CRT Power Technology – Strategic Positioning Summary

CRT Power Technology – Strategic Positioning Summary Core Concept Carbon Recycling Technology (CRT) is a carbon-recycling power technology in which captured CO₂ is continuously reused while renewable hydrogen provides the energy input. Carbon acts as a recyclable carrier rather than a waste stream. Fossil fuels such as LNG are required only for start-up and commissioning. Strategic Positioning Rather than presenting CRT as a conventional power plant with carbon capture and methanation, it can be positioned as a carbon-recycling energy system. The focus shifts from carbon disposal to carbon circulation. Key Message • Carbon is recycled rather than emitted. • Renewable hydrogen supplies the energy. • CO₂ is continuously captured, converted, reused, and recaptured. • LNG is used only as a start-up fuel. • The concept is applicable across multiple industrial sectors. Applications The same CRT architecture can be applied to: • Data centres and trigeneration systems • Industrial facilities • Utility-scale power generation • Steel production • Marine transport • Aviation fuel production • Other carbon-recycling energy systems Differentiation from CCS Traditional CCS follows the sequence: Capture → Compress → Store. CRT follows the sequence: Capture → Recycle → Fuel → Energy → Capture Again. The objective is not permanent storage of carbon but its repeated reuse within an industrial cycle. Patent and Technology Narrative The deeper scientific basis of CRT is that the carbon atom functions as a reusable carrier. The molecular form may change between CO₂, CO, CH₄, methanol, SAF, e-gasoline, or other carbon-containing products, but the carbon remains in circulation while renewable hydrogen provides the energy required to sustain the cycle. Commercial Vision CRT can be deployed as a modular platform integrating carbon capture, fuel synthesis, power generation, heat recovery, and industrial energy applications. The same core concept can be scaled from small pilots to large commercial installations.

The Missing Link in the Energy Transition

The Missing Link in the Energy Transition: Why Integration Matters More Than Individual Technologies For more than two decades, the global energy transition has focused on developing individual technologies to address climate change and energy security. Significant progress has been made in renewable energy, hydrogen production, carbon capture, ammonia synthesis, batteries, fuel cells, and synthetic fuels. Each of these technologies has demonstrated technical feasibility and commercial potential. Yet despite billions of dollars of investment, the world still faces a fundamental challenge: how to provide reliable 24×7 baseload energy while simultaneously achieving deep emissions reductions. This apparent contradiction raises an important question. If so many technologies are available, why has the core problem not yet been solved? The answer may lie not in the technologies themselves, but in the way they are being developed and deployed. Most are evaluated in isolation, whereas the energy system operates as an interconnected whole. Renewable energy provides low‑carbon electricity but is inherently variable. Batteries offer short-duration storage but become expensive for long-duration and seasonal storage. Hydrogen can store energy for long periods but requires conversion infrastructure. Carbon capture can reduce emissions but does not itself provide an energy carrier. Fuel cells efficiently convert hydrogen into electricity but depend on reliable fuel supplies. Ammonia and synthetic fuels offer transportable energy carriers but require upstream production and downstream utilisation systems. Viewed individually, each technology addresses part of the challenge. Viewed collectively, they reveal a systems-integration problem. Society does not need isolated solutions; it needs an energy ecosystem capable of producing, storing, transporting, and delivering energy continuously, affordably, and with minimal environmental impact. History provides many examples where transformative progress resulted from integration rather than a single breakthrough. The modern electricity grid combined generators, transmission systems, substations, controls, and end-use devices into a coherent network. The LNG industry required gas production, liquefaction, shipping, storage, and regasification. The internet emerged from the integration of computers, communications networks, protocols, and software. In each case, success came not from one technology but from the effective orchestration of many technologies. The energy transition may require a similar shift in thinking. Instead of asking whether renewable energy, hydrogen, carbon capture, batteries, or synthetic fuels can independently solve the problem, a more useful question is how they can be integrated into a unified system. Such a system would harness the strengths of each technology while compensating for their individual limitations. This perspective suggests that the future of energy lies in system architecture. The challenge is not a shortage of innovation; it is the need to connect innovations into reliable, scalable, and economically viable frameworks. Technologies that are often viewed as competitors may ultimately become complementary components of a broader solution. From this viewpoint, the central task of the coming decades is the creation of integrated energy systems capable of delivering dependable 24×7 power with near-zero emissions. The world may already possess many of the necessary building blocks. What remains is the engineering, commercial, and policy effort required to assemble them into a coherent whole. The lesson is simple: the energy transition is not merely a technology challenge. It is an integration challenge. The solutions that succeed will likely be those that combine generation, storage, fuel production, carbon management, and reliability into complete systems that serve society's real needs. In that sense, the future belongs not only to inventors of new technologies, but also to architects of integrated solutions.

