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20e6e440 still produces different residuals 6ea9caf0 Tony H2S. Amm.dat, phreeqc.dat, pitzer.dat, utf8, updated test cases c1c97a85 before H2S a7be9fcf Updated Amm.dat, phreeqc.dat, pitzer.dat for H2S(g) b40b25fd Another SIT database fce334ff use cmake for valgrind tests 90f9cb53 checking in test cases using latest revisions. degree sign in pitzer.dat d45a37e0 database UTF-8 3aa7a146 Tony database update, kinetic_rates example f385cf57 Tony's updates March 10, 2021 88afb660 Tony's changes March 10, 2021. 4396def4 add databases e4e5449a [wphast] updated date 4c209593 [phreeqc3] updated image location beaab1d6 more characters 6b8138c2 fixed degree sign 759cac1f fixed some sit.dat characters 3f258562 updated databases 8be6ec5f update to charlton master 2560903d [phreeqci] Testing subtree merges 1d71804f Merge commit 'a400365a5e06a9cd2ac0aa6e2c51fa4797c631f8' a400365a [phreeqc3] Testing subtree merges 4296b155 Merge commit '0e8069e37275f23d47e04bd6b7873ec56dfdf088' 0e8069e3 Fixed bug with more porosities than cells in TRANSPORT. Added silica sorption to databases. Revised CalPortDiff fa7cbaf5 Added .gitlab-ci.yml 6a8d5088 Added .gitlab-ci.yml cfc208b0 updated installer 164b85d3 Fixed some bugs with iso.dat inverse modeling, added test case. Still does not generate [13C](4) and [13C](-4) from SOLUTION 06e25ec8 Correction to core10.dat from Neveu git-subtree-dir: database git-subtree-split: 20e6e440f056358f9887ada878a76d8e3d4ecc64
158 lines
5.3 KiB
Plaintext
158 lines
5.3 KiB
Plaintext
# Concrete minerals
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# Read this file in your input file with
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# INCLUDE$ c:\phreeqc\database\concrete_phr.dat
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PRINT; -reset false
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# # AFm (short for monosulfoaluminate) is an anion-exchanger, with the general formula Ca4Al2(Y-2)(OH)12:6H2O.
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# # Listed are the solubilities of end-members in the neutral form as Y-AFm, and with 5% surface charge as Y-AFmsura.
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# #
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# # Example of the combination of the charged AFmsura and charge-balancing EDL calculations:
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# SURFACE_MASTER_SPECIES
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# Sura Sura+
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# SURFACE_SPECIES
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# Sura+ = Sura+
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# SOLUTION 1
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# pH 7 charge
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# REACTION 1
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# Ca3O3Al2O3 1 gypsum 1; 0.113 # MW gfw("Ca3O3Al2O3CaSO4(H2O)2") = 442.4. 0.113 for w/s = 20
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# SAVE solution 2
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# END
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# RATES
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# Sum_all_AFmsura # Sums up with the single charge formula, Ca2Al...
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# 10 tot_ss = 2 * equi("AFmsura")
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# 20 SAVE (m - tot_ss) * time
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# -end
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# USE solution 2
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# EQUILIBRIUM_PHASES 2
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# AFmsura 0 0
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# KINETICS 2
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# Sum_all_AFmsura; -formula H2O 0; -m0 0; -time_step 30
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# SURFACE 2
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# Sura Sum_all_AFmsura kin 0.05 8.6e3; -donnan debye 2 ; -equil 1
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# END
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PHASES
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Portlandite # Reardon, 1990
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Ca(OH)2 = Ca+2 + 2 OH-
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-log_k -5.19; -Vm 33.1
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Gibbsite
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Al(OH)3 + OH- = Al(OH)4-
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-log_k -1.123; -Vm 32.2
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-analyt -7.234 1.068e-2 0 1.1829 # data from Wesolowski, 1992, GCA 56, 1065
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# AFm with a single exchange site...
