OUR DIFFERENCE
Scalable and resilient clean fuel infrastructure
Greenlyte’s modular platform enables a fossil-free energy supply wherever it’s needed most.
Most synthetic fuel solutions rely on fossil-derived inputs and energy-intensive processes. Greenlyte changes the equation.
Our Liquid Solar system converts sunlight, air, and water into high-purity carbon and hydrogen, the essential feedstocks for clean fuel, through an all-electric, modular platform optimized for intermittent renewable power.
This is Liquid Solar:
A new energy era.
No fossils. No combustion. No compromise.
Sunlight
+
Air
+
Water
=
Fuel-ready carbon and hydrogen
TECHNOLOGY
The Liquid Solar system
Greenlyte’s technology transforms air, sunlight and water into fuel-ready feedstocks, transforming carbon and hydrogen production into a scalable, fully electrified process that thrives on cheap, intermittent renewable energy.
1
Direct air capture through efficient absorption
Ambient air is absorbed by a non-toxic, water-based solution, capturing carbon as solid bicarbonate, without the need for heat, pressure, or toxic chemicals.
2
Scalable Carbon Storage
Captured carbon is stored until renewable electricity is available. This decouples collection from release, creating a resilient system that adapts to variable solar supply.
3
Electrochemical desorption and hydrogen co-production
Using only cheap solar power when given, carbon and hydrogen feedstocks are produced through a patented electrolysis process. The absorbent is fully regenerated for reuse, making the system circular and cost-efficient. Day and night's difference in solar power availability determine the process.
4
Ready for synthesis
The resulting carbon and hydrogen, both >99% pure, are ready for integration into e-fuel synthesis pathways, including e-methanol, eSAF, e-diesel, and other clean chemicals.
1
Direct air capture through efficient absorption
Ambient air is absorbed by a non-toxic, water-based solution, capturing carbon as solid bicarbonate, without the need for heat, pressure, or toxic chemicals.
2
Scalable Carbon Storage
Captured carbon is stored until renewable electricity is available. This decouples collection from release, creating a resilient system that adapts to variable solar supply.
3
Electrochemical desorption and hydrogen co-production
Using only cheap solar power when given, carbon and hydrogen feedstocks are produced through a patented electrolysis process. The absorbent is fully regenerated for reuse, making the system circular and cost-efficient. Day and night's difference in solar power availability determine the process.
4
Ready for synthesis
The resulting carbon and hydrogen, both >99% pure, are ready for integration into e-fuel synthesis pathways, including e-methanol, eSAF, e-diesel, and other clean chemicals.
OUR ADVANTAGE
The platform behind clean fuel production
30% lower energy costs
Electrochemical capture runs on direct current from wind and solar. No heat. No combustion. No toxic solvents.
50% lower system costs
Integrated CO₂ and H₂ production minimizes capital and operational expenses.
Fuel-ready outputs
99% pure carbon and hydrogen, delivered at tunable ratios or as direct syngas, ready for immediate use in synthesis processes.
30% lower energy costs
Electrochemical capture runs on direct current from wind and solar. No heat. No combustion. No toxic solvents.
50% lower system costs
Integrated CO₂ and H₂ production minimizes capital and operational expenses.
Fuel-ready outputs
99% pure carbon and hydrogen, delivered at tunable ratios or as direct syngas, ready for immediate use in synthesis processes.
INTEGRATION
One electrified system. Multiple fuel pathways.
Greenlyte delivers the infrastructure that e-fuel producers rely on, which is scalable, flexible, and designed to plug into today’s clean fuel applications.
Modular design for fast deployment and capacity scaling
Tunable outputs for methanol, Fischer-Tropsch, Sabatier, and more
Proven in the field with operational pilots in Duisburg and Marl
R&D PROJECTS
Our Research
Greenlyte GigaSAF 1
Project
CCU Modellregion
RESEARCH GOAL
This project conducts a pre-study to integrate Greenlyte’s DAC-H₂ technology with methanol synthesis, paving the way for Greenlyte’s first commercial plant in Marl.
MAIN FACTS
Essen, Germany
Location
2025/2026
Planned year of deployment
PARTNERS
PUBLIC FUNDING INSTITUTIONS
Project
HyInnoHECC
Use case
This project develops a scalable DAC-H₂ electrolyzer to overcome desorption limits, combining advanced design, material testing, and modeling within RWTH Aachen’s Zukunftscluster Wasserstoff.
MAIN FACTS
Essen, Germany
Location
2025/2026
Planned year of deployment
PARTNERS
PUBLIC FUNDING INSTITUTIONS
Project
SPRIN-D
Research goal
Validation study for crystallization.
MAIN FACTS
Essen, Germany
Location
2025
Planned year of deployment
PARTNERS
Project
Greenberry Grüne Gründungen
Research goal
Unleashing fully integrated DAC with autonomous carbon absorption-desorption – setting the new baseline for scalable, affordable carbon capture.
MAIN FACTS
Essen, Germany
Location
2024/2025
Planned year of deployment
PARTNERS
MEET OUR TEAM
The builders of Greenlyte
Scientists, engineers, and entrepreneurs united by a bold idea: that clean fuel can be built from sunlight, air, and water.
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PARTNER WITH US
Explore how Greenlyte can support your transition to fossil-free fuel production.
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