We Turn Waste into Clean Energy
We transform waste into sustainable energy solutions tackling environmental challenges head-on.
Through innovation and technology, we redefine how waste is repurposed advancing the circular economy and creating a cleaner and greener world.
Vision
We drive the global shift to sustainability by developing and scaling feedstock-based technologies that convert waste into clean energy. Our solutions reduce waste, lower emissions and help restore the environment for a greener future.
Mission
We convert waste into valuable energy by transforming various feedstocks, including tyres and other waste materials. Through innovation and scale, we minimise global waste and drive the transition to sustainable energy solutions.
Problems We Solve
Millions of tonnes of waste, from tyres to other feedstocks, end up in landfills or are incinerated, adding to pollution. We tackle this by converting waste into clean energy solving waste issues while providing a sustainable energy source.
Our Technologies
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Hybrid Miacrowave Plasma Torch Enhanced Gasification
HMPG (Hybrid Microwave Plasma Torch Enhanced Gasification) technology efficiently gasifies various types of burnable waste, producing syngas without flue gases and extracting clean H2, while recycling the CO2-rich tail gas back into the reformer to generate additional H2 and carbon sludge, resulting in a remarkable 70% to 100% reduction in CO2 emissions.
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HMPG (Hybrid Microwave Plasma Torch Enhanced Gasification) can produce green methanol for the transformative fuel of shipping industry as well as for a key raw material of Sustainable Aviation Fuel(SAF) for the aviation industry.
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Microwave Plasma Steam Methane Reforming and Gas Cracker
MPSMR (Microwave Plasma Steam Methane Reforming) technology produces clean hydrogen from natural gas without catalysts or a WGS reactor, using high temperatures and diverse radicals generated by the microwave steam plasma torch as catalysts for methane reforming, achieving over 70% CO2 emissions reduction and simultaneous reforming and WGS reactions.
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MPGC (Microwave Plasma Gas Cracker) technology enables efficient and precise dissociation of methane, producing CO2-free hydrogen with lower energy consumption and enhanced cracking efficiency and carbon black by-product.
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Microwave Plasma Ammonia
Producer and Cracker
MPAP (Microwave Plasma Ammonia Producer) technology reduces energy consumption compared to Haber-Bosch and water electrolysis methods, generates CO2 free green ammonia, and streamlines the production timeline by eliminating the need for separate green hydrogen production through water electrolysis.
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MPAC (Microwave Plasma Ammonia Cracker) technology enables the production of high-purity, CO2 free hydrogen by decomposing ammonia using our patented microwave plasma torch.
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GS-1000: On-Site Hydrogen Production from Natural Gas
GS-1000 is a compact, modular hydrogen production system that enables existing gas-fired power plants to reduce carbon emissions without replacing infrastructure.
It utilises a catalytic microwave-plasma reactor to convert natural gas and water into a hydrogen-rich gas stream. This stream is then refined through cryogenic separation, yielding clean hydrogen fuel and recoverable carbon byproducts. The hydrogen is fed directly into existing turbines while the carbon compounds are captured for reuse in industrial processes.
Each 20-foot unit supports up to 25MW of generation, and multiple modules can be clustered to scale output. Designed for rapid deployment, GS-1000 integrates seamlessly into existing plant operations with minimal disruption.
Worldwide Business Opportunities
​We are committed to expanding our presence as a leading technology solution provider on a global scale. Our innovative solutions in converting waste into clean and sustainable energy position us at the forefront of the industry. We have business opportunities in Australia, the US, China, India, Saudi Arabia, Europe, and ASEAN countries.
We actively explore business opportunities across international markets, collaborating with partners, governments and enterprises to deliver our technology solutions that address global challenges. By leveraging our expertise and advanced technologies, we aim to drive sustainable groth, create new market opportunities and contribute to a cleaner and more efficient future worldwide.
Our Projects
- Converting waste tyres into clean energy -
CERG
(Clean Energy Resources Geelong)
Project Overview
The project is a pilot initiative between Green Science and CERG aimed at developing innovative solutions for clean energy by leveraging Green Science’s advanced technologies to convert tyre feedstock into clean energy (hydrogen) with improved efficiency and reduced carbon emissions.
About CERG
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Expertise in Clean Energy: CERG specialises in converting waste including end-of-life tyres into green hydrogen and other renewable resources with zero harmful emissions.
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Scalable and Adaptable Technology: CERG's technology can process 100 to 1000 tonnes of feedstock per day making it suitable for large-scale operations and adaptable to various types of waste.
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Strategic Partnerships: CERG has partnered with the Australian Federal Government and Deakin University to address environmental challenges and promote sustainable energy solutions. This partnership is to provide an environmentally-friendly solution to processing end-of-life tyres by converting them into clean baseload electricity, green hydrogen and carbon black.
3 tonnes of tyre feedstock per day
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The project processes 3 tonnes of tyre feedstock daily that includes collecting used tyres and converting them into clean energy reducing waste and promoting sustainability.
Converting tyre into clean energy (Hydrogen)
The primary focus of the project is to convert tyre feedstock into clean energy, specifically hydrogen, which helps manage waste tyres and contributes to the production of a clean and renewable energy source.
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On the way to commercialisation stage in 2025
The project is progressing steadily and is expected to reach the commercialisation stage by 2025 meaning that the technologies and processes developed will be ready for large-scale deployment and market introduction.
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Ready to scale up to 50~100 tonnes per day
At commercialisation, the project aims to scale up to processing 50–100 tonnes of tyre feedstock daily, boosting waste management and clean energy production.
Deploying proven river interception technologies in 10 high-impact cities across Latin America and Asia to reduce river-borne plastic pollution by approximately 90%.
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Interception Technology
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Piloting a waste-to-energy solution from Green Science in Guatemala converting up to 20 tons of mixed waste daily into emission-free energy.
Waste-to-Energy Solution
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Creating a replicable model for other interceptions and future waste-to-energy projects benefiting communities in developing regions by improving waste management and providing clean energy.
Global Impact
- Converting waste plastics into clean energy -
PICCO
(Plastic Interception & Conversion for Clean Oceans)
Project Overview
The PICCO project aims to tackle ocean plastic pollution by intercepting waste in 10 high-impact cities and converting it into clean energy. The project focuses on scaling river plastic pollution interception, reviving ecosystems, and sustaining communities.
About The Ocean Cleanup
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The Ocean Cleanup is a non-profit organisation dedicated to developing and scaling technologies to rid the oceans of plastic.
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The organisation has removed millions of kilograms of plastic from oceans and rivers globally.
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They deploy scalable plastic interception technologies in rivers and oceans.
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The Ocean Cleanup operates in multiple countries, including Indonesia, Guatemala and the United States.
Our Partners
We are piloting a project with CERG to convert tyre feedstock into clean energy reducing carbon emissions. The PICCO initiative offers an opportunity to turn ocean plastic waste into clean energy in collaboration with The Ocean Cleanup.
