Our mission is simple: to reduce costs, cut carbon, and build a truly renewable future.
Advancing biomass gasification through precise design and research to achieve cleaner, more efficient renewable energy systems.
Transforming forestry residues and agricultural by-products into reliable, low-carbon energy for circular local economies.
Developing scalable systems that adapt to farms, communities, and industries for flexible, efficient energy use.
Creating renewable technologies that reduce reliance on imported fuels and strengthen local energy resilience.
Turning natural resources and waste into clean, efficient energy
Our core research focuses on refining the gasification process that transforms biomass into syngas — a renewable, low-emission fuel for heat and power generation. By improving efficiency, control, and reliability, we are paving the way for a new standard in sustainable energy production.
Developing optimized gasifier designs that deliver consistent performance and fuel flexibility.
Reducing emissions and maximizing energy yield through advanced control and temperature management.
Building pilot systems to validate technology performance in real-world conditions.
Our research is in the early stages of developing carbon capture systems that extract and repurpose CO₂ from industrial and energy processes. By refining absorption methods, material efficiency, and system integration, we aim to create scalable solutions that help industries reduce emissions and close the loop on carbon use.
Researching advanced sorbents and membranes that enhance CO₂ absorption rates, reduce energy demand, and improve system longevity.
Developing adaptable designs that integrate seamlessly with existing energy systems to optimise efficiency and minimise disruption.
Designing flexible configurations for agricultural, commercial, and industrial environments.
Designing flexible, modular systems for every scale of operation
We are developing modular energy systems that adapt to the needs of farms, communities, and industries. Each system is designed for seamless integration, combining power generation, heat recovery, and storage to operate efficiently both off-grid and on-grid.
Creating scalable systems that grow with demand while maintaining high performance.
Combining energy generation, storage, and management for maximum system efficiency.
Designing flexible configurations for agricultural, commercial, and industrial environments.
Our research is preparing to enter the early stages of developing green hydrogen production through renewable-powered electrolysis. This future project aims to refine the efficiency, cost-effectiveness, and scalability of hydrogen generation, positioning it as a clean energy carrier that supports industrial processes, transport, and power storage.
Studying advanced electrolysis methods to improve conversion rates and reduce overall power consumption during hydrogen generation.
Investigating processes that convert natural and synthetic waste polymers into hydrogen, helping to reduce global pollution while producing clean energy.
Researching efficient compression, storage, and delivery systems to make hydrogen accessible and cost-effective for multiple applications.