Humanity faces the global challenge of safely removing CO2 from the atmosphere to secure a stable climate. Broadly, there are three options: terrestrial, soils and ocean, and coastal blue carbon sinks. Each option has unique characteristics in relation to permanence, leakage, environmental integrity and co-bene?ts. This extended abstract explores opportunities for blue carbon projects and highlights the important role of engineers in advancing the success of these innovative techniques. Examples of blue carbon include salt marshes, mangroves, seagrasses, macro-algae, coral reefs and open-ocean micro-algae. Regional case studies for mangrove rehabilitation and pioneering research in Australia on micro-algae and open-ocean sequestration are also presented. The world’s oceans contain about 90% of the global carbon budget. Nearly half of global primary productivity occurs in the open-ocean; this productivity has been achieved using only 0.05% of the earth’s biomass. Coastal and marine systems are ef?cient at the continuous storage of carbon, retaining it for centuries. Co-bene?ts include coastal protection, ?sh nurseries, marine biodiversity and improved water quality. Blue carbon is therefore not only direct mitigation, but also a major contributor to the adaptation of changing climate, building a more resilient ecology and supporting long-term sustainability, including that of the major carbon-based industries. Engineers are well equipped to lead this blue revolution while working with scientists and carbon professionals. This extended absrtact highlights opportunities for fast-track implementation and the engineering challenges; it draws on case studies to show scaleable solutions for achieving climate and food security.