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AFm phases

January 01, 1970

An AFm phase is an "alumina, ferric oxide, monosubstituted" phase, or aluminate ferrite monosubstituted, or Al2O3, Fe2O3 mono, in cement chemist notation (CCN). AFm phases are important hydration products in the hydration of Portland cements and hydraulic cements.

They are crystalline hydrates with generic, simplified, formula 3CaO·(Al,Fe)2O3·CaXy·nH2O,
where:

  • CaO, Al2O3, Fe2O3 represent calcium oxide, aluminium oxide, and ferric oxide, respectively;
  • CaX represents a calcium salt, where X replaces an oxide ion;
  • X is the substituted anion in CaX:
    – divalent  (SO2−4, CO2−3…) with y = 1, or;
    – monovalent (OH, Cl…) with y = 2.
  • n represents the number of water molecules in the hydrate and may be comprised between 13 and 19.[1]

AFm form inter alia when tricalcium aluminate 3CaO·Al2O3, or C3A in CCN, reacts with dissolved calcium sulfate (CaSO4), or calcium carbonate (CaCO3). As the sulfate form is the dominant one in AFm phases in the hardened cement paste (HCP) in concrete, AFm is often simply referred to as Aluminate Ferrite monosulfate or calcium aluminate monosulfate. However, carbonate-AFm phases also exist (monocarbonate and hemicarbonate) and are thermodynamically more stable than the sulfate-AFm phase. During concrete carbonation by the atmospheric CO2, sulfate-AFm phase is also slowly transformed into carbonate-AFm phases.

Different AFm phases edit

AFm phases belong to the class of layered double hydroxides (LDH). LDHs are hydroxides with a double layer structure. The main cation is divalent (M2+) and its electrical charge is compensated by 2 OH anions: M(OH)2. Some M2+ cations are replaced by a trivalent one (N3+). This creates an excess of positive electrical charges which needs to be compensated by the same number of negative electrical charges born by anions. These anions are located in the space present in between adjacent hydroxide layers. The interlayers in LDHs are also occupied by water molecules accompanying the anions counterbalancing the excess of positive charges created by the cation isomorphic substitution in the hydroxides sheets.

In the most studied class of LDHs, the positive layer (c), consisting of divalent M2+ and trivalent N3+ cations, can be represented by the generic formula:

[M2+
1-xN3+
x(OH
)2]x+ [(Xn−)x/n · yH
2O]x-
where Xn− is the intercalating anion.

In AFm, the divalent cation is a calcium ion (Ca2+), while the substituting trivalent cation is an aluminium ion (Al3+). The nature of the counterbalancing anion (Xn−) can be very diverse: OH, Cl, SO2−4, CO2−3, NO3, NO2.[2][3][4] The thickness of the interlayer is sufficient to host a variety of relatively large anions often present as impurities: B(OH)4, SeO2−4, SeO2−3...[5][6] As other LDHs, AFm can incorporate in their structure toxic elements such as boron[5] and selenium.[6] Some AFm phases are presented in the table here below as a function of the nature of the anion counterbalancing the excess of positive charges in the Ca(OH)2 hydroxide sheets. As in portlandite (Ca(OH)2), the hydroxide sheets of AFm are made of hexa-coordinated octahedral cations located in a same plane, but due to the excess of positive electrical charges, the hydroxide sheets are distorted.

