Feedstocks study on CO2 mineralization technology

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• 作者：Heping Xie ; Liang Tang ; Yufei Wang ; Tao Liu ; Zhengmeng Hou…
• 关键词：CO2 mineralization ; Electricity generation ; Alkaline earth minerals ; Industrial alkaline wastes ; Reduction of environmental implications
• 刊名：Environmental Earth Sciences
• 出版年：2016
• 出版时间：April 2016
• 年：2016
• 卷：75
• 期：7
• 全文大小：432 KB
• 参考文献：Aggarwal S, Gupta N (2015) Applications of mathematical programming models for product mix optimization in world steel industry: challenges and directions. Managing in Recovering Markets. pp. 133–142
  Ahmaruzzaman M (2010) A review on the utilization of fly ash. Prog Energy Combust Sci 36(3):327–363CrossRef
  Allegre CJ, Schneider SH (1994) The evolution of the Earth. Sci Am 271:44–51CrossRef
  Altas L, Buyukgungor H (2008) Sulfide removal in petroleum refinery wastewater by chemical precipitation. J Hazard Mater 153(1–2):462–469CrossRef
  Baciocchi R, Costa G, Di Bartolomeo E, Polettini A, Pomi R (2010) Carbonation of stainless steel slag as a process for CO2 storage and slag valorization. Waste Biomass Valoriz 1(4):467–477CrossRef
  Baciocchi R, Costa G, Polettini A, Pomi R (2015) Effects of thin-film accelerated carbonation on steel slag leaching. J Hazard Mater 286:369–378CrossRef
  Béarat H, McKelvy MJ, Chizmeshya AVG, Gormley D, Nunez R, Carpenter RW, Squires K, Wolf GH (2006) Carbon sequestration via aqueous olivine mineral carbonation: role of passivating layer formation. Environ Sci Technol 40(15):4802–4808CrossRef
  Berndt ME, Allen DE, Seyfried WE (1996) Reduction of CO2 during serpentinization of olivine at 300 °C and 500 bar. Geology 24(4):351–354CrossRef
  Bonenfant D, Kharoune L, Sauvé S, Hausler R, Niquette P, Mimeault M, Kharoune M (2008) CO2 sequestration by aqueous red mud carbonation at ambient pressure and temperature. Ind Eng Chem Res 47(20):7617–7622CrossRef
  Çengeloğlu Y, Kır E, Ersöz M (2002) Removal of fluoride from aqueous solution by using red mud. Sep Purif Technol 28(1):81–86CrossRef
  Cheng J, Zhou JH, Liu JZ, Cao XY, Cen KF (2009) Physicochemical characterizations and desulfurization properties in coal combustion of three calcium and sodium industrial wastes. Energy Fuels 23(5):2506–2516CrossRef
  Clechenko CC, Valley JW (2003) Oscillatory zoning in garnet from the Willsboro wollastonite skarn, Adirondack Mts, New York: a record of shallow hydrothermal processes preserved in a granulite facies terrane. J Metamorph Geol 21(8):771–784CrossRef
  Dalton JA, Presnall DC (1998) Carbonatitic melts along the solidus of model lherzolite in the system CaO–MgO–Al2O3–SiO2–CO2 from 3 to 7 GPa. Contrib Miner Petrol 131(2–3):123–135CrossRef
  Dare SAS, Barnes S-J, Prichard HM, Fisher PC (2010) The timing and formation of platinum-group minerals from the Creighton Ni-Cu-platinum-group element sulfide deposit, Sudbury, Canada: early crystallization of PGE-rich sulfarsenides. Econ Geol 105(6):1071–1096CrossRef
  Deng BL, Liu XX, Yang XM, Pan YN (2015) Application of salt mud in sewage treatment. China Chlor-Alkali (2):35–36 (in Chinese)
  Editors (2015a) New technology generates electricity from CO2 mineralization. Nature news, p 22
  Editors (2015b) 2014 China Science annual newsmaker, Xie Heping. ScienceNet.cn (in Chinese)
  Eggler DH (1978) The effect of CO2 upon partial melting of peridotite in the system Na2O–CaO–Al2O3–MgO–SiO2–CO2 to 35 kb, with an analysis of melting in a peridotite–H2O–CO2 system. Am J Sci 278(3):305–343CrossRef
