References for thermodynamic data in CHNOSZ 2.1.0 (2024-02-11)

Click on a column header to sort, or on a citation to open the URL in new window.

Column 'number' gives the number of times each reference appears in thermo()$OBIGT.

See also the vignette OBIGT thermodynamic database.

number key author year citation note
1 proton OBIGT 1997 Hydrogen-ion convention "The conventional standard molal properties of the hydrogen ion are zero at any pressure and temperature" [@JOH92]
MWKL17.1 G. D. Miron et al. 2017 Am. J. Sci. 317, 755-806 ΔG°f values
88 SLOP98.10 E. L. Shock et al. 1998 slop98.dat computer data file "Corrected values based on data from @HSS95 "
5 SLOP98.11 E. L. Shock et al. 1998 slop98.dat computer data file "Data and parameters as used by @MS97. "
32 SLOP16.1 E. L. Shock et al. 2016 slop16.dat computer data file "Enthalpy changed to be compatible with the equation ΔH=ΔG+TΔS for the formation reaction from elements."
55 SLOP16.6 E. L. Shock et al. 2016 slop16.dat computer data file "Enthalpy corrected to be compatible with the equation ΔG=ΔH-TΔS for the formation reaction from elements."
6 SLOP98.8 E. L. Shock et al. 1998 slop98.dat computer data file "These data were used in @SK95, but were not tabulated in the paper."
DEW17.05 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet (Al+3: parameters in DEW spreadsheet are the same as in @SSWS97)
DEW17.04 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet (Ar, Xe: parameters in DEW spreadsheet are the same as in @SHS89)
DEW19.5 D. A. Sverjensky et al. 2019 Deep Earth Water (DEW) spreadsheet (Ca+2: values listed in DEW spreadsheet)
DEW19.6 D. A. Sverjensky et al. 2019 Deep Earth Water (DEW) spreadsheet (Fe+2: HKF a1-a4 parameters taken from @HS19, which are different from 2019 DEW spreadsheet)
DEW17.01 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet (acetic acid, glycine, methanol, propanoic acid, propanol: parameters in DEW spreadsheet are the same as in @PS01)
DEW17.02 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet (ethanol: parameters in DEW spreadsheet are different from @PS01; no comment provided)
DEW17.03 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet (parameters in DEW spreadsheet are the same as in @FDM+14)
DEW19.1 D. A. Sverjensky et al. 2019 Deep Earth Water (DEW) spreadsheet (values from @HS19 listed in DEW spreadsheet)
DEW19 D. A. Sverjensky et al. 2019 Deep Earth Water (DEW) spreadsheet (values listed in DEW spreadsheet)
DEW17.14 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet 29/11/16: Fit to @TDDZ00 with revised volume increased in order that a1 of the complex a bit greater than the sum of the a1 values of the ions
30 LD12 D. E. LaRowe and J. M. Dick 2012 Geochim. Cosmochim. Acta 80, 70-91 4-hydroxyproline, 5-hydroxylysine, 4 dipeptides, and sidechain and backbone groups in proteins
SK93.1 E. L. Shock and C. M. Koretsky 1993 Geochim. Cosmochim. Acta 57, 4899-4922 Ag-, Au-, Cu(I)- and Al-acetate complexes
SH88.3 E. L. Shock and H. C. Helgeson 1988 Geochim. Cosmochim. Acta 52, 2009-2036 Ag+
1 AVZP06 N. N. Akinfiev et al. 2006 Geochem. Int. 44, 867-878 AgCl3-2
PSK99.1 P. Prapaipong, E. L. Shock and C. M. Koretsky 1999 Geochim. Cosmochim. Acta 63, 2547-2577 Al(Mal)+ and Al(Oxal)+
MWKH16.1 G. D. Miron et al. 2016 Geochim. Cosmochim. Acta 187, 41-78 Al(OH)3 and HSiO3- derived from literature data
SSWS97.4 E. L. Shock, D. C. Sassani et al. 1997 Geochim. Cosmochim. Acta 61, 907-950 Al+3 and Al-hydroxide complexes
8 NA03 D. K. Nordstrom and D. G. Archer 2003 Arsenic thermodynamic data and environmental geochemistry. In Arsenic in Groundwater, eds. Welch and Stollenwerk, Kluwer As oxide and sulfide minerals
1 ZZL+16.1 K. Zimmer et al. 2016 Comp. Geosci. 90, 97-111 As(α): V listed in spronsbl.dat
2 PPB+08.1 E. Perfetti et al. 2008 Geochim. Cosmochim. Acta 72, 713-731 As(OH)3 and AsO(OH)3
10 SSW01 M. D. Schulte, E. L. Shock and R. H. Wood 2001 Geochim. Cosmochim. Acta 65, 3919-3930 AsH3, CF4, CH3F, Cl2, ClO2, N2O, NF3, NO, PH3, and SF6
SSH97.1 D. A. Sverjensky, E. L. Shock and H. C. Helgeson 1997 Geochim. Cosmochim. Acta 61, 1359-1412 Au(HS)2- and Ag(HS)2-
SSH97.3 D. A. Sverjensky, E. L. Shock and H. C. Helgeson 1997 Geochim. Cosmochim. Acta 61, 1359-1412 Au-, Ag-, Cu- and Zn-chloride complexes
SSWS97.2 E. L. Shock, D. C. Sassani et al. 1997 Geochim. Cosmochim. Acta 61, 907-950 Au+ and Cu+
1 OBIGT.3 J. M. Dick 2017 OBIGT database in CHNOSZ AuCl4- renamed to AuCl4-3