Different AFm phases as a function of the nature of the counterbalancing anion in the LDH structure and its stoichiometry
n Anion AFm name Oxide notation LDH formula Reference
  AFm-generic 3CaO·Al2O3·CaXy·nH2O Ca4Al2Xy(OH)12·(n− 6)H2O
  AFm-monohydrate 3CaO·Al2O3·Ca(OH)2·10H2O Ca4Al2(OH)14·4H2O Hydrocalumite (HBM)[7] (Mindat)[8]
  AFm-monosulfate 3CaO·Al2O3·CaSO4·12H2O Ca4Al2(SO4)(OH)12·6H2O Divet (2000)[9]
  AFm-monocarbonate 3CaO·Al2O3·CaCO3·11H2O Ca4Al2(CO3)(OH)12·5H2O Divet (2000)[9]
  AFm-hemicarbonate 3CaO·Al2O3·½CaCO3·½Ca(OH)2·11.5H2O Ca4Al2(CO3)½(OH)13·5.5H2O Divet (2000)[9]
  Friedel's salt 3CaO·Al2O3·CaCl2·10H2O Ca4Al2Cl2(OH)12·4H2O Friedel (1897)[2]
  Kuzel's salts 3CaO·Al2O3·½CaSO4·½CaCl2·11H2O Ca4Al2(SO4)½Cl(OH)12·5H2O Glasser (1999)[3]
  AFm-nitrate 3CaO·Al2O3·Ca(NO3)2·10H2O Ca4Al2(NO3)2(OH)12·4H2O Balonis & Glasser (2011)[4]
  AFm-nitrite 3CaO·Al2O3·Ca(NO2)2·10H2O Ca4Al2(NO2)2(OH)12·4H2O Balonis & Glasser (2011)[4]

To convert the oxide notation in LDH formula, the mass balance in the system has to respect the principle of the conservation of matter. Oxide ions (O2−) and water are transformed into 2 hydroxide anions (OH) according to the acid-base reaction between H2O and O2− (a strong base) as typically exemplified by the quicklime (CaO) slaking process:

H2O + O2− ⇌ OH + OH,
A1 + B2 ⇌ B1 + A2
or simply,
O2− + H2O ⇌ 2 OH

AFm structure edit

AFm phases encompass a class of calcium aluminate hydrates (C-A-H) whose structure derives from that of hydrocalumite:[7][8] 4CaO·Al2O3·13–19H2O, in which OH anions are partly replaced by SO2−4 or CO2−3 anions.[8] The different mineral phases resulting from these anionic substitutions do not easily form solid solutions but behave as independent phases. The replacement of hydroxide ions by sulfate ions does not exceed 50 mol %. So, AFm does not refer to a single pure mineralogical phase but rather to a mix of several AFm phases co-existing in hydrated cement paste (HCP).[1]

Considering a monovalent anion X, the chemical formula can be rearranged and expressed as 2[Ca2(Al,Fe)(OH)6]·X·nH2O (or Ca4(Al,Fe)2(OH)12·X·nH2O, as presented in the table in the former section). The Me(OH)6 octahedral ions are located in a plane as for calcium or magnesium hydroxides in portlandite or brucite hexagonal sheets respectively. The replacement of one divalent Ca2+ cation by a trivalent Al3+ cation, or to a lesser extent by a Fe3+ cation, with a Ca:Al ratio of 2:1 (one Al substituted for every 3 cations) causes an excess of positive charge in the sheet: 2[2Ca(OH)2·(Al,Fe)(OH)2]+ to be compensated by 2 negative charges X. The anions X counterbalancing the positive charge imbalance born by the sheet are located in the interlayer whose spacing is much larger than in the layered structure of brucite or portlandite. This allows the AFm structure to accommodate larger anionic species along with water molecules.[1]

The crystal structure of AFm phases is that of layered double hydroxide (LDH) and AFm phases also exhibit the same anion exchange properties. The carbonate anion (CO2−3) occupies the interlayer space in a privileged way with the highest selectivity coefficient and is more retained in the interlayer than other divalent or monovalent anions such as SO2−4 or OH.

According to Miyata (1983),[10] the equilibrium constant (selectivity coefficient) for anion exchange varies in the order CO2−3 > HPO2−4 > SO2−4 for divalent anions, and OH > F > Cl > Br > NO3 > I for monovalent anions, but this order is not universal and varies with the nature of the LDH.

Thermodynamic stability edit

The thermodynamic stability of AFm phases studied at 25 °C depends on the nature of the anion present in the interlayer: CO2−3 stabilises AFm and displaces OH and SO2−4 anions at their concentrations typically found in hardened cement paste (HCP).[1] Different sources of carbonate can contribute to the carbonation of AFm phases:[1] Addition of limestone filler finely ground, atmospheric CO2, carbonate present as impurity in the gypsum interground with the clinker to avoid cement flash setting, and "alkali sulfates" condensed onto clinker during its cooling, or from added clinker kiln dust.[1] Carbonation can rapidly occur within the fresh concrete during its setting and hardening (internal carbonate sources), or slowly continue in the long-term in the hardened cement paste in concrete exposed to external sources of carbonate: CO2 from the air, or bicarbonate anion (HCO3) present in groundwater (immersed structures) or clay porewater (foundations and underground structures).