Core Concet of CRT

The Sun, sea and the wind are the energy sources in CEWT's Carbon recycling technology

CEWT Core Concept – Carbon Recycling Technology (CRT) The Sun provides the energy. The Wind expands the resource base. The Sea provides the resources. CRT closes the loop. Carbon Recycling Technology (CRT) is founded on a simple principle: work with Nature’s existing cycles rather than against them. CRT harnesses the Sun, the Wind, and the Sea as renewable sources of energy and resources. The Sun and Wind provide renewable electricity. The Sea provides water for hydrogen production and serves as a vast carbon reservoir through dissolved carbon dioxide. Seawater can also be used as a solvent to absorb and recover CO₂ emissions from industrial processes and power generation. In the CRT process: • Renewable energy from the Sun and Wind is used to produce hydrogen. • The Sea provides water for hydrogen production. • The Sea acts as a carbon reservoir through dissolved CO₂. • Seawater can be used to absorb and recover CO₂ emissions. • Captured carbon is recycled into renewable fuels and energy products rather than treated as waste. • Carbon remains within a circular system, reducing dependence on new fossil-carbon inputs. CRT transforms carbon from a waste stream into a recyclable carrier of renewable energy. Unlike conventional fossil-fuel systems, which transfer carbon from underground reservoirs to the atmosphere, CRT seeks to maintain carbon within a managed circular cycle powered by renewable energy. The result is a platform capable of producing: • Renewable Natural Gas (RNG) • e-Methanol • Sustainable Aviation Fuel (SAF) • e-Gasoline • Dispatchable Renewable Power • Industrial Decarbonisation Solutions CRT is not simply a fuel technology. It is a carbon-recycling platform that integrates energy, water, and carbon management into a single circular system. It also helps to stop ‘Ocean acidification’ simultaneously. The Sun provides the energy. The Wind expands the resource base. The Sea provides the resources. CRT closes the loop.

CEWT Technology Portfolio Sheet

CEWT Technology Portfolio Sheet Clean Energy and Water Technologies Pty Ltd (CEWT) Carbon Recycling • Renewable Fuels • Energy Security Core Platform Carbon Recycling Technology (CRT): A platform that combines captured CO₂ and renewable hydrogen to create renewable fuels, dispatchable energy, and industrial decarbonisation solutions. Technology Portfolio Renewable Fuels • Renewable Natural Gas (RNG) • e-Methanol • Sustainable Aviation Fuel (SAF) • e-Gasoline and synthetic fuels Energy Systems • Dispatchable low-carbon power generation • CRT-Trigen systems for data centres • Combined heat, power, and cooling solutions Industrial Decarbonisation • Steel and DRI applications • Refineries and petrochemicals • Process industry carbon recycling • Carbon utilisation and circular carbon systems Business Model • Technology licensing • Process integration and system architecture • Strategic partnerships • Project development support • Engineering and commercialisation pathways Vision Transform captured carbon from a waste stream into a renewable resource by creating circular carbon pathways that support energy security, industrial competitiveness, and net-zero objectives.