DEW17.33 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet August 16th, 2013 fit to @BL06
AP14 N. N. Akinfiev and A. V. Plyasunov 2014 Geochim. Cosmochim. Acta 126, 338-351 B(OH)3, Si(OH)4, and As(OH)3
SHA14.2 D. A. Sverjensky et al. 2014 Geochim. Cosmochim. Acta 129, 125-145 BO(OH): Revised May 2013
SHA14.4 D. A. Sverjensky et al. 2014 Geochim. Cosmochim. Acta 129, 125-145 BO2-: revised a1-a4 using delkappan for BO2- instead of B(OH)4- used by @SH88; @SSWS97
DEW17.5 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet BaCl+, CaCl+, CaCl2: with new V from the sum of a1 values of ions
3 SM93 E. L. Shock and W. B. McKinnon 1993 Icarus 106, 464-477 CO, HCN, urea
FDM+14 S. Facq et al. 2014 Geochim. Cosmochim. Acta 132, 375-390 CO2, HCO3-, CO3-2, CaCO3, Ca+2
SPRONS92.2 H. C. Helgeson et al. 1992 sprons92.dat computer data file Ca-bearing minerals; "Gibbs free energies and enthalpies were corrected to be consistent with updated values of Gibbs free energies of Ca2+ and CO32- [@SH88] together with the solubilities of calcite and aragonite reported by @PB82 "
DEW19.3 D. A. Sverjensky et al. 2019 Deep Earth Water (DEW) spreadsheet CaO: Fitted by Dimitri to high PT retrievals from Fang
DEW17.10 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet CaSO4: revised using exptl V and pred. a1 from new correlation
4 LBT+11 W. Liu et al. 2011 Geochim. Cosmochim. Acta 75, 1227-1248 Co-chloride complexes
2 ZZL+16.2 K. Zimmer et al. 2016 Comp. Geosci. 90, 97-111 Cp parameters listed in spronsbl.dat
OH90 E. H. Oelkers and H. C. Helgeson 1990 Geochim. Cosmochim. Acta 54, 727-738 Debye-Hückel extended term parameter (b$\gamma$)
10 ZS92 C. Zhu and D. A. Sverjensky 1982 Geochim. Cosmochim. Acta 56, 3435-3467 F,Cl,OH biotite and apatite endmembers. GHS and V were taken from Table 6 of @ZS92; heat capacity and volume parameters from `berman.dat`.
1 VPV05 O. Vidal, T. Parra and P. Viellard 2005 Am. Mineral. 90, 347-358 Fe-amesite
LEB+06 W. Liu et al. 2006 Chem. Geol. 231, 326-349 FeCl2+, FeCl3, FeCl4-
DEW17.15 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet FeCl2+, FeCl4-: 29/11/16: Fit to @LEB+06 with revised volume increased in order that a1 of the complex a bit greater than the sum of the a1 values of the ions
DEW17.16 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet FeCl3: 29/11/16: Fit to @LEB+06 with revised volume increased in order that a1 of the complex is equal to the sum of the a1 values of the ions
TDDZ00 B. R. Tagirov et al. 2000 Chem. Geol. 162, 193-219 FeCl+2
DEW17.13 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet FeOH+, FeO, HFeO2-: 31/1/17: V from estimate to have similar behavior to MgO,aq
DEW17.26 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet Fit to @SBS14 & @SH77; plus revised V increased so that a1 of the complex is the sum of the a1 values of the ions
SHA14.3 D. A. Sverjensky et al. 2014 Geochim. Cosmochim. Acta 129, 125-145 Fitted to @HP97 data with a1 pred. from the sum of the ions and used to predict the volume
9 SHD91 D. A. Sverjensky, J. J. Hemley and W. M. D'Angelo 1991 Geochim. Cosmochim. Acta 55, 989-1004 G and H revisions for K- and Al-bearing silicates
17 OBIGT.1 J. M. Dick 2017 OBIGT database in CHNOSZ GHS (Tr) of the polymorph that is stable at 298.15 K was combined with Htr and the Cp coefficients to calculate the metastable GHS (Tr) of the polymorphs that are stable at higher temperatures.
OBIGT.8 J. M. Dick 2019 OBIGT database in CHNOSZ GHS recalculated by adding difference from SiO2 [@SSH97] to updated values for SiO2 [@AS04]
19 DLH06.2 J. M. Dick, D. E. LaRowe and H. C. Helgeson 2006 Biogeosciences 3, 311-336 Gly-X-Gly tripeptides Cp, V, and HKF c1, c2, ω parameters
SH88.2 E. L. Shock and H. C. Helgeson 1988 Geochim. Cosmochim. Acta 52, 2009-2036 H2AsO3-
1 HGK84 L. Haar and J. S. Gallagher and G. S. Kell 1984 NBS/NRC Steam Tables H2O
1 JOH92 J. W. Johnson and E. H. Oelkers and H. C. Helgeson 1992 Comp. Geosci. 18, 899-947 H2O
1 LXW21 X. Liu, C. Xiao and Y. Wang 2021 Chem. Geol. 584, 120488 H2WO4
RS87 J. R. Ruaya and T. M. Seward 1987 Geochim. Cosmochim. Acta 51, 121-130 HCl
DEW17.21 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet HSO3-: revised using published estimated V and pred. a1 from new correlation
SSH97.2 D. A. Sverjensky, E. L. Shock and H. C. Helgeson 1997 Geochim. Cosmochim. Acta 61, 1359-1412 HSiO3-
1 OBIGT.5 J. M. Dick 2017 OBIGT database in CHNOSZ Incorrect values of HKF a1--a4 parameters for [-CH2NH2] were printed in Table 6 of @DLH06; corrected values are used here.