When the carbonate concentration increases in the hardened cement paste (HCP), hydroxy-AFm are progressively replaced, first by hemicarboaluminate and then by monocarboaluminate. The stability of AFm phases increases with their carbonate content as shown by Damidot and Glasser (1995) by means of their thermodynamic calculations of the CaO-Al2O3-SiO2-H2O system at 25 °C.[1][11]

When carbonate displaces sulfate from AFm, the sulfate released in the concrete pore water may react with portlandite (Ca(OH)2) to form ettringite (3CaO·Al2O3·3CaSO4·32H2O), the main AFt phase present in the hydrated cement system.[1]

As stressed by Matschei et al. (2007), the impact of small amounts of carbonate on the nature and stability of the AFm phases is noteworthy.[1] Divet (2000) also notes that micromolar amount of carbonate can inhibit the formation of AFm sulfate, favoring so the crystallisation of ettringite (AFt sulfate).[9]

See also edit

References edit

  1. ^ a b c d e f g h i Matschei, T.; Lothenbach, B.; Glasser, F. P. (2007-02-01). "The AFm phase in Portland cement". Cement and Concrete Research. 37 (2): 118–130. doi:10.1016/j.cemconres.2006.10.010. ISSN 0008-8846. Retrieved 2022-02-10.
  2. ^ a b Friedel, Georges (1897). "Sur un chloro-aluminate de calcium hydraté se maclant par compression". Bulletin de la Société Française de Minéralogie et de Cristallographie. 19: 122–136.
  3. ^ a b Glasser, F.P.; Kindness, A.; Stronach, S.A. (June 1999). "Stability and solubility relationships in AFm phases". Cement and Concrete Research. 29 (6): 861–866. doi:10.1016/S0008-8846(99)00055-1. ISSN 0008-8846.
  4. ^ a b c Balonis, Magdalena; Mędala, Marta; Glasser, Fredrik P. (July 2011). "Influence of calcium nitrate and nitrite on the constitution of AFm and AFt cement hydrates". Advances in Cement Research. 23 (3): 129–143. doi:10.1680/adcr.10.00002. eISSN 1751-7605. ISSN 0951-7197.
  5. ^ a b Champenois, Jean-Baptiste; Mesbah, Adel; Cau Dit Coumes, Céline; Renaudin, Guillaume; Leroux, Fabrice; Mercier, Cyrille; Revel, Bertrand; Damidot, Denis (October 2012). "Crystal structures of Boro-AFm and sBoro-AFt phases". Cement and Concrete Research. 42 (10): 1362–1370. doi:10.1016/j.cemconres.2012.06.003. ISSN 0008-8846.
  6. ^ a b Baur, Isabel; Johnson, C. Annette (November 2003). "The solubility of selenate-AFt (3CaO·Al2O3·3CaSeO4·37.5H2O) and selenate-AFm (3CaO·Al2O3·CaSeO4·xH2O)". Cement and Concrete Research. 33 (11): 1741–1748. doi:10.1016/S0008-8846(03)00151-0. ISSN 0008-8846.
  7. ^ a b Handbook of mineralogy (2005). "Hydrocalumite" (PDF). handbookofmineralogy.org. Retrieved 19 April 2023.
  8. ^ a b c Mindat (3 April 2023). "Hydrocalumite". mindat.org. Retrieved 19 April 2023.
  9. ^ a b c d Divet, Loïc (2000). "Etat des connaissances sur les causes possibles des réactions sulfatiques internes au béton" (PDF). Bulletin de Liaison des Laboratoires des Ponts et Chaussées. 227: 71–84.
  10. ^ Miyata, Shigeo (1983-08-01). "Anion-exchange properties of hydrotalcite-like compounds". Clays and Clay Minerals. 31 (4): 305–311. Bibcode:1983CCM....31..305M. doi:10.1346/CCMN.1983.0310409. ISSN 1552-8367.
  11. ^ Damidot, D.; Glasser, F.P. (January 1995). "Investigation of the CaO-Al2O3-SiO2-H2O system at 25 °C by thermodynamic calculations". Cement and Concrete Research. 25 (1): 22–28. doi:10.1016/0008-8846(94)00108-B. ISSN 0008-8846.

