Projects
Human-Earth-System framework for assessing Carbon Dioxide Removal strategies
Assessing the feasibility and effectiveness of Carbon Dioxide Removal (CDR) strategies via the complex and interconnected Human-Earth-System framework
Game-changing absorbents for increasing efficiency and lowering costs of direct air capture (DAC)
Investigating novel liquid absorbents for direct air capture applications
Creating a toolkit for in-situ CO2 mineralisation in basaltic rocks
Unravelling the mechanisms of CO2 mineralisation for successful field-scale deployment
Algal biomass for CO2 removal at scale
Developing a new algal-bacterial biofilm platform for carbon capture and storage
Responsible transition pathways for new carbon dioxide removal technologies
Identifying responsible pathways for the development and deployment of novel carbon dioxide removal technologies
Novel air-liquid contacting concepts for direct air capture of CO2
Developing an innovative pathway for realising effective, low-cost direct air capture
Accelerating discovery of novel CO2 capture materials using AI and machine learning
Teaching chemical intuition to AI to enable a fundamental shift in materials discovery
Microorganisms with macro potential
Exploring biomineralising microbes for ex-situ long-term carbon storage
Looking into fundamental geochemical processes of mineral carbonation
Unravelling molecular-level processes to accelerate mineral carbonation of carbon dioxide
Optimising direct air capture technologies for better environmental and social outcomes
Developing an optimal design methodology for direct air capture