SH88.4 E. L. Shock and H. C. Helgeson 1988 Geochim. Cosmochim. Acta 52, 2009-2036 K+, Na+, Ca+2, Mg+2, Cl-, and OH-
PH97 V. A. Pokrovskii and H. C. Helgeson 1997 Chem. Geol. 137, 221-242 KAl2O
OH88 E. H. Oelkers and H. C. Helgeson 1988 J. Phys. Chem. 92, 1631-1639 KCl
HP97 P. C. Ho and D. A. Palmer 1997 Geochim. Cosmochim. Acta 61, 3027-3040 KOH
SGX+06 A. V. Sharygin et al. 2006 Geochim. Cosmochim. Acta 70, 5169-5182 KSO4-
15 AZ01 N. N. Akinfiev and A. V. Zotov 2001 Geochem. Int. 39, 990-1006 M+, MCl2-, M(OH)2-, MCl, and MOH (M = Au+, Ag+, or Cu+)
6 AZ10 N. N. Akinfiev and A. V. Zotov 2010 Geochem. Int. 48, 714-720 MHS and M(HS)2- (M = Au+, Ag+, or Cu+)
DEW17.23 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet May, 2017 Fitted to logKs from @OH88 + retrieved logKs from Hemley experiments at 1.0 kb using the HCl referred to above
SBS14 A. Stefánsson, P. Benézéth and J. Schott 2014 Geochim. Cosmochim. Acta 138, 21-31 Mg(HCO3)+
41 LH06b D. E. LaRowe and H. C. Helgeson 2006 Thermochim. Acta 448, 82-106 Mg-complexed adenosine nucleotides (ATP), NAD, and NADP
DEW17.27 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet MgCO3: @SSH97 revised volume increased in order that a1 of the complex is the sum of the a1 values of the ions; and Cp revised using isocoulombic reln with CaCO3,aq; also omega is set to +0.3 as for all neutral metal complexes.
DEW19.2 D. A. Sverjensky et al. 2019 Deep Earth Water (DEW) spreadsheet MgOH+: Revised by Dimitri, January, 2019; with minimum volume needed
ARHB06 C. Akilan et al. 2006 ChemPhysChem 7, 2319-2330 MgSO4
2 MS97 T. M. McCollom and E. L. Shock 1997 Geochim. Cosmochim. Acta 61, 4375-4391 MgSO4, NaSO4-, and HCl
2 WEP+82.1 D. D. Wagman, W. H. Evans et al. 1982 J. Phys. Chem. Ref. Data 11, Suppl. 2, 1-392 Mn(OH)2 (amorphous) and MgSO4
1 SUF+98 H. Senoh et al. 1998 J. Alloys Compd. 280, 114-124 Mn(OH)2: Cp coefficients from linear fit to values estimated by @SUF+98
2 AS01 J. P. Amend and E. L. Shock 2001 FEMS Microbiol. Rev. 25, 175-243 NO and N2O
1 DPS+96 I. Diakonov, G. Pokrovski et al. 1996 Geochim. Cosmochim. Acta 60, 197-211 NaAl(OH)4
SBS13 A. Stefánsson, P. Benézéth and J. Schott 2013 Geochim. Cosmochim. Acta 120, 600-611 NaCO3-
DEW17.30 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet NaCO3-: Fit to @SBS13 (80 to 200 C) & @GTS61 (at 25 C) to get G, S and Cp; with a1 pred. from the sum of the ions and used to predict the volume
SSH97.5 D. A. Sverjensky, E. L. Shock and H. C. Helgeson 1997 Geochim. Cosmochim. Acta 61, 1359-1412 NaHSiO3, CaHSiO3+, and MgHSiO3+
DEW17.32 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet NaOH: Fitted to @HP97 data with a1 pred. from the sum of the ions and used to predict the volume
10 AKK+20 N. N. Akinfiev et al. 2020 Geochim. Cosmochim. Acta 280, 102-115 Nb and Ta species
1 electron OBIGT 2006 See CHNOSZ vignette OBIGT.Rmd for more information Non-zero entropy of the electron based on the hydrogen-ion convention
AML10.1 M. Accornero, L. Marini and M. Lelli 2010 Appl. Geochem. 25, 242-260 Np- and Am-chromate complexes
BL06 A. V. Bandura and S. N. Lvov 2006 J. Phys. Chem. Ref. Data 35, 15-30 OH-
SS98a.3 D. C. Sassani and E. L. Shock 1998 Geochim. Cosmochim. Acta 62, 2643-2671 Pd+2 and Pt+2 and their complexes
11 TBZ+13 B. R. Tagirov et al. 2013 Geochim. Cosmochim. Acta 117, 348-373 Pd+2 and complexes
5 TBB15 B. R. Tagirov et al. 2015 Geochem. Int. 53, 327-340 Pt+2 and complexes
DEW17.19 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet Regression of @RS87 & @TZA97 with new full correlations
DEW17.17 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet Revised 1/22/15 based on V at 25 C from @ZW07 and predicted a1, a2, and a4; c1 and c2 from fits to delCpr protonation of @ZW07; S from fitting temperature dependence of logK from @ZW07; omega predicted from S using ion correlation.