Further reading edit

  • Baquerizo, Luis G.; Matschei, Thomas; Scrivener, Karen L.; Saeidpour, Mahsa; Wadsö, Lars (2015-07-01). "Hydration states of AFm cement phases". Cement and Concrete Research. 73: 143–157. doi:10.1016/j.cemconres.2015.02.011. ISSN 0008-8846.
  • Feng, Pan; Miao, Changwen; Bullard, Jeffrey W. (2016-03-01). "Factors influencing the stability of AFm and AFt in the Ca – Al – S – O – H System at 25 °C". Journal of the American Ceramic Society. 99 (3). R. Riman (ed.): 1031–1041. doi:10.1111/jace.13971. ISSN 1551-2916. PMC 4911640. PMID 27335503.
  • Galan, Isabel; Glasser, Fredrik P. (2015-02-01). "Chloride in cement". Advances in Cement Research. 27 (2): 63–97. doi:10.1680/adcr.13.00067. eISSN 1751-7605. ISSN 0951-7197.
  • Glasser, F.P.; Kindness, A.; Stronach, S.A. (June 1999). "Stability and solubility relationships in AFm phases". Cement and Concrete Research. 29 (6): 861–866. doi:10.1016/S0008-8846(99)00055-1. ISSN 0008-8846.
  • Hirao, Hiroshi; Yamada, Kazuo; Takahashi, Haruka; Zibara, Hassan (2005). "Chloride binding of cement estimated by binding isotherms of hydrates". Journal of Advanced Concrete Technology. 3 (1): 77–84. doi:10.3151/jact.3.77. eISSN 1347-3913. ISSN 1346-8014.
  • Matschei, T.; Lothenbach, B.; Glasser, F.P. (February 2007). "The AFm phase in Portland cement". Cement and Concrete Research. 37 (2): 118–130. doi:10.1016/j.cemconres.2006.10.010. ISSN 0008-8846.
  • Mesbah, Adel; Cau-dit-Coumes, Céline; Frizon, Fabien; Leroux, Fabrice; Ravaux, Johann; Renaudin, Guillaume (2011). "A new investigation of the Cl–CO32− substitution in AFm phases". Journal of the American Ceramic Society. 94 (6): 1901–1910. doi:10.1111/j.1551-2916.2010.04305.x. ISSN 1551-2916.
  • Mesbah, Adel; Cau-dit-Coumes, Céline; Renaudin, Guillaume; Frizon, Fabien; Leroux, Fabrice (2012-08-01). "Uptake of chloride and carbonate ions by calcium monosulfoaluminate hydrate". Cement and Concrete Research. 42 (8): 1157–1165. doi:10.1016/j.cemconres.2012.05.012. ISSN 0008-8846.
  • Mesbah, Adel; Rapin, Jean-Philippe; François, Michel; Cau-dit-Coumes, Céline; Frizon, Fabien; Leroux, Fabrice; Renaudin, Guillaume (2011). "Crystal structures and phase transition of cementitious bi-anionic AFm-(Cl, CO32−) compounds". Journal of the American Ceramic Society. 94 (1): 261–268. doi:10.1111/j.1551-2916.2010.04050.x. ISSN 1551-2916.
  • Nedyalkova, Latina; Tits, Jan; Renaudin, Guillaume; Wieland, Erich; Mäder, Urs; Lothenbach, Barbara (2022-02-15). "Mechanisms and thermodynamic modelling of iodide sorption on AFm phases". Journal of Colloid and Interface Science. 608 (Pt 1): 683–691. Bibcode:2022JCIS..608..683N. doi:10.1016/j.jcis.2021.09.104. ISSN 0021-9797. PMID 34634544. S2CID 238637368.
  • Terzis, A.; Filippakis, S.; Kuzel, Hans-Jürgen; Burzlaff, Hans (1 December 1987). "The crystal structure of Ca2Al(OH)6Cl · 2H2O". Zeitschrift für Kristallographie - Crystalline Materials. 181 (1–4): 29–34. doi:10.1524/zkri.1987.181.14.29. eISSN 2196-7105. ISSN 2194-4946. S2CID 102051376.

