Generation, Capture, and Utilization of Industrial Carbon Dioxide

As a carbon‐based life form living in a predominantly carbon‐based environment, it is not surprising that we have created a carbon‐based consumer society. Our principle sources of energy are carbon‐based (coal, oil, and gas) and many of our consumer goods are derived from organic (i.e., carbon‐based...

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Veröffentlicht in:	ChemSusChem 2010-03, Vol.3 (3), p.306-322
Hauptverfasser:	Hunt, Andrew J., Sin, Emily H. K., Marriott, Ray, Clark, James H.
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Sprache:	eng
Schlagworte:	Air Pollution - economics Air Pollution - legislation & jurisprudence Air Pollution - prevention & control Carbon Dioxide - chemistry Carbon Dioxide - isolation & purification Carbon Dioxide - metabolism carbon dioxide fixation carbon storage Fossil Fuels Global Warming - economics Global Warming - legislation & jurisprudence Global Warming - prevention & control green chemistry Green Chemistry Technology - economics Green Chemistry Technology - legislation & jurisprudence Green Chemistry Technology - methods Industrial Waste - prevention & control supercritical fluids sustainable chemistry
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description	As a carbon‐based life form living in a predominantly carbon‐based environment, it is not surprising that we have created a carbon‐based consumer society. Our principle sources of energy are carbon‐based (coal, oil, and gas) and many of our consumer goods are derived from organic (i.e., carbon‐based) chemicals (including plastics, fabrics and materials, personal care and cleaning products, dyes, and coatings). Even our large‐volume inorganic‐chemicals‐based industries, including fertilizers and construction materials, rely on the consumption of carbon, notably in the form of large amounts of energy. The environmental problems which we now face and of which we are becoming increasingly aware result from a human‐induced disturbance in the natural carbon cycle of the Earth caused by transferring large quantities of terrestrial carbon (coal, oil, and gas) to the atmosphere, mostly in the form of carbon dioxide. Carbon is by no means the only element whose natural cycle we have disturbed: we are transferring significant quantities of elements including phosphorus, sulfur, copper, and platinum from natural sinks or ores built up over millions of years to unnatural fates in the form of what we refer to as waste or pollution. However, our complete dependence on the carbon cycle means that its disturbance deserves special attention, as is now manifest in indicators such as climate change and escalating public concern over global warming. As with all disturbances in materials balances, we can seek to alleviate the problem by (1) dematerialization: a reduction in consumption; (2) rematerialization: a change in what we consume; or (3) transmaterialization: changing our attitude towards resources and waste. The “low‐carbon” mantra that is popularly cited by organizations ranging from nongovernmental organizations to multinational companies and from local authorities to national governments is based on a combination of (1) and (2) (reducing carbon consumption though greater efficiency and lower per capita consumption, and replacing fossil energy sources with sources such as wind, wave, and solar, respectively). “Low carbon” is of inherently less value to the chemical and plastics industries at least in terms of raw materials although a version of (2), the use of biomass, does apply, especially if we use carbon sources that are renewable on a human timescale. There is however, another renewable, natural source of carbon that is widely available and for which greater util
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K. ; Marriott, Ray ; Clark, James H.</creator><creatorcontrib>Hunt, Andrew J. ; Sin, Emily H. K. ; Marriott, Ray ; Clark, James H.</creatorcontrib><description>As a carbon‐based life form living in a predominantly carbon‐based environment, it is not surprising that we have created a carbon‐based consumer society. Our principle sources of energy are carbon‐based (coal, oil, and gas) and many of our consumer goods are derived from organic (i.e., carbon‐based) chemicals (including plastics, fabrics and materials, personal care and cleaning products, dyes, and coatings). Even our large‐volume inorganic‐chemicals‐based industries, including fertilizers and construction materials, rely on the consumption of carbon, notably in the form of large amounts of energy. The environmental problems which we now face and of which we are becoming increasingly aware result from a human‐induced disturbance in the natural carbon cycle of the Earth caused by transferring large quantities of terrestrial carbon (coal, oil, and gas) to the atmosphere, mostly in the form of carbon dioxide. Carbon is by no means the only element whose natural cycle we have disturbed: we are transferring significant quantities of elements including phosphorus, sulfur, copper, and platinum from natural sinks or ores