DEW17.18 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet Revised 1/22/15 based on fitting Cp and V vs T data from @HDM+94 + revised correlation for a1 from @SHA14; omega from delCPr above 100 °C [@ZW07]; G, H, and S from @AH97b
DEW17.25 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet Revised G, S and Cp to fit @Noy07 & @SGX+06 with a1 of the complex equal to the sum of the a1 values of the ions
1 SS98a.2 D. C. Sassani and E. L. Shock 1998 Geochim. Cosmochim. Acta 62, 2643-2671 Rh+3
DEW17.29 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet S, Cp, V, omega from fit to @ARHB06 and @FDM94
DEW17.36 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet S3-: Regression of data from @PD15; Feb. 2015
DEW17.38 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet SO2: @SHS89 with revised a1 predicted as a complex from delVn
SHS89.1 E. L. Shock, H. C. Helgeson and D. A. Sverjensky 1989 Geochim. Cosmochim. Acta 53, 2157-2183 SiO2
SHA14 D. A. Sverjensky et al. 2014 Geochim. Cosmochim. Acta 129, 125-145 SiO2 and Si2O4
5 JH85 K. J. Jackson and H. C. Helgeson 1985 Econ. Geol. 80, 1365-1378 Sn minerals
2 OBIGT.7 J. M. Dick 2019 OBIGT database in CHNOSZ Tl(Gly) and Tl(Gly)2-: change Ti to Tl
SLOP16.2 E. L. Shock et al. 2016 slop16.dat computer data file Zn(Ac)3-: "Enthalpy changed to be compatible with the equation ΔH=ΔG+TΔS for the formation reaction from elements. See footnote h in table 2 of @SSH97."
SSH97.4 D. A. Sverjensky, E. L. Shock and H. C. Helgeson 1997 Geochim. Cosmochim. Acta 61, 1359-1412 Zn-acetate complexes
SSWS97.5 E. L. Shock, D. C. Sassani et al. 1997 Geochim. Cosmochim. Acta 61, 907-950 Zn+2 and Zn-hydroxide complexes
13 AT14 N. N. Akinfiev and B. R. Tagirov 2014 Geochem. Int. 52, 197-214 Zn+2 and complexes
DEW17.7 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet acetate: revised January 26th, 2016; new a1 value from complexes and organics correlation
MS99 W. M. Murphy and E. L. Shock 1999 Rev. Mineral. Geochem. 38, 221-253 actinides
1 LCT17 A. R. Lowe, J. S. Cox and P. R. Tremaine 2017 J. Chem. Thermodynamics 112, 129-145 adenine HKF parameters
2 SLOP16.4 E. L. Shock et al. 2016 slop16.dat computer data file adipic acid and n-dodecanoate: "Gibbs free energy corrected to be compatible with the equation ΔG=ΔH-TΔS for the formation reaction from elements. See footnote y in table 4 of @Sho95."
10 SS93 M. D. Schulte and E. L. Shock 1993 Geochim. Cosmochim. Acta 57, 3835-3846 aldehydes
12 SR04 M. D. Schulte and K. L. Rogers 2004 Geochim. Cosmochim. Acta 68, 1087-1097 alkane thiols
17 Ric08 L. Richard 2008 personal communication alkenes
10 DSM+97 J. D. Dale, E. L. Shock et al. 1997 Geochim. Cosmochim. Acta 61, 4017-4024 alkylphenols
2 Ber90.1 R. G. Berman 1990 Am. Mineral. 75, 328-344 almandine and ilmenite: modified H and/or S
RH95.3 R. A. Robie and B. S. Hemingway 1995 U. S. Geological Survey Bull. 2131 almandine, dickite, glaucophane, grunerite, halloysite, pyrope: GHS and Cp at 25 °C
PH95 V. A. Pokrovskii and H. C. Helgeson 1995 Am. J. Sci. 295, 1255-1342 aluminum species
38 DLH06 J. M. Dick, D. E. LaRowe and H. C. Helgeson 2006 Biogeosciences 3, 311-336 amino acid, protein, and organic groups
20 HOKR98.1 H. C. Helgeson, C. E. Owens et al. 1998 Geochim. Cosmochim. Acta 62, 985-1081 amino acids
19 AH97b J. P. Amend and H. C. Helgeson 1997 J. Chem. Soc., Faraday Trans. 93, 1927-1941 amino acids GHS
27 DLH06.1 J. M. Dick, D. E. LaRowe and H. C. Helgeson 2006 Biogeosciences 3, 311-336 amino acids HKF parameters
1 Ber90 R. G. Berman 1990 Am. Mineral. 75, 328-344 annite
1 SHD91.2 D. A. Sverjensky, J. J. Hemley and W. M. D'Angelo 1991 Geochim. Cosmochim. Acta 55, 989-1004 annite: G and H revision for K-bearing silicates [after @SHD91]
1 BDat17.1 D. A. Sverjensky et al. 2017 berman.dat file in SUPCRT92b.zip on the DEW website antigorite: "Oct. 21, 2016: Revised volume coefficients consistent with @HDR06 and @YIY+14 "