January 01, 1970
phases, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, news, newspapers, books, scholar, jstor, february, 2022, lea. This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources AFm phases news newspapers books scholar JSTOR February 2022 Learn how and when to remove this message An AFm phase is an alumina ferric oxide monosubstituted phase or aluminate ferrite monosubstituted or Al2O3 Fe2O3 mono in cement chemist notation CCN AFm phases are important hydration products in the hydration of Portland cements and hydraulic cements They are crystalline hydrates with generic simplified formula 3CaO Al Fe 2O3 CaXy nH2O where CaO Al2O3 Fe2O3 represent calcium oxide aluminium oxide and ferric oxide respectively CaX represents a calcium salt where X replaces an oxide ion X is the substituted anion in CaX divalent SO2 4 CO2 3 with y 1 or monovalent OH Cl with y 2 n represents the number of water molecules in the hydrate and may be comprised between 13 and 19 1 AFm form inter alia when tricalcium aluminate 3CaO Al2O3 or C3A in CCN reacts with dissolved calcium sulfate CaSO4 or calcium carbonate CaCO3 As the sulfate form is the dominant one in AFm phases in the hardened cement paste HCP in concrete AFm is often simply referred to as Aluminate Ferrite monosulfate or calcium aluminate monosulfate However carbonate AFm phases also exist monocarbonate and hemicarbonate and are thermodynamically more stable than the sulfate AFm phase During concrete carbonation by the atmospheric CO2 sulfate AFm phase is also slowly transformed into carbonate AFm phases Contents 1 Different AFm phases 2 AFm structure 3 Thermodynamic stability 4 See also 5 References 6 Further readingDifferent AFm phases editAFm phases belong to the class of layered double hydroxides LDH LDHs are hydroxides with a double layer structure The main cation is divalent M2 and its electrical charge is compensated by 2 OH anions M OH 2 Some M2 cations are replaced by a trivalent one N3 This creates an excess of positive electrical charges which needs to be compensated by the same number of negative electrical charges born by anions These anions are located in the space present in between adjacent hydroxide layers The interlayers in LDHs are also occupied by water molecules accompanying the anions counterbalancing the excess of positive charges created by the cation isomorphic substitution in the hydroxides sheets In the most studied class of LDHs the positive layer c consisting of divalent M2 and trivalent N3 cations can be represented by the generic formula M2 1 x N3 x OH 2 x Xn x n yH2 O x where Xn is the intercalating anion In AFm the divalent cation is a calcium ion Ca2 while the substituting trivalent cation is an aluminium ion Al3 The nature of the counterbalancing anion Xn can be very diverse OH Cl SO2 4 CO2 3 NO 3 NO 2 2 3 4 The thickness of the interlayer is sufficient to host a variety of relatively large anions often present as impurities B OH 4 SeO2 4 SeO2 3 5 6 As other LDHs AFm can incorporate in their structure toxic elements such as boron 5 and selenium 6 Some AFm phases are presented in the table here below as a function of the nature of the anion counterbalancing the excess of positive charges in the Ca OH 2 hydroxide sheets As in portlandite Ca OH 2 the hydroxide sheets of AFm are made of hexa coordinated octahedral cations located in a same plane but due to the excess of positive electrical charges the hydroxide sheets are distorted Different AFm phases as a function of the nature of the counterbalancing anion in the LDH structure