This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Koleva DA, Hu J, Fraaij ALA, Stroeven P, Boshkov N, de Wit JHW. Quantitative characterisation of steel/cement paste interface microstructure and corrosion phenomena in mortars suffering from chloride attack. Corros Sci. 2006 Dec 1;48(12):4001–19.KolevaDAHuJFraaijALAStroevenPBoshkovNde WitJHW.Quantitative characterisation of steel/cement paste interface microstructure and corrosion phenomena in mortars suffering from chloride attack. . 2006Dec1;48(12):4001–19.Search in Google Scholar
Dalla Vecchia F, dos Santos VHJM, Schütz MK, Ponzi GGD, Stepanha ASdGe, Malfatti C de F, et al. Wellbore integrity in a saline aquifer: experimental steel-cement interface degradation under supercritical CO2 conditions representative of Brazil’s Parana basin. Int J Greenhouse Gas Control. 2020 Jul 1;98:103077.Dalla VecchiaFdos SantosVHJMSchützMKPonziGGDStepanhaASdGeMalfattiC de FWellbore integrity in a saline aquifer: experimental steel-cement interface degradation under supercritical CO2 conditions representative of Brazil’s Parana basin. . 2020Jul1;98:103077.Search in Google Scholar
Feng J, Wang ZM, Zheng D, Song GL. The localized corrosion of mild steel in carbonated cement pore solution under supercritical carbon dioxide in a simulated geothermal environment. Constr Build Mater. 2021 Mar 8;274:122035.FengJWangZMZhengDSongGL.The localized corrosion of mild steel in carbonated cement pore solution under supercritical carbon dioxide in a simulated geothermal environment. . 2021Mar8;274:122035.Search in Google Scholar
Tremosa J, Mito S, Audigane P, Xue Z. Experimental assessment of well integrity for CO2 geological storage: a numerical study of the geochemical interactions between a CO2-brine mixture and a sandstone-cement-steel sample. Appl Geochem. 2017 Mar 1;78:61–73.TremosaJMitoSAudiganePXueZ.Experimental assessment of well integrity for CO2 geological storage: a numerical study of the geochemical interactions between a CO2-brine mixture and a sandstone-cement-steel sample. . 2017Mar1;78:61–73.Search in Google Scholar
Mito S, Xue Z, Satoh H. Experimental assessment of well integrity for CO2 geological storage: batch experimental results on geochemical interactions between a CO2 -brine mixture and a sandstone-cement-steel sample. Int J Greenhouse Gas Control. 2015 Aug 1;39: 420–31.MitoSXueZSatohH.Experimental assessment of well integrity for CO2 geological storage: batch experimental results on geochemical interactions between a CO2 -brine mixture and a sandstone-cement-steel sample. . 2015Aug1;39: 420–31.Search in Google Scholar
Nakano K, Ohbuchi A, Mito S, Xue Z. Chemical interaction of well composite samples with supercritical CO2 along the cement - sandstone interface. Energy Procedia. 2014 Jan 1;63:5754–61.NakanoKOhbuchiAMitoSXueZ.Chemical interaction of well composite samples with supercritical CO2 along the cement - sandstone interface. . 2014Jan1;63:5754–61.Search in Google Scholar
Loizzo M, Bressers P, Benedictus T, Le Guen Y, Poupard O. Assessing CO2 interaction with cement and steel over a two-year injection period: current state and future risks for the MovECBM project in Poland. Energy Procedia. 2009 Feb 1;1(1):3579–86.LoizzoMBressersPBenedictusTLe GuenYPoupardO.Assessing CO2 interaction with cement and steel over a two-year injection period: current state and future risks for the MovECBM project in Poland. . 2009Feb1;1(1):3579–86.Search in Google Scholar