built up over millions of years to unnatural fates in the form of what we refer to as waste or pollution. However, our complete dependence on the carbon cycle means that its disturbance deserves special attention, as is now manifest in indicators such as climate change and escalating public concern over global warming. As with all disturbances in materials balances, we can seek to alleviate the problem by (1) dematerialization: a reduction in consumption; (2) rematerialization: a change in what we consume; or (3) transmaterialization: changing our attitude towards resources and waste. The “low‐carbon” mantra that is popularly cited by organizations ranging from nongovernmental organizations to multinational companies and from local authorities to national governments is based on a combination of (1) and (2) (reducing carbon consumption though greater efficiency and lower per capita consumption, and replacing fossil energy sources with sources such as wind, wave, and solar, respectively). “Low carbon” is of inherently less value to the chemical and plastics industries at least in terms of raw materials although a version of (2), the use of biomass, does apply, especially if we use carbon sources that are renewable on a human timescale. There is however, another renewable, natural source of carbon that is widely available and for which greater utilization would help restore material balance and the natural cycle for carbon in terms of resource and waste. CO2, perhaps the most widely discussed and feared chemical in modern society, is as fundamental to our survival as water, and like water we need to better understand the human as well as natural production and consumption of CO2 so that we can attempt to get these into a sustainable balance. Current utilization of this valuable resource by the chemical industry is only 90 megatonne per year, compared to the 26.3 gigatonne CO2 generated annually by combustion of fossil fuels for energy generation, as such significant opportunities exist for increased utilization of CO2 generated from industrial processes. It is also essential that renewable energy is used if CO2 is to be utilized as a C1 building block. The increasing emissions of greenhouse gases, such as CO2, from human activities are leading to an enhanced greenhouse effect. It is of vital importance to the long‐term success of the human race that CO2 emissions are reduced in order to prevent damaging changes in climate. In this Review the opportunities for increased utilization of CO2 generated from industrial processes are explored.</description><identifier>ISSN: 1864-5631</identifier><identifier>EISSN: 1864-564X</identifier><identifier>DOI: 10.1002/cssc.200900169</identifier><identifier>PMID: 20049768</identifier><language>eng</language><publisher>Weinheim: WILEY-VCH Verlag</publisher><subject><![CDATA[Air Pollution - economics ; Air Pollution - legislation & jurisprudence ; Air Pollution - prevention & control ; Carbon Dioxide - chemistry ; Carbon Dioxide - isolation & purification ; Carbon Dioxide - metabolism ; carbon dioxide fixation ; carbon storage ; Fossil Fuels ; Global Warming - economics ; Global Warming - legislation & jurisprudence ; Global Warming - prevention & control ; green chemistry ; Green Chemistry Technology - economics ; Green Chemistry Technology - legislation & jurisprudence ; Green Chemistry Technology - methods ; Industrial Waste - prevention & control ; supercritical fluids ; sustainable chemistry]]></subject><ispartof>ChemSusChem, 2010-03, Vol.3 (3), p.306-322</ispartof><rights>Copyright © 2010 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c4859-e9e43f25e7d12e0a0126338314205c316243c89f585b84ea46d28baed9243b073</citedby><cites>FETCH-LOGICAL-c4859-e9e43f25e7d12e0a0126338314205c316243c89f585b84ea46d28baed9243b073</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://onlinelibrary.wiley.com/doi/pdf/10.1002%2Fcssc.200900169$$EPDF$$P50$$Gwiley$$H</linktopdf><linktohtml>$$Uhttps://onlinelibrary.wiley.com/doi/full/10.1002%2Fcssc.200900169$$EHTML$$P50$$Gwiley$$H</linktohtml><link.rule.ids>314,780,784,1417,27924,27925,45574,45575</link.rule.ids><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/20049768$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink></links><search><creatorcontrib>Hunt, Andrew J.</creatorcontrib><creatorcontrib>Sin, Emily H. K.</creatorcontrib><creatorcontrib>Marriott, Ray</creatorcontrib><creatorcontrib>Clark, James H.