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OH-AFm # Appelo, 2021
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Ca2AlOH(OH)6:6H2O = 2 Ca+2 + Al(OH)4- + 3 OH- + 6 H2O
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-log_k -12.84; -Vm 185
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OH-AFmsura
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Ca2Al(OH)0.95(OH)6:6H2O+0.05 = 2 Ca+2 + Al(OH)4- + OH- + 1.95 OH- + 6 H2O
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-log_k -12.74; -Vm 185
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Cl-AFm # Friedel's salt. Appelo, 2021
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Ca2AlCl(OH)6:2H2O = 2 Ca+2 + Al(OH)4- + Cl- + 2 OH- + 2 H2O
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-log_k -13.68; -Vm 136
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Cl-AFmsura
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Ca2AlCl0.95(OH)6:2H2O+0.05 = 2 Ca+2 + Al(OH)4- + 0.95 Cl- + 2 OH- + 2 H2O
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-log_k -13.59; -Vm 136
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# AFm with a double exchange site...
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SO4-AFm # Monosulfoaluminate. Appelo, 2021
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Ca4Al2(SO4)(OH)12:6H2O = 4 Ca+2 + 2 Al(OH)4- + SO4-2 + 4 OH- + 6 H2O
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-log_k -29.15; -Vm 309
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SO4-AFmsura
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Ca4Al2(SO4)0.95(OH)12:6H2O+0.1 = 4 Ca+2 + 2 Al(OH)4- + 0.95 SO4-2 + 4 OH- + 6 H2O
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-log_k -28.88; -Vm 309
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SO4-OH-AFm # Hemisulfoaluminate. Appelo, 2021
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Ca4Al2(SO4)0.5(OH)(OH)12:9H2O = 4 Ca+2 + 2 Al(OH)4- + 0.5 SO4-2 + 5 OH- + 9 H2O
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-log_k -27.24; -Vm 340
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SO4-OH-AFmsura
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Ca4Al2(SO4)0.475(OH)0.95(OH)12:9H2O+0.1 = 4 Ca+2 + 2 Al(OH)4- + 0.475 SO4-2 + 4.95 OH- + 9 H2O
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-log_k -26.94; -Vm 340
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CO3-AFm # Monocarboaluminate. Appelo, 2021
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Ca4Al2(CO3)(OH)12:5H2O = 4 Ca+2 + 2 Al(OH)4- + CO3-2 + 4 OH- + 5 H2O
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-log_k -31.32; -Vm 261
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CO3-AFmsura
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Ca4Al2(CO3)0.95(OH)12:5H2O+0.1 = 4 Ca+2 + 2 Al(OH)4- + 0.95 CO3-2 + 4 OH- + 5 H2O
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-log_k -31.05; -Vm 261
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CO3-OH-AFm # Hemicarboaluminate. Appelo, 2021
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Ca4Al2(CO3)0.5(OH)(OH)12:5.5H2O = 4 Ca+2 + 2 Al(OH)4- + 0.5 CO3-2 + 5 OH- + 5.5 H2O
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-log_k -29.06; -Vm 284
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CO3-OH-AFmsura
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Ca4Al2(CO3)0.475(OH)0.95(OH)12:5.5H2O+0.1 = 4 Ca+2 + 2 Al(OH)4- + 0.475 CO3-2 + 4.95 OH- + 5.5 H2O
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-log_k -28.84; -Vm 284
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SO4-Cl-AFm # Kuzel's salt. Appelo, 2021
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Ca4Al2(SO4)0.5Cl(OH)12:5H2O = 4 Ca+2 + 2 Al(OH)4- + 0.5 SO4-2 + Cl- + 4 OH- + 5 H2O
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-log_k -28.52; -Vm 290
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SO4-Cl-AFmsura
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Ca4Al2(SO4)0.475Cl0.95(OH)12:5H2O+0.1 = 4 Ca+2 + 2 Al(OH)4- + 0.475 SO4-2 + 0.95 Cl- + 4 OH- + 5 H2O
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-log_k -28.41; -Vm 290
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SO4-AFem # Lothenbach 2019
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Ca4Fe2(SO4)(OH)12:6H2O = 4 Ca+2 + 2 Fe(OH)4- + SO4-2 + 4 OH- + 6 H2O
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-log_k -31.57; -Vm 321
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CO3-AFem # Lothenbach 2019
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Ca4Fe2(CO3)(OH)12:6H2O = 4 Ca+2 + 2 Fe(OH)4- + CO3-2 + 4 OH- + 6 H2O
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-log_k -34.59; -Vm 292
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CO3-OH-AFem # Lothenbach 2019. ?? 3.5 H2O??
