Transforming the Hydrogen Sector with our ultra-low electricity consumption technology
Electrolysis
50-55 kWh/kg H₂ (current-generation electrolyzers)
S-Wave (current reactor)
41.6 kWh/kg H₂ – The current S-Wave reactor already outperforms electrolyzers by 25%, delivering exceptional energy efficiency, as confirmed by third-party certification.
S-Wave Optimized Reactor (under development)
Under 25.0 kWh/ kg – H2 :
The next-generation of S-Wave reactor is undergoing a relevant optimization that will radically enhance consumption even further to an unprecedented efficiency. This breakthrough enhancement is already validated by Hammer & Stone’s proprietary dynamic simulation algorithms.
How is such an outstanding energy efficiency possible?
Unlike electrolysis, where electrical energy directly splits water molecules, S-Wave leverages localized extreme conditions created by cavitation to dissociate molecules with minimal electricity input.
Here, electrical energy is used only to generate oscillatory fields, triggering a chain reaction of molecular interactions.
Unmatched Efficiency Far Beyond Electrolysis’ Thermodynamic Limits
Even at 100% efficiency, electrolyzers are constrained by thermodynamic laws, requiring at least 39.4 kWh to produce 1 kg of hydrogen.
S-Wave, on the other hand, enables hydrogen extraction with significantly lower electricity consumption than this theoretical limit.
By leveraging intense localized thermal effects, S-Wave drastically reduces the energy needed to break molecular bonds, making it possible to produce hydrogen with far less than 39.4 kWh/kg.
A Game-Changer for the Hydrogen Economy
By overcoming efficiency barriers, S-Wave enables large-scale, low-cost hydrogen production, making green hydrogen economically viable across industries.
With its unmatched energy efficiency, this breakthrough has multi-billion dollar market potential, driving the global transition to a cleaner energy future.