and its stoichiometry n Anion AFm name Oxide notation LDH formula Reference yX displaystyle ce yX nbsp AFm generic 3CaO Al2O3 CaXy nH2O Ca4Al2Xy OH 12 n 6 H2O 2 OH displaystyle ce 2OH nbsp AFm monohydrate 3CaO Al2O3 Ca OH 2 10H2O Ca4Al2 OH 14 4H2O Hydrocalumite HBM 7 Mindat 8 1 SO 4 2 displaystyle ce 1SO4 2 nbsp AFm monosulfate 3CaO Al2O3 CaSO4 12H2O Ca4Al2 SO4 OH 12 6H2O Divet 2000 9 1 CO 3 2 displaystyle ce 1CO3 2 nbsp AFm monocarbonate 3CaO Al2O3 CaCO3 11H2O Ca4Al2 CO3 OH 12 5H2O Divet 2000 9 1 2 CO 3 2 1 OH displaystyle ce 1 2CO3 2 1OH nbsp AFm hemicarbonate 3CaO Al2O3 CaCO3 Ca OH 2 11 5H2O Ca4Al2 CO3 OH 13 5 5H2O Divet 2000 9 2 Cl displaystyle ce 2Cl nbsp Friedel s salt 3CaO Al2O3 CaCl2 10H2O Ca4Al2Cl2 OH 12 4H2O Friedel 1897 2 1 Cl 1 2 SO 4 2 displaystyle ce 1Cl 1 2SO4 2 nbsp Kuzel s salts 3CaO Al2O3 CaSO4 CaCl2 11H2O Ca4Al2 SO4 Cl OH 12 5H2O Glasser 1999 3 2 NO 3 displaystyle ce 2NO3 nbsp AFm nitrate 3CaO Al2O3 Ca NO3 2 10H2O Ca4Al2 NO3 2 OH 12 4H2O Balonis amp Glasser 2011 4 2 NO 2 displaystyle ce 2NO2 nbsp AFm nitrite 3CaO Al2O3 Ca NO2 2 10H2O Ca4Al2 NO2 2 OH 12 4H2O Balonis amp Glasser 2011 4 To convert the oxide notation in LDH formula the mass balance in the system has to respect the principle of the conservation of matter Oxide ions O2 and water are transformed into 2 hydroxide anions OH according to the acid base reaction between H2O and O2 a strong base as typically exemplified by the quicklime CaO slaking process H2O O2 OH OH A1 B2 B1 A2 or simply O2 H2O 2 OH AFm structure editAFm phases encompass a class of calcium aluminate hydrates C A H whose structure derives from that of hydrocalumite 7 8 4CaO Al2O3 13 19H2O in which OH anions are partly replaced by SO2 4 or CO2 3 anions 8 The different mineral phases resulting from these anionic substitutions do not easily form solid solutions but behave as independent phases The replacement of hydroxide ions by sulfate ions does not exceed 50 mol So AFm does not refer to a single pure mineralogical phase but rather to a mix of several AFm phases co existing in hydrated cement paste HCP 1 Considering a monovalent anion X the chemical formula can be rearranged and expressed as 2 Ca2 Al Fe OH 6 X nH2O or Ca4 Al Fe 2 OH 12 X nH2O as presented in the table in the former section The Me OH 6 octahedral ions are located in a plane as for calcium or magnesium hydroxides in portlandite or brucite hexagonal sheets respectively The replacement of one divalent Ca2 cation by a trivalent Al3 cation or to a lesser extent by a Fe3 cation with a Ca Al ratio of 2 1 one Al substituted for every 3 cations causes an excess of positive charge in the sheet 2 2Ca OH 2 Al Fe OH 2 to be compensated by 2 negative charges X The anions X counterbalancing the positive charge imbalance born by the sheet are located in the interlayer whose spacing is much larger than in the layered structure of brucite or portlandite This allows the AFm structure to accommodate larger anionic species along with water molecules 1 The crystal structure of AFm phases is that of layered double hydroxide LDH and AFm phases also exhibit the same anion exchange properties The carbonate anion CO2 3 occupies the interlayer space in a privileged way with the highest selectivity coefficient and is more retained in the interlayer than other divalent or monovalent anions such as SO2 4 or OH According to Miyata 1983 10 the equilibrium constant selectivity coefficient for anion exchange varies in the order CO2 3 gt HPO2 4 gt SO2 4 for divalent anions and OH gt F gt Cl gt Br gt NO 3 gt I for monovalent anions but this