</creatorcontrib><title>Generation, Capture, and Utilization of Industrial Carbon Dioxide</title><title>ChemSusChem</title><addtitle>ChemSusChem</addtitle><description>As a carbon‐based life form living in a predominantly carbon‐based environment, it is not surprising that we have created a carbon‐based consumer society. Our principle sources of energy are carbon‐based (coal, oil, and gas) and many of our consumer goods are derived from organic (i.e., carbon‐based) chemicals (including plastics, fabrics and materials, personal care and cleaning products, dyes, and coatings). Even our large‐volume inorganic‐chemicals‐based industries, including fertilizers and construction materials, rely on the consumption of carbon, notably in the form of large amounts of energy. The environmental problems which we now face and of which we are becoming increasingly aware result from a human‐induced disturbance in the natural carbon cycle of the Earth caused by transferring large quantities of terrestrial carbon (coal, oil, and gas) to the atmosphere, mostly in the form of carbon dioxide. Carbon is by no means the only element whose natural cycle we have disturbed: we are transferring significant quantities of elements including phosphorus, sulfur, copper, and platinum from natural sinks or ores built up over millions of years to unnatural fates in the form of what we refer to as waste or pollution. However, our complete dependence on the carbon cycle means that its disturbance deserves special attention, as is now manifest in indicators such as climate change and escalating public concern over global warming. As with all disturbances in materials balances, we can seek to alleviate the problem by (1) dematerialization: a reduction in consumption; (2) rematerialization: a change in what we consume; or (3) transmaterialization: changing our attitude towards resources and waste. The “low‐carbon” mantra that is popularly cited by organizations ranging from nongovernmental organizations to multinational companies and from local authorities to national governments is based on a combination of (1) and (2) (reducing carbon consumption though greater efficiency and lower per capita consumption, and replacing fossil energy sources with sources such as wind, wave, and solar, respectively). “Low carbon” is of inherently less value to the chemical and plastics industries at least in terms of raw materials although a version of (2), the use of biomass, does apply, especially if we use carbon sources that are renewable on a human timescale. There is however, another renewable, natural source of carbon that is widely available and for which greater utilization would help restore material balance and the natural cycle for carbon in terms of resource and waste. CO2, perhaps the most widely discussed and feared chemical in modern society, is as fundamental to our survival as water, and like water we need to better understand the human as well as natural production and consumption of CO2 so that we can attempt to get these into a sustainable balance. Current utilization of this valuable resource by the chemical industry is only 90 megatonne per year, compared to the 26.3 gigatonne CO2 generated annually by combustion of fossil fuels for energy generation, as such significant opportunities exist for increased utilization of CO2 generated from industrial processes. It is also essential that renewable energy is used if CO2 is to be utilized as a C1 building block. The increasing emissions of greenhouse gases, such as CO2, from human activities are leading to an enhanced greenhouse effect. It is of vital importance to the long‐term success of the human race that CO2 emissions are reduced in order to prevent damaging changes in climate. In this Review the opportunities for increased utilization of CO2 generated from industrial processes are explored.</description><subject>Air Pollution - economics</subject><subject>Air Pollution - legislation & jurisprudence</subject><subject>Air Pollution - prevention & control</subject><subject>Carbon Dioxide - chemistry</subject><subject>Carbon Dioxide - isolation & purification</subject><subject>Carbon Dioxide - metabolism</subject><subject>carbon dioxide fixation</subject><subject>carbon storage</subject><subject>Fossil Fuels</subject><subject>Global Warming - economics</subject><subject>Global Warming - legislation & jurisprudence</subject><subject>Global Warming - prevention & control</subject><subject>green chemistry</subject><subject>Green Chemistry Technology - economics</subject><subject>Green Chemistry Technology - legislation & jurisprudence</subject><subject>Green Chemistry Technology - methods</subject><subject>Industrial Waste - prevention & control</subject><subject>supercritical fluids</subject><subject>sustainable chemistry</subject><issn>1864-5631</issn><issn>1864-564X</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2010</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqFkDFPwzAQRi0EolBYGVE2lqbYsePYYxWgVKpAohS6WU5ykQxpUuxEtPx6UlIqNqY73b3vDR9CFwQPCcbBdepcOgwwlhgTLg_QCRGc-SFni8P9TkkPnTr3hjHHkvNj1GsDTEZcnKDRGEqwujZVOfBivaobCwNPl5k3r01hvn4-XpV7kzJrXG2NLlrMJu3xxlRrk8EZOsp14eB8N_tofnf7HN_708fxJB5N_ZSJUPoggdE8CCHKSABYYxJwSgUlLMBhSgkPGE2FzEMRJoKBZjwLRKIhk-0jwRHto6vOu7LVRwOuVkvjUigKXULVOBVRGgoqMW3JYUemtnLOQq5W1iy13SiC1bY1tW1N7VtrA5c7dZMsIdvjvzW1gOyAT1PA5h-dimez-K_c77LG1bDeZ7V9VzyiUaheH8ZqEcVPM0an6oV-A09bhso</recordid><startdate>20100322</startdate><enddate>20100322</enddate><creator>Hunt, Andrew J.</creator><creator>Sin, Emily H. 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K.</creatorcontrib><creatorcontrib>Marriott, Ray</creatorcontrib><creatorcontrib>Clark, James H.</creatorcontrib><collection>Istex</collection><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>MEDLINE - Academic</collection><jtitle>ChemSusChem</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Hunt, Andrew J.