04895nam 2200661 a 450 991079001310332120230801221847.01-280-12849-697866135323740-643-10682-0(CKB)2670000000155560(EBL)866451(OCoLC)759909520(SSID)ssj0000832136(PQKBManifestationID)12336825(PQKBTitleCode)TC0000832136(PQKBWorkID)10881274(PQKB)10468900(MiAaPQ)EBC866451(Au-PeEL)EBL866451(CaPaEBR)ebr10619931(CaONFJC)MIL353237(EXLCZ)99267000000015556020120801d2012 uy 0engur|n|---|||||txtccrClean energy, climate and carbon[electronic resource] /Peter J. CookCollingwood, Vic. CSIRO Pub. ;Leiden CRCc20121 online resource (233 p.)Description based upon print version of record.0-643-09485-7 Includes bibliographical references (p. 195-210) and index.Cover; Contents; Preface; Acknowledgements; 1 The context; Climate change science: the controversies; Global and national efforts to take action on climate change; About this book; 2 CO2 and climate change; Greenhouse gases; The nature of carbon dioxide; Carbon dioxide and earth's history; Weather versus climate; Causes of pre-human climate change; Distinguishing natural climate change from anthropogenic climate change; Sea level change as evidence for global warming; Global warming and extreme weather events; Act now or later?; Conclusions; 3 Where and why are we producing so much CO2?The production and use of energy and its impacts on CO2 emissions: an overviewThe use of fossil fuels; Two key sectors: electricity production and transport; Conclusions; 4 Technology options for decreasing CO2 emissions; Solar energy; Wind power; Hydroelectric power; Ocean energy; Biomass; Geothermal energy; Nuclear power; Sequestering CO2 through carbon capture and storage (CCS); Conclusion; 5 The mitigation mix; Population growth and the energy mix; Biofuels in the mix; Land requirements of different technologies; Energy and water; Renewable energy in the energy mixNon renewable energy in the energy mixThe energy mix in the medium to long term; Conclusions; 6 Where and how can we capture CO2?; Directly removing CO2 from the atmosphere; Capturing CO2 emitted from various sources; CCS and gas production; CCS and coal and gas-fired power generation; Post combustion capture; CCS and gasification; CCS and industrial processes emitting CO2; Technologies for separating CO2 from emissions; Conclusions; 7 How can we transport CO2?; Key issues in transportation of CO2 via pipelines; CO2 transportation by road, rail and sea; Reducing transportation costs: CO2 hubsConclusion8 Storing CO2; Why geological storage over other forms of storage?; Identifying suitable geological CO2 storage sites: sedimentary basins; Features of a sedimentary basin that may make it suitable for storage; Storage of CO2 in depleted oil and gas fields; Storage in deep saline aquifers; Storage in coals; Storage in basalts; Storage in serpentinites; Assessing storage capacity; National assessments of storage potential; Conclusions; 9 How do we know CCS will be effective?; The nature of risk assessment; Geological risk; Existing natural gas storage facilitiesNatural accumulations of CO2Knowledge derived from large scale commercial CO2 storage projects; Location-specific risk assessment: characterising the site; The risks of earthquakes; The risk to groundwater; Monitoring; The regulatory regime; A 'social licence' for CCS?; 10 The cost of clean energy; The interplay of costs; The costs of capturing CO2 emissions from non-power sources; Transport and associated costs; Storage costs; Indicative total costs for CCS; Cost estimates derived from operational CCS activities; Costing uncertainty; Comparison costing; Conclusions11 The technology and the politics of clean energyOutlines the global challenge of decreasing greenhouse gas emissions.Geological carbon sequestrationCarbon dioxide mitigationGreenhouse gas mitigationGeological carbon sequestration.Carbon dioxide mitigation.Greenhouse gas mitigation.333.79344.2404/6342Cook P. J1468785MiAaPQMiAaPQMiAaPQBOOK9910790013103321Clean energy, climate and carbon3839169UNINA