A gas-phase reactor system for dissociating and reacting gas-phase molecules employs a novel combination of plasma and pyrolytic energy to achieve up to 500 times greater dissociation efficiency compared to existing plasma, pyrolytic, catalytic, or water-based remediation systems. Integrated with an adsorption bed, the system neutralizes and captures dissociated elements and molecular fragments to levels below 1 part per billion. The reactor's innovative design eliminates the need for downstream water scrubbing, carrier gases, plasma-enhancing gases, additional heat, or catalytic inputs, enabling true point-of-use remediation. This results in up to a 10-fold reduction in cost of ownership and facility footprint compared to conventional centralized remediation systems, offering a compact, efficient, and cost-effective solution for gas-phase molecular processing.

A gas-phase reactor system for dissociating and reacting gas-phase molecules employs a novel combination of plasma and pyrolytic energy to achieve up to 500 times greater dissociation efficiency compared to existing plasma, pyrolytic, catalytic, or water-based remediation systems. Integrated with an adsorption bed, the system neutralizes and captures dissociated elements and molecular fragments to levels below 1 part per billion. The reactor's innovative design eliminates the need for downstream water scrubbing, carrier gases, plasma-enhancing gases, additional heat, or catalytic inputs, enabling true point-of-use remediation. This results in up to a 10-fold reduction in cost of ownership and facility footprint compared to conventional centralized remediation systems, offering a compact, efficient, and cost-effective solution for gas-phase molecular processing.