A holistic platform for accelerating sorbent-based carbon capture.
Charithea CharalambousElias MoubarakJohannes SchillingEva Sanchez FernandezJin-Yu WangLaura HerraizFergus McilwaineShing Bo PehMatthew GarvinKevin Maik JablonkaSeyed Mohamad MoosaviJoren Van HerckAysu Yurdusen OzturkAlireza PourghaderiAh-Young SongGeorges MouchahamChristian SerreJeffrey A ReimerAndre BardowBerend SmitSusana GarcíaPublished in: Nature (2024)
Reducing carbon dioxide (CO 2 ) emissions urgently requires the large-scale deployment of carbon-capture technologies. These technologies must separate CO 2 from various sources and deliver it to different sinks 1,2 . The quest for optimal solutions for specific source-sink pairs is a complex, multi-objective challenge involving multiple stakeholders and depends on social, economic and regional contexts. Currently, research follows a sequential approach: chemists focus on materials design 3 and engineers on optimizing processes 4,5 , which are then operated at a scale that impacts the economy and the environment. Assessing these impacts, such as the greenhouse gas emissions over the plant's lifetime, is typically one of the final steps 6 . Here we introduce the PrISMa (Process-Informed design of tailor-made Sorbent Materials) platform, which integrates materials, process design, techno-economics and life-cycle assessment. We compare more than 60 case studies capturing CO 2 from various sources in 5 global regions using different technologies. The platform simultaneously informs various stakeholders about the cost-effectiveness of technologies, process configurations and locations, reveals the molecular characteristics of the top-performing sorbents, and provides insights on environmental impacts, co-benefits and trade-offs. By uniting stakeholders at an early research stage, PrISMa accelerates carbon-capture technology development during this critical period as we aim for a net-zero world.