</au><au>Sin, Emily H. K.</au><au>Marriott, Ray</au><au>Clark, James H.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Generation, Capture, and Utilization of Industrial Carbon Dioxide</atitle><jtitle>ChemSusChem</jtitle><addtitle>ChemSusChem</addtitle><date>2010-03-22</date><risdate>2010</risdate><volume>3</volume><issue>3</issue><spage>306</spage><epage>322</epage><pages>306-322</pages><issn>1864-5631</issn><eissn>1864-564X</eissn><abstract>As a carbon‐based life form living in a predominantly carbon‐based environment, it is not surprising that we have created a carbon‐based consumer society. Our principle sources of energy are carbon‐based (coal, oil, and gas) and many of our consumer goods are derived from organic (i.e., carbon‐based) chemicals (including plastics, fabrics and materials, personal care and cleaning products, dyes, and coatings). Even our large‐volume inorganic‐chemicals‐based industries, including fertilizers and construction materials, rely on the consumption of carbon, notably in the form of large amounts of energy. The environmental problems which we now face and of which we are becoming increasingly aware result from a human‐induced disturbance in the natural carbon cycle of the Earth caused by transferring large quantities of terrestrial carbon (coal, oil, and gas) to the atmosphere, mostly in the form of carbon dioxide. Carbon is by no means the only element whose natural cycle we have disturbed: we are transferring significant quantities of elements including phosphorus, sulfur, copper, and platinum from natural sinks or ores built up over millions of years to unnatural fates in the form of what we refer to as waste or pollution. However, our complete dependence on the carbon cycle means that its disturbance deserves special attention, as is now manifest in indicators such as climate change and escalating public concern over global warming. As with all disturbances in materials balances, we can seek to alleviate the problem by (1) dematerialization: a reduction in consumption; (2) rematerialization: a change in what we consume; or (3) transmaterialization: changing our attitude towards resources and waste. The “low‐carbon” mantra that is popularly cited by organizations ranging from nongovernmental organizations to multinational companies and from local authorities to national governments is based on a combination of (1) and (2) (reducing carbon consumption though greater efficiency and lower per capita consumption, and replacing fossil energy sources with sources such as wind, wave, and solar, respectively). “Low carbon” is of inherently less value to the chemical and plastics industries at least in terms of raw materials although a version of (2), the use of biomass, does apply, especially if we use carbon sources that are renewable on a human timescale. There is however, another renewable, natural source of carbon that is widely available and for which greater utilization would help restore material balance and the natural cycle for carbon in terms of resource and waste. CO2, perhaps the most widely discussed and feared chemical in modern society, is as fundamental to our survival as water, and like water we need to better understand the human as well as natural production and consumption of CO2 so that we can attempt to get these into a sustainable balance. Current utilization of this valuable resource by the chemical industry is only 90 megatonne per year, compared to the 26.3 gigatonne CO2 generated annually by combustion of fossil fuels for energy generation, as such significant opportunities exist for increased utilization of CO2 generated from industrial processes. It is also essential that renewable energy is used if CO2 is to be utilized as a C1 building block. The increasing emissions of greenhouse gases, such as CO2, from human activities are leading to an enhanced greenhouse effect. It is of vital importance to the long‐term success of the human race that CO2 emissions are reduced in order to prevent damaging changes in climate. In this Review the opportunities for increased utilization of CO2 generated from industrial processes are explored.</abstract><cop>Weinheim</cop><pub>WILEY-VCH Verlag</pub><pmid>20049768</pmid><doi>10.1002/cssc.200900169</doi><tpages>17</tpages></addata></record>
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subjects	Air Pollution - economics Air Pollution - legislation & jurisprudence Air Pollution - prevention & control Carbon Dioxide - chemistry Carbon Dioxide - isolation & purification Carbon Dioxide - metabolism carbon dioxide fixation carbon storage Fossil Fuels Global Warming - economics Global Warming - legislation & jurisprudence Global Warming - prevention & control green chemistry Green Chemistry Technology - economics Green Chemistry Technology - legislation & jurisprudence Green Chemistry Technology - methods Industrial Waste - prevention & control supercritical fluids sustainable chemistry
title	Generation, Capture, and Utilization of Industrial Carbon Dioxide
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