Carey JW, Lichtner PC. Computational studies of two-phase cement/CO2/brine interaction in wellbore environments. SPE J. 2011;16(04):940–8.CareyJWLichtnerPC.Computational studies of two-phase cement/CO2/brine interaction in wellbore environments. . 2011;16(04):940–8.Search in Google Scholar
Li D, Duan Z. The speciation equilibrium coupling with phase equilibrium in the H2O–CO2–NaCl system from 0 to 250°C, from 0 to 1000 bar, and from 0 to 5 molality of NaCl. Chem Geol. 2007;244(3–4):730–51.LiDDuanZ.The speciation equilibrium coupling with phase equilibrium in the H2O–CO2–NaCl system from 0 to 250°C from 0 to 1000 bar, and from 0 to 5 molality of NaCl. . 2007;244(3-4):730–51.Search in Google Scholar
Glasser FP, Marchand J, Samson E. Durability of concrete-degradation phenomena involving detrimental chemical reactions. Cem Concr Res. 2008;38(2): 226–46.GlasserFPMarchandJSamsonE.Durability of concrete-degradation phenomena involving detrimental chemical reactions. . 2008;38(2): 226–46.Search in Google Scholar
Schmitt G. Fundamental aspects of CO2 metal loss corrosion. Part II: influence of different parameters on CO2 corrosion mechanism. 2015;139–43. url: https://api.semanticscholar.org/CorpusID:93849534SchmittG.Fundamental aspects of CO2 metal loss corrosion. . 2015;139–43. url: https://api.semanticscholar.org/CorpusID:93849534Search in Google Scholar
Kermani M, Morshed A. Carbon dioxide corrosion in oil and gas productiona compendium. Corrosion. 2003;59(08).KermaniMMorshedA.Carbon dioxide corrosion in oil and gas productiona compendium. . 2003;59(08).Search in Google Scholar
Xiao T, McPherson B, Bordelon A, Viswanathan H, Dai Z, Tian H, et al. Quantification of CO2-cement-rock interactions at the well-caprock-reservoir interface and implications for geological CO2 storage. Int J Green-house Gas Control. 2017 Aug 1;63:126–40.XiaoTMcPhersonBBordelonAViswanathanHDaiZTianHQuantification of CO2-cement-rock interactions at the well-caprock-reservoir interface and implications for geological CO2 storage. . 2017Aug1;63:126–40.Search in Google Scholar
Castellote M, Fernandez L, Andrade C, Alonso C. Chemical changes and phase analysis of OPC pastes carbonated at different CO2 concentrations. Mater Struct. 2009;42:515–25.CastelloteMFernandezLAndradeCAlonsoC.Chemical changes and phase analysis of OPC pastes carbonated at different CO2 concentrations. . 2009;42:515–25.Search in Google Scholar
Morandeau A, Thiery M, Dangla P. Investigation of the carbonation mechanism of CH and CSH in terms of kinetics, microstructure changes and moisture properties. Cem Concr Res. 2014;56:153–70.MorandeauAThieryMDanglaP.Investigation of the carbonation mechanism of CH and CSH in terms of kinetics, microstructure changes and moisture properties. . 2014;56:153–70.Search in Google Scholar
Silva DA, Monteiro PJ. The influence of polymers on the hydration of portland cement phases analyzed by soft X-ray transmission microscopy. Cem Concr Rese. 2006;36(8):1501–7.SilvaDAMonteiroPJ.The influence of polymers on the hydration of portland cement phases analyzed by soft X-ray transmission microscopy. . 2006;36(8):1501–7.Search in Google Scholar
Omosebi O, Maheshwari H, Ahmed R, Shah S, Osisanya S, Hassani S, et al. Degradation of well cement in HPHT acidic environment: effects of CO2 concentration and pressure. Cem Concr Compos. 2016 Nov 1;74:54–70.OmosebiOMaheshwariHAhmedRShahSOsisanyaSHassaniSDegradation of well cement in HPHT acidic environment: effects of CO2 concentration and pressure. . 2016Nov1;74:54–70.Search in Google Scholar
