INTEGRATED CARBON DIOXIDE REMOVAL AND VALORIZATION

The urgent demand for affordable carbon dioxide removal (CDR) solutions is rapidly increasing as the world faces the pressing challenge of mitigating climate change. To cap the global temperature rise at 1.5 °C within the next century, substantial advancements in direct air CO2 capture (DAC) are crucial. Traditional CO2 capture methods, such as amine scrubbing, face significant challenges, including high energy requirements for sorbent regeneration, high operational expenses, and durability issues. Consequently, there is a critical need for innovative and energy-efficient alternatives to traditional CO2 capture methods. RedoxNRG aims to address this need through the development of electrochemically driven carbon dioxide capture (EDAC) technology, utilizing a novel class of conductive, redox-active nanostructures. This project focuses on employing the unique properties of these nanostructures to achieve reversible CO2 electrosorption under mild conditions — ambient pressure, temperature, and neutral pH. The primary objective is to design, optimize, and apply these materials to EDAC, thereby overcoming the limitations of current methods. By targeting higher energy efficiency, enhanced stability, and reduced operational costs, RedoxNRG seeks to make a significant impact on global CO2 removal efforts.
The EDAC technology developed by RedoxNRG is expected to revolutionize the field of DAC and contribute significantly to global climate change mitigation. By achieving superior energy efficiency and stability compared to conventional methods, this technology can reduce the cost and increase the feasibility of large-scale CO2 capture. Additionally, the integration of CO2 utilization into industrial processes, such as converting captured CO2 into valuable products like methanol or formic acid, further enhances the economic viability and sustainability of the system. This dual-function approach not only addresses the environmental need for CO2 reduction but also provides a pathway for industries to transition from fossil fuels to carbon-neutral operations. The broader impact of this project includes fostering a more sustainable and circular economy, driving significant environmental and economic benefits. By contributing to the reduction of greenhouse gas emissions and promoting innovative industrial practices, CO2REMOVAL project aligns with global sustainability goals and has the potential to position Estonia and Europe as leaders in the fight against climate change. The results of this project provide crucial scientific and technological tools needed for the European industry to meet evolving environmental regulations and societal expectations for a cleaner, more sustainable future.

Our project implemented a comprehensive R&D plan structured into three multidisciplinary tasks: theoretical modeling, synthesis, and application of eco-friendly conductive, redox-active nanostructures (ecoMOMs). Task 1 focused on theoretical modeling to screen and design hypothetical ecoMOMs with diverse combinations. These computational insights guided Task 2, where we synthesized ecoMOMs, using sustainable synthetic procedures. Task 3 involved applying these synthesized ecoMOMs to electrochemical CO2 direct air capture system, evaluating their performance in terms of efficiency and CO2 capture capacity. This integrated approach ensured a continuous exchange of insights among tasks, with theoretical and experimental results. In Task 1, we utilized open-source software for density functional theory modeling to explore the electronic and structural properties of various ecoMOMs. The theoretical models helped predict the conductivity and redox activity of the materials. These models provided critical insights into layer stacking and the impact of different binding centers on CO2 adsorption efficiency, identifying key factors such as induced charge and structural configuration essential for optimizing CO2 electrosorption. In Task 2 we developed scalable, green synthetic protocols using hydrothermal methods and mechanosynthesis. Task 3 tested these materials in electrochemical screening experiments, assessing their stability and CO2 capture performance. Using ex-situ and in-situ electrochemical techniques, we demonstrated the CO2 electrosorption capabilities of ecoMOMs and addressed degradation issues by improving the experimental setup. These advancements led to better gas supply and electrode permeation, enhancing the reliability of the electrosorption process. Overall, our project identified promising ecoMOMs for CO2 EDAC, provided valuable electrochemical performance data, and established guidelines for future research and commercialization efforts.

The results achieved in CO2REMOVAL project represent a significant leap forward in the field of CO2 direct air capture, particularly through the development of eco-friendly sorbent materials for electrochemically driven CO2 capture. The successful synthesis and characterization of ecoMOMs demonstrate promising redox activity and conductivity, crucial for effective CO2 electrosorption under mild operating conditions. This achievement surpasses current state-of-the-art technologies by offering a more energy-efficient and environmentally sustainable approach to CO2 capture, addressing key challenges such as high operational costs and environmental impacts associated with traditional methods. The implications of our findings extend beyond laboratory-scale experiments, laying the groundwork for scalable applications in commercial DAC systems. The promising electrochemical screening results, showcasing high CO2 capture efficiency and stability of developed electrodes, provide a pathway for integrating these materials into practical DAC solutions. Moving forward, further research and development will be essential to optimize ecoMOMs' composition, enhance their durability, and validate their performance in pilot-scale demonstrations. These efforts are crucial to meet the growing global demand for affordable and efficient CO2 removal technologies, supporting climate change mitigation goals effectively.