Reprint

Carbon Capture and Storage

Edited by
August 2019
178 pages
  • ISBN978-3-03921-399-3 (Paperback)
  • ISBN978-3-03921-400-6 (PDF)

This is a Reprint of the Special Issue Carbon Capture and Storage that was published in

Chemistry & Materials Science
Engineering
Environmental & Earth Sciences
Physical Sciences
Summary

Climate change is one of the main threats to modern society. This phenomenon is associated with an increase in greenhouse gas (GHGs, mainly carbon dioxide—CO2) emissions due to anthropogenic activities. The main causes are the burning of fossil fuels and land use change (deforestation). Climate change impacts are associated with risks to basic needs (health, food security, and clean water), as well as risks to development (jobs, economic growth, and the cost of living). The processes involving CO2 capture and storage are gaining attention in the scientific community as an alternative for decreasing CO2 emissions, reducing its concentration in ambient air. The carbon capture and storage (CCS) methodologies comprise three steps: CO2 capture, CO2 transportation, and CO2 storage. Despite the high research activity within this topic, several technological, economic, and environmental issues as well as safety problems remain to be solved, such as the following needs: increase of CO2 capture efficiency, reduction of process costs, and verification of the environmental sustainability of CO2 storage.

Format
  • Paperback
License and Copyright
© 2019 by the authors; CC BY-NC-ND license
Keywords
CO2 separation; TBAB; IGCC; anti-agglomerant; micromorphology; hydrate; carbon capture and storage; knowledge mapping; technological evolution; CiteSpace; carbon storage; the Loess Plateau; InVEST; carbon density; normalized difference vegetation index (NDVI); supercritical CO2; flow instability; stability map; CO2 pipeline; carbon capture and storage (CCS); CO2 capture and utilization; energy dependence; power-to-methane; synthetic natural gas; renewable power; fossil fuels; electricity production; carbon capture; calcium looping; life cycle assessment; GHG mitigation; CCS; cement; techno-economic analysis; MEA-based absorption; chilled ammonia; membrane-assisted CO2 liquefaction; oxyfuel; calcium looping; CO2 capture; cement production with CO2 capture; CO2 capture in industry; CO2 capture retrofitability; oxyfuel; chilled ammonia; membrane-assisted CO2 liquefaction; calcium looping