order is not universal and varies with the nature of the LDH Thermodynamic stability editThe thermodynamic stability of AFm phases studied at 25 C depends on the nature of the anion present in the interlayer CO2 3 stabilises AFm and displaces OH and SO2 4 anions at their concentrations typically found in hardened cement paste HCP 1 Different sources of carbonate can contribute to the carbonation of AFm phases 1 Addition of limestone filler finely ground atmospheric CO2 carbonate present as impurity in the gypsum interground with the clinker to avoid cement flash setting and alkali sulfates condensed onto clinker during its cooling or from added clinker kiln dust 1 Carbonation can rapidly occur within the fresh concrete during its setting and hardening internal carbonate sources or slowly continue in the long term in the hardened cement paste in concrete exposed to external sources of carbonate CO2 from the air or bicarbonate anion HCO 3 present in groundwater immersed structures or clay porewater foundations and underground structures When the carbonate concentration increases in the hardened cement paste HCP hydroxy AFm are progressively replaced first by hemicarboaluminate and then by monocarboaluminate The stability of AFm phases increases with their carbonate content as shown by Damidot and Glasser 1995 by means of their thermodynamic calculations of the CaO Al2O3 SiO2 H2O system at 25 C 1 11 When carbonate displaces sulfate from AFm the sulfate released in the concrete pore water may react with portlandite Ca OH 2 to form ettringite 3CaO Al2O3 3CaSO4 32H2O the main AFt phase present in the hydrated cement system 1 As stressed by Matschei et al 2007 the impact of small amounts of carbonate on the nature and stability of the AFm phases is noteworthy 1 Divet 2000 also notes that micromolar amount of carbonate can inhibit the formation of AFm sulfate favoring so the crystallisation of ettringite AFt sulfate 9 See also editAFt phases Concrete degradation Chloride attack Layered double hydroxides LDH Friedel s salt Ettringite AFt Pitting corrosion of rebar induced by chloride attackReferences edit a b c d e f g h i Matschei T Lothenbach B Glasser F P 2007 02 01 The AFm phase in Portland cement Cement and Concrete Research 37 2 118 130 doi 10 1016 j cemconres 2006 10 010 ISSN 0008 8846 Retrieved 2022 02 10 a b Friedel Georges 1897 Sur un chloro aluminate de calcium hydrate se maclant par compression Bulletin de la Societe Francaise de Mineralogie et de Cristallographie 19 122 136 a b Glasser F P Kindness A Stronach S A June 1999 Stability and solubility relationships in AFm phases Cement and Concrete Research 29 6 861 866 doi 10 1016 S0008 8846 99 00055 1 ISSN 0008 8846 a b c Balonis Magdalena Medala Marta Glasser Fredrik P July 2011 Influence of calcium nitrate and nitrite on the constitution of AFm and AFt cement hydrates Advances in Cement Research 23 3 129 143 doi 10 1680 adcr 10 00002 eISSN 1751 7605 ISSN 0951 7197 a b Champenois Jean Baptiste Mesbah Adel Cau Dit Coumes Celine Renaudin Guillaume Leroux Fabrice Mercier Cyrille Revel Bertrand Damidot Denis October 2012 Crystal structures of Boro AFm and sBoro AFt phases Cement and Concrete Research 42 10 1362 1370 doi 10 1016 j cemconres 2012 06 003 ISSN 0008 8846 a b Baur Isabel Johnson C Annette November 2003 The solubility of selenate AFt 3CaO Al2O3 3CaSeO4 37 5H2O and selenate AFm 3CaO Al2O3 CaSeO4 xH2O Cement and Concrete Research 33 11 1741 1748 doi 10 1016 S0008 8846 03 00151 0 ISSN 0008 8846 a b Handbook of mineralogy 2005 Hydrocalumite PDF handbookofmineralogy