TS01.1 B. Tagirov and J. Schott 2001 Geochim. Cosmochim. Acta 65, 3965-3992 aqueous Al species
17 TS01 B. Tagirov and J. Schott 2001 Geochim. Cosmochim. Acta 65, 3965-3992 aqueous Al+3 and complexes
8 NA03.1 D. K. Nordstrom and D. G. Archer 2003 Arsenic thermodynamic data and environmental geochemistry. In Arsenic in Groundwater, eds. Welch and Stollenwerk, Kluwer aqueous As oxides and sulfides
Ste01 A. Stefansson 2001 Chem. Geol. 172, 225-250 aqueous H4SiO4
MS97.2 T. M. McCollom and E. L. Shock 1997 Geochim. Cosmochim. Acta 61, 4375-4391 aqueous HCl
1 TZA97 B. R. Tagirov, A. V. Zotov and N. N. Akinfiev 2007 Geochim. Cosmochim. Acta 61, 4267-4280 aqueous HCl
MWKH16 G. D. Miron et al. 2016 Geochim. Cosmochim. Acta 187, 41-78 aqueous NaCl, NaOH, KCl, KOH, and HCl based on new conductance experiments
AS04 J. Apps and N. Spycher 2004 Data qualification for thermodynamic data used to support THC calculations. Bechtel SAIC Company, LLC. ANL-NBS-HS-000043 REV 00 (DOC.20041118.0004) aqueous SiO2
231 SSWS97 E. L. Shock, D. C. Sassani et al. 1997 Geochim. Cosmochim. Acta 61, 907-950 aqueous ions and hydroxide complexes
3 PS01.1 A. V. Plyasunov and E. L. Shock 2001 Geochim. Cosmochim. Acta 65, 3879-3900 aqueous nonelectrolytes (Ar, Xe, and CO2)
8 PS01 A. V. Plyasunov and E. L. Shock 2001 Geochim. Cosmochim. Acta 65, 3879-3900 aqueous nonelectrolytes (organic species)
MWKL17 G. D. Miron et al. 2017 Am. J. Sci. 317, 755-806 aqueous species in the system Ca-Mg-Na-K-Al-Si-O-H-C-Cl
PB82 L. N. Plummer and E. Busenberg 1982 Geochim. Cosmochim. Acta 46, 1011-1040 aragonite and calcite
1 FDM+14.1 S. Facq et al. 2014 Geochim. Cosmochim. Acta 132, 375-390 aragonite; source of data: `berman.dat`
SSWS97.3 E. L. Shock, D. C. Sassani et al. 1997 Geochim. Cosmochim. Acta 61, 907-950 arsenate and arsenite species
3 PPB+08 E. Perfetti et al. 2008 Geochim. Cosmochim. Acta 72, 713-731 arsenopyrite, loellingite, and westerveldite
2 ZZX+05 Y. Zhu et al. 2005 J. Hazard. Mater. A120, 37-44 barium arsenate and barium hydrogen arsenate: G
1 HRA91 B. S. Hemingway et al. 1991 Am. Mineral. 76, 445-457 boehmite
2 PK70 L. B. Pankratz and E. G. King 1970 U. S. Bureau of Mines Report of Investigations 7435 bornite and chalcopyrite
1 RH95.6 R. A. Robie and B. S. Hemingway 1995 U. S. Geological Survey Bull. 2131 bromellite (melting temperature and G and H not in SUPCRT92)
10 AP01 J. P. Amend and A. V. Plyasunov 2001 Geochim. Cosmochim. Acta 65, 3901-3917 carbohydrates
2 Sho93.1 E. L. Shock 1993 Geochim. Cosmochim. Acta 57, 3341-3349 carbon monoxide and ethylene
77 Sho95 E. L. Shock 1995 Am. J. Sci. 295, 496-580 carboxylic acids
2 HDR+24 B. P. von der Heyden et al. 2024 Can. J. Mineral. Petrol. 62, 77-93 carrollite
3 PMW87 L. B. Pankratz, A. D. Mah and S. W. Watson 1987 Thermodynamic Properties of Sulfides (U.S. Bureau of Mines Bull. 689) cattierite, linnaeite, and Co-pentlandite
1 RA87 E. J. Reardon and D. K. Armstrong 1987 Geochim. Cosmochim. Acta 51, 63-72 celestite GHS
1 HDNB78.2 H. C. Helgeson, J. M. Delany et al. 1978 Am. J. Sci. 278A, 1-229 celestite V and Cp parameters
2 OBIGT.4 J. M. Dick 2017 OBIGT database in CHNOSZ charge of NpO2(Oxal), La(Succ)+, NH4(Succ)-, and NpO2(Succ) as listed by @PSK99
36 Kit15 N. Kitadai 2015 Origins Life Evol. Biospheres 45, 377-409 charged amino acids
8 Kit15.1 N. Kitadai 2015 Origins Life Evol. Biospheres 45, 377-409 charged amino acids GHS (Arg+, Arg-, Asp-, Glu-, His+, Lys+, Lys-, and Tyr-)
1 Pan70 L. B. Pankratz 1970 U. S. Bureau of Mines Report of Investigations 7430 chlorargyrite
1 RHF78 R. A. Robie, B. S. Hemingway and J. R. Fisher 1978 U. S. Geological Survey Bull. 1452 chlorargyrite
6 HS99 J. R. Haas and E. L. Shock 1998 Geochim. Cosmochim. Acta 63, 3429-3441 chloroethylene species
4 LH06a.1 D. E. LaRowe and H. C. Helgeson 2006 Geochim. Cosmochim. Acta 70, 4680-4724 citric acid and citrate
22 CS16 P. A. Canovas III and E. L. Shock 2016 Geochim. Cosmochim. Acta 195, 293-322 citric acid cycle metabolites