  Einaudi MT, Burt DM (1982) Introduction, terminology, classification, and composition of skarn deposits. Econ Geol 77(4):745–754CrossRef
  Fan XD, Li HX, Ji HY, Zhang XK (2015) Advanced treatment of dye wastewater by biological activated carbon and biological toxicity characterization. Chin J Environ Eng 9(1):188–194 (in Chinese)
  Hövelmann J, Putnis CV, Austrheim H, Ruiz-Agudo E (2012) Direct nanoscale observations of CO2 sequestration during brucite [Mg(OH)2] dissolution. Environ Sci Technol 46(9):5253–5260CrossRef
  Hu XJ, Lei LC, Chen GH, Yue PL (2001) On the degradability of printing and dyeing wastewater by wet air oxidation. Water Res 35(8):2078–2080CrossRef
  Jiang XJ, Lin XH, Yao D, Zhai SK, Guo WD (2007) Geochemistry of lithium in marine ferromanganese oxide deposits. Deep Sea Res Part I 54(1):85–98CrossRef
  John MGS, Bagatto G, Behan-Pelletier V, Lindquist EE, Shorthouse JD, Smith IM (2002) Mite (Acari) colonization of vegetated mine tailings near Sudbury, Ontario, Canada. Plant Soil 245(2):295–305CrossRef
  Kasai E (2015) Recent resource and environmental issues in the steel industry. Topical Themes in Energy and Resources. Springer, pp. 215–227
  Keith ML (1946) Brucite deposits in the Rutherglen district, Ontario. Geol Soc Am Bull 57(10):967–984CrossRef
  Kirby CS, Rimstidt JD (1993) Mineralogy and surface properties of municipal solid waste ash. Environ Sci Technol 27(4):652–660CrossRef
  Kolbe JL, Lee LS, Jafvert CT, Murarka IP (2011) Use of alkaline coal ash for reclamation of a former strip mine, World of Coal Ash (WOCA) Conference, USA, pp 1–15
  Koukouzas N, Hämäläinen J, Papanikolaou D, Tourunen A, Jäntti T (2007) Mineralogical and elemental composition of fly ash from pilot scale fluidised bed combustion of lignite, bituminous coal, wood chips and their blends. Fuel 86(14):2186–2193CrossRef
  Li FS, Wang XJ (2015) Pollution and treatment of mercury in calcium based PVC production. Polyvinyl Chloride 43(4):35–39 (in Chinese)
  Li XM, Bertos MF, Hills CD, Carey PJ, Simon S (2007) Accelerated carbonation of municipal solid waste incineration fly ashes. Waste Manag 27(9):1200–1206CrossRef
  Li ZW, Li W, Bai ZQ, Li BQ (2010) Sequest ration of carbon dioxide with olivine promoted by an elect rochemical method. J China Univ Ming Technol 39(2):38–42
  Li YJ, Liu CT, Sun RY, Liu HL, Wu SM, Lu CM (2012) Sequential SO2/CO2 capture of calcium-based solid waste from the paper industry in the calcium looping process. Ind Eng Chem Res 51(49):16042–16048CrossRef
  Liang H (2007) Activity effect of fly ash. Central South Univeristy, Changsha (in Chinese)
  Liu XY, Ding CX, Chu PK (2004) Mechanism of apatite formation on wollastonite coatings in simulated body fluids. Biomaterials 25(10):1755–1761CrossRef
  Liu Z, Guan D, Wei W, Davis SJ, Ciais P, Bai J, Peng S, Zhang Q, Hubacek K, Marland G, Andres RJ, Crawford-Brown D, Lin J, Zhao H, Hong C, Boden TA, Feng K, Peters GP, Xi F, Liu J, Li Y, Zhao Y, Zeng N, He K (2015) Reduced carbon emission estimates from fossil fuel combustion and cement production in China. Nature 524(7565):335–338CrossRef
  Lockwood CL, Stewart DI, Mortimer RJG, Mayes WM, Jarvis AP, Gruiz K, Burke IT (2015) Leaching of copper and nickel in soil-water systems contaminated by bauxite residue (red mud) from Ajka, Hungary: the importance of soil organic matter. Environmental Science and Pollution Research 22(14):10800–10810CrossRef
  Lopez E, Soto B, Arias M, Nunez A, Rubinos D, Barral MT (1998) Adsorbent properties of red mud and its use for wastewater treatment. Water Res 32(4):1314–1322CrossRef