org Retrieved 19 April 2023 a b c Mindat 3 April 2023 Hydrocalumite mindat org Retrieved 19 April 2023 a b c d Divet Loic 2000 Etat des connaissances sur les causes possibles des reactions sulfatiques internes au beton PDF Bulletin de Liaison des Laboratoires des Ponts et Chaussees 227 71 84 Miyata Shigeo 1983 08 01 Anion exchange properties of hydrotalcite like compounds Clays and Clay Minerals 31 4 305 311 Bibcode 1983CCM 31 305M doi 10 1346 CCMN 1983 0310409 ISSN 1552 8367 Damidot D Glasser F P January 1995 Investigation of the CaO Al2O3 SiO2 H2O system at 25 C by thermodynamic calculations Cement and Concrete Research 25 1 22 28 doi 10 1016 0008 8846 94 00108 B ISSN 0008 8846 Further reading editBaquerizo Luis G Matschei Thomas Scrivener Karen L Saeidpour Mahsa Wadso Lars 2015 07 01 Hydration states of AFm cement phases Cement and Concrete Research 73 143 157 doi 10 1016 j cemconres 2015 02 011 ISSN 0008 8846 Feng Pan Miao Changwen Bullard Jeffrey W 2016 03 01 Factors influencing the stability of AFm and AFt in the Ca Al S O H System at 25 C Journal of the American Ceramic Society 99 3 R Riman ed 1031 1041 doi 10 1111 jace 13971 ISSN 1551 2916 PMC 4911640 PMID 27335503 Galan Isabel Glasser Fredrik P 2015 02 01 Chloride in cement Advances in Cement Research 27 2 63 97 doi 10 1680 adcr 13 00067 eISSN 1751 7605 ISSN 0951 7197 Glasser F P Kindness A Stronach S A June 1999 Stability and solubility relationships in AFm phases Cement and Concrete Research 29 6 861 866 doi 10 1016 S0008 8846 99 00055 1 ISSN 0008 8846 Hirao Hiroshi Yamada Kazuo Takahashi Haruka Zibara Hassan 2005 Chloride binding of cement estimated by binding isotherms of hydrates Journal of Advanced Concrete Technology 3 1 77 84 doi 10 3151 jact 3 77 eISSN 1347 3913 ISSN 1346 8014 Matschei T Lothenbach B Glasser F P February 2007 The AFm phase in Portland cement Cement and Concrete Research 37 2 118 130 doi 10 1016 j cemconres 2006 10 010 ISSN 0008 8846 Mesbah Adel Cau dit Coumes Celine Frizon Fabien Leroux Fabrice Ravaux Johann Renaudin Guillaume 2011 A new investigation of the Cl CO32 substitution in AFm phases Journal of the American Ceramic Society 94 6 1901 1910 doi 10 1111 j 1551 2916 2010 04305 x ISSN 1551 2916 Mesbah Adel Cau dit Coumes Celine Renaudin Guillaume Frizon Fabien Leroux Fabrice 2012 08 01 Uptake of chloride and carbonate ions by calcium monosulfoaluminate hydrate Cement and Concrete Research 42 8 1157 1165 doi 10 1016 j cemconres 2012 05 012 ISSN 0008 8846 Mesbah Adel Rapin Jean Philippe Francois Michel Cau dit Coumes Celine Frizon Fabien Leroux Fabrice Renaudin Guillaume 2011 Crystal structures and phase transition of cementitious bi anionic AFm Cl CO32 compounds Journal of the American Ceramic Society 94 1 261 268 doi 10 1111 j 1551 2916 2010 04050 x ISSN 1551 2916 Nedyalkova Latina Tits Jan Renaudin Guillaume Wieland Erich Mader Urs Lothenbach Barbara 2022 02 15 Mechanisms and thermodynamic modelling of iodide sorption on AFm phases Journal of Colloid and Interface Science 608 Pt 1 683 691 Bibcode 2022JCIS 608 683N doi 10 1016 j jcis 2021 09 104 ISSN 0021 9797 PMID 34634544 S2CID 238637368 Terzis A Filippakis S Kuzel Hans Jurgen Burzlaff Hans 1 December 1987 The crystal structure of Ca2Al OH 6Cl 2H2O Zeitschrift fur Kristallographie Crystalline Materials 181 1 4 29 34 doi 10 1524 zkri 1987 181 14 29 eISSN 2196 7105 ISSN 2194 4946 S2CID 102051376 Retrieved from https en wikipedia org w index php title AFm phases amp oldid 1176745137, wikipedia, wiki, book, books, library,

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