4 CS16.1 P. A. Canovas III and E. L. Shock 2016 Geochim. Cosmochim. Acta 195, 293-322 citric acid species HKF a1--a4 parameters
249 HSS95 J. R. Haas, E. L. Shock and D. C. Sassani 1995 Geochim. Cosmochim. Acta 59, 4329-4350 complexes of rare earth elements
3 MNM+06 J. Majzlan, A. Navrotsky et al. 2006 Eur. J. Mineral. 18, 175-186 coquimbite, ferricopiapite, and rhomboclase
1 PAB+14 G. S. Pokrovski, N. N. Akinfiev et al., 2014 2014 Geol. Soc. Spec. Publ. 402, 9-70 corrected H of AuHS
SLOP07.1 E. L. Shock et al. 2007 slop07.dat computer data file corrected charge of Pu(Oxal)+2
MA10 L. Marini and M. Accornero 2010 Environ. Earth Sci. 59, 1601-1606 corrected values
2 VPT01 O. Vidal, T. Parra and F. Trotet 2001 Am. J. Sci. 301, 557-592 daphnite and Mg-amesite
SLOP98.2 E. L. Shock et al. 1998 slop98.dat computer data file daphnite; "Gf and Hf from @SS93a TMM"
2 JUN92 C. de Capitani 1992 JUN92.bs database supplied with Theriak/Domino software data as listed in `JUN92.bs` data file
4 ZZL+16 K. Zimmer et al. 2016 Comp. Geosci. 90, 97-111 data listed in spronsbl.dat
1 ZZL+16.3 K. Zimmer et al. 2016 Comp. Geosci. 90, 97-111 dawsonite GHS
1 RH95.2 R. A. Robie and B. S. Hemingway 1995 U. S. Geological Survey Bull. 2131 dawsonite: Cp coefficients corrected in @TKSS14; Cp value at 25 °C from @BPAH07, citing @FSR76
3 OBIGT.9 J. M. Dick 2021 OBIGT database in CHNOSZ diaminopimelic acid, putrescine and spermidine: parameters recalculated to account for a missing [-CH2NH2] group in the group additivity equations
LRB09 K. H. Lemke, R. J. Rosenbauer and D. K. Bird 2009 Astrobiology 9, 141-146 diglycine and diketopiperazine
DEW17.11 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet diglycine: Jamie & Dimitri fit to exptl Cp(T) and pred. a1-a4; delGf and S from fitting logK dimerisation values from @LRB09
1 Sho92.1 E. L. Shock 1992 Geochim. Cosmochim. Acta 56, 3481-3491 diketopiperazine GHS
DEW17.12 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet diketopiperazine: Jamie & Dimitri fit delGf and S from to logK dimerisation values from @LRB09; pred. a1-a4
1 ST97.1 D. Shvedov and P. R. Tremaine 1997 J. Solution Chem. 26, 1113-1143 dimethylamine HKF parameters
6 LA19 D. E. LaRowe and J. P. Amend 2019 Geomicrobiol. J. 36, 492-505 dimethylamine, trimethylamine, resorcinol, phloroglucinol, cyclohexane carboxylate, and cyclohexane carboxylic acid
1 ST97 D. Shvedov and P. R. Tremaine 1997 J. Solution Chem. 26, 1113-1143 dimethylammonium chloride HKF parameters
6 DSM+97.2 J. D. Dale, E. L. Shock et al. 1997 Geochim. Cosmochim. Acta 61, 4017-4024 dimethylphenol isomers
AD03.2 N. N. Akinfiev and L. W. Diamond 2003 Geochim. Cosmochim. Acta 67, 613-629 dissolved gas species; parameters estimated from standard-state properties at 25 ° C
AD03.1 N. N. Akinfiev and L. W. Diamond 2003 Geochim. Cosmochim. Acta 67, 613-629 dissolved gas species; parameters estimated from the experimental Henry's constant
2 Sho93 E. L. Shock 1993 Geochim. Cosmochim. Acta 57, 3341-3349 ethylacetate and acetamide
15 LA16 D. E. LaRowe and J. P. Amend 2016 ISME J. 10, 1285-1295 fatty acids, saccharides, and other species
1 Pol90 D. A. Polya 1990 Trans. Inst. Min. Metall. 99, B120-B124 ferberite G, S and Cp (Cp coefficients multiplied by 4.184 to convert to J, as listed in @WS00, but who give a 2nd term that is off by a factor of 10). Cp at 25 °C is from @LW74.
1 Hel85 H. C. Helgeson 1985 Am. J. Sci. 285, 845-855 ferrosilite and siderite
DEW17.37 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet fit to Raman speciation and quartz solubility data
RH95.4 R. A. Robie and B. S. Hemingway 1995 U. S. Geological Survey Bull. 2131 fluorphlogopite (Al/Si disordered) (G and H not in SUPCRT92)
1 SLOP16.3 E. L. Shock et al. 2016 slop16.dat computer data file formaldehyde: "Entropy corrected to be compatible with the equation ΔH=ΔG+TΔS for the formation reaction from elements. See footnote i in table 2 of @SS93."