  McKelvy MJ, Bearat H, Chizmeshya AVG, Nunez R, Carpenter RW (2003). Understanding olivine CO2 mineral sequestration mechanisms at the atomic level: Optimizing reaction process design, Arizona State University (US)
  Meng XL, Liu DS (2014) Develop polyvinyl chloride to revive chlor alkali industry. China Chlor-Alkali 10:16–19 (in Chinese)
  Meyer NA, Vögeli JU, Becker M, Broadhurst JL, Reid DL, Franzidis JP (2014) Mineral carbonation of PGM mine tailings for CO2 storage in South Africa: a case study. Miner Eng 59:45–51CrossRef
  Monger HC, Kraimer RA, Cole DR, Wang XJ, Wang JP (2015) Sequestration of inorganic carbon in soil and groundwater. Geology 43(5):375–378CrossRef
  Morfeldt J, Nijs W, Silveira S (2015) The impact of climate targets on future steel production-an analysis based on a global energy system model. Journal of Cleaner Production 103:469–482CrossRef
  Ni SJ (2014) Scientists for the first time developed a carbon mineralization generation technology (in Chinese), China Science Daily. China Science Daily press, Beijing
  Niu SL, Liu MQ, Lu CM, Li H, Huo MJ (2014) Thermogravimetric analysis of carbide slag. J Therm Anal Calorim 115(1):73–79CrossRef
  Olsson J, Bovet N, Makovicky E, Bechgaard K, Balogh Z, Stipp SLS (2012) Olivine reactivity with CO2 and H2O on a microscale: implications for carbon sequestration. Geochim Cosmochim Acta 77:86–97CrossRef
  Pascual J, Corpas FA, López-Beceiro J, Benítez-Guerrero M, Artiaga R (2009) Themal characterization of a spanish red mud. J Therm Anal Calorim 96(2):407–412CrossRef
  Peuble S, Andreani M, Godard M, Gouze P, Barou F, Van de Moortele B, Mainprice D, Reynard B (2015) Carbonate mineralization in percolated olivine aggregates: linking effects of crystallographic orientation and fluid flow. Am Mineral 100(2–3):474–482CrossRef
  Power G, Gräfe M, Klauber C (2011) Bauxite residue issues: I. Current management, disposal and storage practices. Hydrometallurgy 108(1–2):33–45CrossRef
  Qin YH, Chen Y, Fu J (2014) The importance and Application of papermaking wastewater treatment. Technol Mark 21(4):228–229 (in Chinese)
  Rigopoulos I, Petallidou KC, Vasiliades MA, Delimitis A, Ioannou I, Efstathiou AM, Kyratsi T (2015) Carbon dioxide storage in olivine basalts: effect of ball milling process. Powder Technol 273:220–229CrossRef
  Schaef HT, Windisch CF, McGrail BP, Martin PF, Rosso KM (2011) Brucite [Mg(OH2)] carbonation in wet supercritical CO2: an in situ high pressure X-ray diffraction study. Geochim Cosmochim Acta 75(23):7458–7471CrossRef
  Schuiling RD, Krijgsman P (2006) Enhanced weathering: an effective and cheap tool to sequester CO2. Clim Change 74(1–3):349–354CrossRef
  Seifritz W (1990) CO2 disposal by means of silicates. Nature 345:486CrossRef
  Sheng XF, Ji JF, Chen J (2011) Assessment of carbon dioxide sequestration potential of ultramific rocks in China. Quat Sci 31(3):447–454 (in Chinese)
  Shi CJ (2004) Steel slag-its production, processing, characteristics, and cementitious properties. J Mater Civ Eng 16(3):230–236CrossRef
  Shih PH, Wu ZZ, Chiang HL (2004) Characteristics of bricks made from waste steel slag. Waste Manag 24(10):1043–1047CrossRef
  Shimizu T, Hirama T, Hosoda H, Kitano K, Inagaki M, Tejima K (1999) A twin fluid-bed reactor for removal of CO2 from combustion processes. Chem Eng Res Des 77(1):62–68CrossRef
  Simandl GJ, Paradis S, Irvine M (2007) Brucite-industrial mineral with a future. Geosci Can 34(2)
  Singh M, Upadhayay SN, Prasad PM (1996) Preparation of special cements from red mud. Waste Manag 16(8):665–670CrossRef
