle portion dispersed in the matrix portion and containing, as a main component, any one of Fe, Ni, Co, Cu, and a compound containing at least one of the elements. An average particle diameter of the first particle portion in a cross section is 30.0 ?m or less, and an area fraction of the first particle portion in the cross section is 0.5% or more and 20.0% or less.

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.

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.

A process for producing black powder oxygen carriers for use in a chemical looping combustion unit includes the steps of: (a) removing and collecting the black powder waste material that was formed in a gas pipeline; (b) pre-treating the collected black powder to adjust its spherical shape to avoid attrition and fines production; and (c) activating the black powder to increase its reactivity rate and produce the black powder oxygen carrier that is suitable for use in the chemical looping combustion process as an oxygen carrier.

A process for producing black powder oxygen carriers for use in a chemical looping combustion unit includes the steps of: (a) removing and collecting the black powder waste material that was formed in a gas pipeline; (b) pre-treating the collected black powder to adjust its spherical shape to avoid attrition and fines production; and (c) activating the black powder to increase its reactivity rate and produce the black powder oxygen carrier that is suitable for use in the chemical looping combustion process as an oxygen carrier.

A supply system for providing at least oxygen depleted air and water in a vehicle includes a catalytic converter, at least one hydrogen supply means, at least one air supply means, at least one outlet for oxygen depleted air, and a control unit coupled with the catalytic converter. The catalytic converter is couplable with the hydrogen supply means and is adapted for producing water under consumption of hydrogen from the at least one hydrogen supply means and oxygen. The catalytic converter is further couplable with the at least one air supply means for additionally producing oxygen depleted air. Further, the control unit is adapted for selectively operating the catalytic converter based on a demand of water and oxygen depleted air.

A supply system for providing at least oxygen depleted air and water in a vehicle includes a catalytic converter, at least one hydrogen supply means, at least one air supply means, at least one outlet for oxygen depleted air, and a control unit coupled with the catalytic converter. The catalytic converter is couplable with the hydrogen supply means and is adapted for producing water under consumption of hydrogen from the at least one hydrogen supply means and oxygen. The catalytic converter is further couplable with the at least one air supply means for additionally producing oxygen depleted air. Further, the control unit is adapted for selectively operating the catalytic converter based on a demand of water and oxygen depleted air.