DEW17.101 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet formate and lactate: revised with new predicted a1 for ions
15 Kel60 K. K. Kelley 1960 U. S. Bureau of Mines Bull. 584 gases Cp
17 WEP+82 D. D. Wagman, W. H. Evans et al. 1982 J. Phys. Chem. Ref. Data 11, Suppl. 2, 1-392 gases GHS
1 RHF78.3 R. A. Robie, B. S. Hemingway and J. R. Fisher 1978 U. S. Geological Survey Bull. 1452 gibbsite GHS
2 Eva90 B. W. Evans 1990 Lithos 25, 3-23 glaucophane and pumpellyite
ZW07 S. P. Ziemer and E. M. Woolley 2007 J. Chem. Thermodynamics 39, 645-666 glutamate
HDM+94 A. W. Hakin et al. 1994 J. Chem. Soc., Faraday Trans. 90, 2027-2035 glutamic acid
4 Dic07 J. M. Dick 2007 Ph.D. Dissertation, Univ. of California glutathione, cystine, and cystine sidechain
DEW19.4 D. A. Sverjensky et al. 2019 Deep Earth Water (DEW) spreadsheet glycinate: @AH97b for the G, H, S, Cp, V
3 DLH06.3 J. M. Dick, D. E. LaRowe and H. C. Helgeson 2006 Biogeosciences 3, 311-336 glycine, [Gly], and [UPBB] HKF parameters
6 GKL02 R. N. Goldberg et al. 2002 J. Phys. Chem. Ref. Data 31, 231-370 glycine, diglycine, and triglycine (+1 and -1 ions) GHS
12 Kit14 N. Kitadai 2014 J. Mol. Evol. 78, 171-187 glycine, diglycine, and triglycine (zwitterions and ions); diketopiperazine, [Gly] and [UPBB] groups
3 MLS+03 J. Majzlan, B. E. Lang et al. 2003 Am. Mineral. 88, 846-854 goethite, lepidocrocite, and maghemite Cp
3 MGN03 J. Majzlan, K.-D. Grevel and A. Navrotsky 2003 Am. Mineral. 88, 855-859 goethite, lepidocrocite, and maghemite GHS
1 Kel60.3 K. K. Kelley 1960 U. S. Bureau of Mines Bull. 584 gypsum Cp
13 RH95 R. A. Robie and B. S. Hemingway 1995 U. S. Geological Survey Bull. 2131 gypsum, manganese, manganosite, pyrolusite, bixbyite, hausmannite, huebneritecobalt, cobalt monoxide, guite, cattierite, linnaeite, wustite, willemite, and zinc
5 DS10 J. Delgado Martin and A. Soler i Gil 2010 Eur. J. Mineral. 22, 363-380 hedenbergite, andradite, ferro-actinolite, grunerite, and ilvaite
3 SLOP16.7 E. L. Shock et al. 2016 slop16.dat computer data file hexanol, heptanol, and octanol: "Minor differences in Gibbs energy, entropy, ω, a1, a2, a3, a4 and c1 values compared to @SH90."
10 SLOP07.2 E. L. Shock et al. 2007 slop07.dat computer data file high-temperature HKF parameters from @AP01
1 LX20 Liu and Xiao 2020 Ore Geol. Rev. 117, 103289 huebnerite Cp
5 TSD97 Y. Tardy, R. Schaul, J. Duplay 1997 C. R. Acad. Sci. Paris 324, 969-976 humic acid, microflora, and plants
2 RH95.1 R. A. Robie and B. S. Hemingway 1995 U. S. Geological Survey Bull. 2131 hydrogen fluoride and hydrogen chloride
1 MSB+04 J. Majzlan, R. Stevens et al. 2004 Phys. Chem. Mineral. 31, 518-531 hydronium jarosite
14 SHS89 E. L. Shock, H. C. Helgeson and D. A. Sverjensky 1989 Geochim. Cosmochim. Acta 53, 2157-2183 inorganic neutral species
57 SH88 E. L. Shock and H. C. Helgeson 1988 Geochim. Cosmochim. Acta 52, 2009-2036 ionic species
HS19 F. Huang and D. A. Sverjensky 2019 Geochim. Cosmochim. Acta 254, 192-230 ions and metal complexes
4 RHF78.2 R. A. Robie, B. S. Hemingway and J. R. Fisher 1978 U. S. Geological Survey Bull. 1452 iron
1 Kel60.2 K. K. Kelley 1960 U. S. Bureau of Mines Bull. 584 iron Cp
DEW17.22 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet isobutane: G, H, S, Cp, V from @SH90; a1 estimated with @SHA14; c2 estimated with a new hydrocarbon correlation.
3 SAJ00 R. E. Stoffregen, C. N. Alpers and J. L. Jambor 2000 Rev. Mineral. Geochem. 40, 453-479 jarosite, natroalunite, and natrojarosite
6 HRMNS09 H. C. Helgeson, L. Richard et al. 2009 Geochim. Cosmochim. Acta 73, 594-695 kerogens (C128, C292, C406, C415, C515) and pyrobitumen (C54H42)
4 GM09 K.-D. Grevel and J. Majzlan 2009 Geochim. Cosmochim. Acta 73, 6805-6815 kieserite, starkeyite, hexahydrite, and epsomite
RH95.5 R. A. Robie and B. S. Hemingway 1995 U. S. Geological Survey Bull. 2131 larnite (G and H not in SUPCRT92); Cp from @Kel60
1 PK95 V. B. Parker and I. L. Khodakovskii 1995 J. Phys. Chem. Ref. Data 24, 1699-1745 melanterite
28 SPD+19 B. St Clair et al. 2019 ACS Earth Space Chem 3, 905-921 metal carbonate and bicarbonate complexes and FeSO4
92 SSH97 D. A. Sverjensky, E. L. Shock and H. C. Helgeson 1997 Geochim. Cosmochim. Acta 61, 1359-1412 metal complexes
104 SK93 E. L. Shock and C. M. Koretsky 1993 Geochim. Cosmochim. Acta 57, 4899-4922 metal-acetate complexes
MA07 L. Marini and M. Accornero 2007 Environ. Geol. 52, 1343-1363 metal-arsenate and metal-arsenite complexes; linked to properties of arsenate and arsenite from @SSWS97
43 AML10 M. Accornero, L. Marini and M. Lelli 2010 Appl. Geochem. 25, 242-260 metal-chromate complexes
151 PSK99 P. Prapaipong, E. L. Shock and C. M. Koretsky 1999 Geochim. Cosmochim. Acta 63, 2547-2577 metal-dicarboxylate complexes
22 AKAE19 M. R. Azadi et al. 2019 Fluid Phase Equilib. 480, 25-40 metal-glycinate complexes
226 SK95 E. L. Shock and C. M. Koretsky 1995 Geochim. Cosmochim. Acta 59, 1497-1532 metal-organic acid complexes
1 LD12.2 D. E. LaRowe and J. M. Dick 2012 Geochim. Cosmochim. Acta 80, 70-91 methionine GHS
1 DLH06.4 J. M. Dick, D. E. LaRowe and H. C. Helgeson 2006 Biogeosciences 3, 311-336 methionine HKF parameters
1 LD12.3 D. E. LaRowe and J. M. Dick 2012 Geochim. Cosmochim. Acta 80, 70-91 methionine sidechain GHS
2 HPT06 B. Hawrylak, R. Palepu and P. R. Tremaine 2006 J. Chem. Thermodynamics 38, 988-1007 methyldiethanolamine and methyldiethanolammonium chloride HKF parameters
58 HDNB78 H. C. Helgeson, J. M. Delany et al. 1978 Am. J. Sci. 278A, 1-229 minerals
65 Ber88 R. G. Berman 1988 J. Petrol. 29, 445-522 minerals
1 SLOP16.5 E. L. Shock et al. 2016 slop16.dat computer data file n-octanoate: "Enthalpy corrected to be compatible with the equation ΔG=ΔH-TΔS for the formation reaction from elements. See footnote ab in table 4 of @Sho95."