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Ca4Fe2(CO3)0.5(OH)(OH)12:3.5H2O = 4 Ca+2 + 2 Fe(OH)4- + 0.5 CO3-2 + 5 OH- + 3.5 H2O
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-log_k -30.83; -Vm 273
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Ettringite # Matschei, 2007, fig. 27
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Ca6Al2(SO4)3(OH)12:26H2O = 6 Ca+2 + 2 Al(OH)4- + 3 SO4-2 + 4 OH- + 26 H2O
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-log_k -44.8; -Vm 707
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-analyt 334.09 0 -26251 -117.57 # 5 - 75 C
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CO3-ettringite # Matschei, 2007, tbl 13
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Ca6Al2(CO3)3(OH)12:26H2O = 6 Ca+2 + 2 Al(OH)4- + 3 CO3-2 + 4 OH- + 26 H2O;
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-log_k -46.50; -Vm 652
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C2AH8 # Matschei, fig. 19
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Ca2Al2(OH)10:3H2O = 2 Ca+2 + 2 Al(OH)4- + 2 OH- + 3 H2O
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-log_k -13.55; -Vm 184
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-analyt -225.37 -0.12380 0 100.522 # 1 - 50 °C
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CAH10 # Matschei, fig. 19
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CaAl2(OH)8:6H2O = Ca+2 + 2 Al(OH)4- + 6 H2O
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-log_k -7.60; -Vm 194
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-delta_h 43.2 # 1 - 20 ºC
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Hydrogarnet_Al # Matschei, 2007, Table 5
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(CaO)3Al2O3(H2O)6 = 3 Ca+2 + 2 Al(OH)4- + 4 OH-
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-log_k -20.84; -Vm 150
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# -analyt -20.64 -0.002 0 0.16 # 5 - 105 °C
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# -delta_h 6.4 kJ # Geiger et al., 2012, AM 97, 1252-1255
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Hydrogarnet_Fe # Lothenbach 2019
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(CaO)3Fe2O3(H2O)6 = 3 Ca+2 + 2 Fe(OH)4- + 4 OH-
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-log_k -26.3; -Vm 155
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Hydrogarnet_Si # Matschei, 2007, Table 6
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Ca3Al2Si0.8(OH)15.2 = 3 Ca+2 + 2 Al(OH)4- + 0.8 H4SiO4 + 4 OH-
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-log_k -33.69; -Vm 143
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-analyt -476.84 -0.2598 0 210.38 # 5 - 85 °C
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Jennite # CSH2.1. Lothenbach 2019
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Ca1.67SiO3.67:2.1H2O + 0.57 H2O = 1.67 Ca+2 + 2.34 OH- + H3SiO4-
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-log_k -13.12; -Vm 78.4
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Tobermorite-I # Lothenbach 2019
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CaSi1.2O3.4:1.6H2O + 0.6 H2O = Ca+2 + 0.8 OH- + 1.2 H3SiO4-
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-log_k -6.80; -Vm 70.4
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Tobermorite-II # Lothenbach 2019
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Ca0.833SiO2.833:1.333H2O + 0.5 H2O = 0.833Ca+2 + 0.666 OH- + H3SiO4-
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-log_k -7.99; -Vm 58.7
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PRINT; -reset true
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# Refs
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# Appelo 2021, Cem. Concr. Res. 140, https://doi.org/10.1016/j.cemconres.2020.106270.
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# Lothenbach, B. et al. 2019, Cem. Concr. Res. 115, 472-506.
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# Matschei, T. et al., 2007, Cem. Concr. Res. 37, 1379-1410. |