Tiong M, Gholami R, Rahman ME. Cement degradation in CO2 storage sites: a review on potential applications of nanomaterials. J Petrol Explor Prod Technol. 2019 Mar 1;9(1):329–40.TiongMGholamiRRahmanME.Cement degradation in CO2 storage sites: a review on potential applications of nanomaterials. . 2019Mar1;9(1):329–40.Search in Google Scholar
William Carey J, Svec R, Grigg R, Zhang J, Crow W. Experimental investigation of wellbore integrity and CO2–brine flow along the casing–cement microannulus. Int J Greenhouse Gas Control. 2010 Mar 1;4(2):272–82.William CareyJSvecRGriggRZhangJCrowW.Experimental investigation of wellbore integrity and CO2–brine flow along the casing–cement microannulus. . 2010Mar1;4(2):272–82.Search in Google Scholar
Abdallah S, Fan M, Rees DW. Bonding mechanisms and strength of steel fiber-reinforced cementitious composites: overview. J Mater Civil Eng. 2018;30(3):04018001.AbdallahSFanMReesDW.Bonding mechanisms and strength of steel fiber-reinforced cementitious composites: overview. . 2018;30(3):04018001.Search in Google Scholar
Hawreen A, Bogas J. Influence of carbon nanotubes on steel–concrete bond strength. Mater Struct. 2018;51: 1–16.HawreenABogasJ.Influence of carbon nanotubes on steel–concrete bond strength. . 2018;51: 1–16.Search in Google Scholar
Carroll S, Carey JW, Dzombak D, Huerta NJ, Li L, Richard T, et al. Review: role of chemistry, mechanics, and transport on well integrity in CO2 storage environments. Int J Greenhouse Gas Control. 2016 Jun 1;49:149–60.CarrollSCareyJWDzombakDHuertaNJLiLRichardTReview: role of chemistry, mechanics, and transport on well integrity in CO2 storage environments. . 2016Jun1;49:149–60.Search in Google Scholar
William Carey J, Svec R, Grigg R, Lichtner PC, Zhang J, Crow W. Wellbore integrity and CO2 brine flow along the casing-cement microannulus. Energy Procedia. 2009 Feb 1;1(1):3609–15.William CareyJSvecRGriggRLichtnerPCZhangJCrowW.Wellbore integrity and CO2 brine flow along the casing-cement microannulus. . 2009Feb1;1(1):3609–15.Search in Google Scholar
Loizzo M, Lombardi S, Deremble L, Lecampion B, Quesada D, Huet B, et al. Monitoring CO2 migration in an injection well: evidence from MovECBM. Energy Procedia. 2011 Jan 1;4:5203–10.LoizzoMLombardiSDerembleLLecampionBQuesadaDHuetBMonitoring CO2 migration in an injection well: evidence from MovECBM. . 2011Jan1;4:5203–10.Search in Google Scholar
Hanor JS. Origin of saline fluids in sedimentary basins. Geol Soc London Spec Publ. 1994;78(1):151–74.HanorJS.Origin of saline fluids in sedimentary basins. . 1994;78(1):151–74.Search in Google Scholar
Zhao H, Dilmore R, Allen DE, Hedges SW, Soong Y, Lvov SN. Measurement and modeling of CO2 solubility in natural and synthetic formation brines for CO2 sequestration. Environ Sci Technol. 2015;49(3): 1972–80.ZhaoHDilmoreRAllenDEHedgesSWSoongYLvovSN.Measurement and modeling of CO2 solubility in natural and synthetic formation brines for CO2 sequestration. . 2015;49(3): 1972–80.Search in Google Scholar
Wang Z, Zhao Y, Liu M, Shen H, Fang Q, Yao J. Investigation of the effects of small flow rate and particle impact on high temperature CO2 corrosion of N80 steel. Corros Sci. 2022 Dec 1;209:110735.WangZZhaoYLiuMShenHFangQYaoJ.Investigation of the effects of small flow rate and particle impact on high temperature CO2 corrosion of N80 steel. . 2022Dec1;209:110735.Search in Google Scholar
Cui L, Kang W, You H, Cheng J, Li Z. Experimental study on corrosion of J55 casing steel and N80 tubing steel in high pressure and high temperature solution containing CO2 and NaCl. J Bio Tribo Corros. 2020 Nov 18;7(1):13.CuiLKangWYouHChengJLiZ.Experimental study on corrosion of J55 casing steel and N80 tubing steel in high pressure and high temperature solution containing CO2 and NaCl. . 2020Nov18;7(1):13.Search in Google Scholar