  Sun RY (2013) Investigation on CO2 capture behavior and attrition characteristics of calcium-based industrial waste during calcination/carbonation cycles. Shandong University, Jinan (in Chinese)
  Sun Y, Zhang YB, Quan X (2008) Treatment of petroleum refinery wastewater by microwave-assisted catalytic wet air oxidation under low temperature and low pressure. Sep Purif Technol 62(3):565–570CrossRef
  Sun RY, Li YJ, Liu CT, Xie X, Lu CM (2013) Utilization of lime mud from paper mill as CO2 sorbent in calcium looping process. Chem Eng J 221:124–132CrossRef
  Swift RS (2001) Sequestration of carbon by soil. Soil Sci 166(11):858–871CrossRef
  Tai CY, Chen WR, Shih SM (2006) Factors affecting wollastonite carbonation under CO2 supercritical conditions. AIChE J 52(1):292–299CrossRef
  Vogeli J, Reid DL, Becker M, Broadhurst J, Franzidis JP (2011) Investigation of the potential for mineral carbonation of PGM tailings in South Africa. Miner Eng 24(12):1348–1356CrossRef
  Wang HL, Liu GS, Li P, Pan F (2006) The effect of bioaugmentation on the performance of sequencing batch reactor and sludge characteristics in the treatment process of papermaking wastewater. Bioprocess Biosyst Eng 29(5–6):283–289
  Wilson I (2007) Brucite bonanza. Ind Miner 481:74–79
  World-Steel-Association (2013) Steel statistical yearbook 2013. World Steel Association, Brussels
  World-Steel-Association (2014) Steel statistical yearbook 2014. Wold Steel Association, Brussels
  Wu HF, Wang SH, Kong HL, Liu TT, Xia MF (2007a) Performance of combined process of anoxic baffled reactor-biological contact oxidation treating printing and dyeing wastewater. Bioresour Technol 98(7):1501–1504CrossRef
  Wu SP, Xue YJ, Ye QS, Chen YC (2007b) Utilization of steel slag as aggregates for stone mastic asphalt (SMA) mixtures. Build Environ 42(7):2580–2585CrossRef
  Xie HP, Wang YF, He Y, Gou ML, Liu T, Wang JL, Tang L, Jiang W, Zhang R, Xie LZ, Liang B (2014) Generation of electricity from CO2 mineralization: principle and realization. Sci China Technol Sci 57(12):2335–2343CrossRef
  Xie HP, Jiang W, Wang YF, Liu T, Wang RL, Liang B, He Y, Wang JL, Tang L, Chen JW (2015a) Thermodynamics study on the generation of electricity via CO2-mineralization cell. Environ Earth Sci. doi:10.​1007/​s12665-015-4731-x
  Xie HP, Jiang W, Xue Y, Hou ZM, Wang YF, Wu DL, Liu T, Wang JL, Tang L (2015b) Effect of water on carbonation of mineral aerosol surface models of kaolinite: a density functional theory study. Environ Earth Sci 73(11):7053–7060CrossRef
  Xie HP, Liu T, Hou ZM, Wang YF, Wang JL, Tang L, Jiang W, He Y (2015c) Using electrochemical process to mineralize CO2 and separate Ca2+/Mg2+ ions from hard water to produce high value-added carbonates. Environ Earth Sci 73(11):6881–6890CrossRef
  Xu Q (2014) Municipal solid waste incineration bottomashes properties research and embankment model test (in Chinese). Hubei University of Technology, Wuhan
  Yadav VS, Prasad M, Khan J, Amritphale SS, Singh M, Raju CB (2010) Sequestration of carbon dioxide (CO2) using red mud. J Hazard Mater 176(1–3):1044–1050CrossRef
  Yan K, Zhou KG (2008) Research on the utilization of calcium carbide residue. Environ Sci Surv 1(1):52–54
  Yan L, Ma HZ, Wang B, Mao W, Chen YS (2010) Advanced purification of petroleum refinery wastewater by catalytic vacuum distillation. J Hazard Mater 178(1–3):1120–1124CrossRef
  Yao ZT, Ji XS, Sarker PK, Tang JH, Ge LQ, Xia MS, Xi YQ (2015) A comprehensive review on the applications of coal fly ash. Earth Sci Rev 141:105–121CrossRef
  Zhang YK, Kang CH, Li X, Ye Z (2001) The treatment and reutilization of carbide slag. Polyvinyl Chloride 1:52–54 (in Chinese)