Uthaman S, Vishwakarma V, George RP, Ramachandran D, Kumari K, Preetha R, et al. Enhancement of strength and durability of fly ash concrete in seawater environments: synergistic effect of nanoparticles. Constr Build Mater. 2018 Oct 30;187:448–59.UthamanSVishwakarmaVGeorgeRPRamachandranDKumariKPreethaREnhancement of strength and durability of fly ash concrete in seawater environments: synergistic effect of nanoparticles. . 2018Oct30;187:448–59.Search in Google Scholar
Ramachandran D, Uthaman S, Vishwakarma V. Studies of carbonation process in nanoparticles modified fly ash concrete. Constr Build Mater. 2020 Aug 20;252: 119127.RamachandranDUthamanSVishwakarmaV.Studies of carbonation process in nanoparticles modified fly ash concrete. . 2020Aug20;252: 119127.Search in Google Scholar
Zhang GA, Liu D, Li YZ, Guo XP. Corrosion behaviour of N80 carbon steel in formation water under dynamic supercritical CO2 conditions. Corros Sci. 2017 May 15;120:107–20.ZhangGALiuDLiYZGuoXP.Corrosion behaviour of N80 carbon steel in formation water under dynamic supercritical CO2 conditions. . 2017May15;120:107–20.Search in Google Scholar
Liao K, Zhou F, Song X, Wang Y, Zhao S, Liang J, et al. Synergistic effect of O2 and H2S on the corrosion behavior of N80 steel in a simulated high-pressure flue gas injection system. J Mater Eng Perform. 2020 Jan 1;29(1):155–66.LiaoKZhouFSongXWangYZhaoSLiangJSynergistic effect of O2 and H2S on the corrosion behavior of N80 steel in a simulated high-pressure flue gas injection system. . 2020Jan1;29(1):155–66.Search in Google Scholar
Ren X, Lu Y, Wei Q, Yu L, Zhai K, Tang J, et al. The influence of Ca2+ on the growth mechanism of corrosion product film on N80 steel in CO2 corrosion environments. Corros Sci. 2023 Jul 1;218:111168.RenXLuYWeiQYuLZhaiKTangJThe influence of Ca2+ on the growth mechanism of corrosion product film on N80 steel in CO2 corrosion environments. . 2023Jul1;218:111168.Search in Google Scholar
Usman BJ, Umoren SA, Gasem ZM. Inhibition of API 5L X60 steel corrosion in CO2-saturated 3.5% NaCl solution by tannic acid and synergistic effect of KI additive. J Mol Liq. 2017 Jul 1;237:146–56.UsmanBJUmorenSAGasemZM.Inhibition of API 5L X60 steel corrosion in CO2-saturated 3.5% NaCl solution by tannic acid and synergistic effect of KI additive. . 2017Jul1;237:146–56.Search in Google Scholar
Xiang Y, Xie W, Ni S, He X. Comparative study of A106 steel corrosion in fresh and dirty MEA solutions during the CO2 capture process: Effect of NO3−\text{NO}_{3}^{-}. Corros Sci. 2020 May 1;167:108521.XiangYXieWNiSHeX.Comparative study of A106 steel corrosion in fresh and dirty MEA solutions during the CO2 capture process: Effect of NO3-. . 2020May1;167:108521.Search in Google Scholar
Peng Y, Hughes AE, Mardel JI, Deacon GB, Junk PC, Forsyth M, et al. Leaching behavior and corrosion inhibition of a rare earth carboxylate incorporated epoxy coating system. ACS Appl Mater Interfaces. 2019;11(39):36154–68.PengYHughesAEMardelJIDeaconGBJunkPCForsythMLeaching behavior and corrosion inhibition of a rare earth carboxylate incorporated epoxy coating system. . 2019;11(39):36154–68.Search in Google Scholar
Gurtubay L, Gallastegui G, Elias A, Rojo N, Barona A. Accelerated ageing of an EAF black slag by carbonation and percolation for long-term behaviour assessment. J Environ Manage. 2014;140:45–50.GurtubayLGallasteguiGEliasARojoNBaronaA.Accelerated ageing of an EAF black slag by carbonation and percolation for long-term behaviour assessment. . 2014;140:45–50.Search in Google Scholar