  Zhao YM (1991) Skarn deposits in the circum-pacific belt. Miner Depos 10(1):41–50 (in Chinese)
  Zhao L, Sang LQ, Chen J, Ji JF, Teng HH (2010) Aqueous carbonation of natural brucite: relevance to CO2 sequestration. Environ Sci Technol 44(1):406–411CrossRef
  Zharikov VA, Pertsev NN, Rusinov VL, Callegari E, Fettes DJ (1998) Metasomatism and metasomatic rocks. Systematics of Metamorphic Rocks
  Zhu MX, Lee L, Wang HH, Wang Z (2007) Removal of an anionic dye by adsorption/precipitation processes using alkaline white mud. J Hazard Mater 149(3):735–741CrossRef
  
• 作者单位：Heping Xie (1) (2)
  Liang Tang (1) (2)
  Yufei Wang (2)
  Tao Liu (2) (3)
  Zhengmeng Hou (4) (6)
  Jinlong Wang (2) (3)
  Tao Wang (5)
  Wen Jiang (2) (7)
  Patrick Were (8)
  
  1. College of Water Resource and Hydropower, Sichuan University, Chengdu, 610065, China
  2. Center of CO2 Mineralization and CCUS, Sichuan University, Chengdu, 610065, China
  3. College of Chemical Engineering, Sichuan University, Chengdu, 610065, China
  4. Key Laboratory of Energy Engineering Safety and Mechanics on Disasters, The Ministry of Education, Sichuan University, Chengdu, 610065, China
  6. Institute of Petroleum Engineering, Clausthal University of Technology, 38678, Clausthal-Zellerfeld, Germany
  5. College of Earth Sciences, Chengdu University of Technology, Chengdu, 610059, China
  7. College of Chemistry, Sichuan University, Chengdu, 610065, China
  8. Energy Research Center of Lower Saxony, Clausthal University of Technology, 38640, Goslar, Germany
  
• 刊物类别：Earth and Environmental Science
• 刊物主题：None Assigned
• 出版者：Springer Berlin Heidelberg
• ISSN：1866-6299

文摘

A tremendous amount of CO₂ has been released into the atmosphere over the past two centuries as a result of excessive use of fossil fuels. A variety of methods to reduce CO₂ emissions into the atmosphere have been proposed, but none of them so far has attained a concrete breakthrough. Developing new technologies using CO₂ and industrial alkaline wastes as alternatives to petroleum-based feedstocks may offer attractive opportunities to reduce both the greenhouse gas emissions and the reliance on petroleum derivatives for production of important base chemical commodities. Recently, a novel technique about harvesting electricity from CO₂ mineralization was proposed by our group based on the principle that chemical energy released from CO₂ mineralization process can be converted into electricity in addition to some high value chemical products of the reaction. However, this technology brings into question a number of issues including the chemical mechanisms taking place in the system, the availability of adequate mineralizing feedstocks for harvesting electricity, the quantity of CO₂ that can be sequestered, and the quantity of electricity that can be generated by the CO₂ mineralization process. A detailed investigation of the CO₂ mineralization was conducted including a study of the required raw materials herein classified as alkali and alkaline minerals, industrial alkaline solid wastes and waste water. The great significance of environmental implications estimates that approximately 10492.32 million tons and 150.35 million tons of CO₂ can be mineralized worldwide and in China, respectively. In other words, annually 250.94 and 147.71 million tons of CO₂ can be sequestered worldwide and in China, respectively. Accordingly, the total amount of electricity produced will reach 2687.03 and 40.50 billion kWh worldwide and in China, respectively, i.e., 69.33 billion kWh worldwide and 39.94 billion kWh in China, annually.