157 LH06a D. E. LaRowe and H. C. Helgeson 2006 Geochim. Cosmochim. Acta 70, 4680-4724 nucleic-acid bases, nucleosides, and nucleotides
81 RG11 L. Richard and X. Gaona 2011 Geochim. Cosmochim. Acta 75, 7304-7350 organic iodine compounds
398 HOKR98 H. C. Helgeson, C. E. Owens et al. 1998 Geochim. Cosmochim. Acta 62, 985-1081 organic molecules and groups
542 RH98 L. Richard and H. C. Helgeson 1998 Geochim. Cosmochim. Acta 62, 3591-3636 organic molecules and groups
47 SH90 E. L. Shock and H. C. Helgeson 1990 Geochim. Cosmochim. Acta 54, 915-945 organic species
7 Sch10 M. Schulte 2010 Aquat. Geochem. 16, 621-637 organic sulfides
137 Ric01 L. Richard 2001 Geochim. Cosmochim. Acta 65, 3827-3877 organic sulfur compounds
3 WV22 A. E. Williams-Jones and O. V. Vasyukova 2022 Econ. Geol. 117, 513-528 parameters listed here
14 RH95.7 R. A. Robie and B. S. Hemingway 1995 U. S. Geological Survey Bull. 2131 phase stability limit
6 DEH+13 J. M. Dick, K. A. Evans et al. 2013 Geochim. Cosmochim. Acta 122, 247-266 phenanthrene and methylphenanthrene isomers
4 DSM+97.1 J. D. Dale, E. L. Shock et al. 1997 Geochim. Cosmochim. Acta 61, 4017-4024 phenol, and cresol isomers
1 SHD91.1 D. A. Sverjensky, J. J. Hemley and W. M. D'Angelo 1991 Geochim. Cosmochim. Acta 55, 989-1004 phlogopite: H and S modified by @Ber90, followed by G and H revision for K-bearing silicates [after @SHD91]
41 SS98a D. C. Sassani and E. L. Shock 1998 Geochim. Cosmochim. Acta 62, 2643-2671 platinum-group ions and complexes
15 SS98a.1 D. C. Sassani and E. L. Shock 1998 Geochim. Cosmochim. Acta 62, 2643-2671 platinum-group solids
8 MVT01 L. Mercury, P. Vieillard. and Y. Tardy 2001 Appl. Geochem. 16, 161-181 polymorphs of ice
DEW17.34 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet propane: @SH90 with new a1-a4 based on revised correlation to predict a1 in Sverjensky et al. (2013)
DEW17.35 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet propanoate: Revised a1 from new delVn correlation for -1 ions
2 LH06b.1 D. E. LaRowe and H. C. Helgeson 2006 Thermochim. Acta 448, 82-106 pyridine and piperidine
20 OBIGT.6 J. M. Dick 2019 OBIGT database in CHNOSZ recalculated values of Cp (those in @AKAE19 appear to be calculated using wrong sign on ω) and enthalpy (using ΔG=ΔH-TΔS and the entropies of the elements)
DEW17.6 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet revised volume increased in order that a1 of the complex is the sum of the a1 values of the ions
DEW17.4 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet revised with a1 equal to the sum of the ions
DEW17.2 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet revised with new predicted a1 for cations
DEW17.3 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet revised with new predicted a1 for complex species
DEW17.1 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet revised with new predicted a1 for ions
SHA14.1 D. A. Sverjensky et al. 2014 Geochim. Cosmochim. Acta 129, 125-145 revisions for AlO2- and HAlO2
BH83 T. S. Bowers and H. C. Helgeson 1983 Geochim. Cosmochim. Acta 47, 1247-1275 rutile
RHF78.4 R. A. Robie, B. S. Hemingway and J. R. Fisher 1978 U. S. Geological Survey Bull. 1452 rutile and titanite
1 LXW21.1 X. Liu, C. Xiao and Y. Wang 2021 Chem. Geol. 584, 120488 scheelite Cp
2 WS00 S. A. Wood and I. M. Samson 2000 Econ. Geol. 95, 143-182 scheelite and ferberite; GHS and V of scheelite and V of ferberite are from @RHF78.
2 LMR06 D. Langmuir et al. 2006 Geochim. Cosmochim. Acta 70, 2942-2956 scorodite and amorphous ferric arsenate: G
3 AS01.1 J. P. Amend and E. L. Shock 2001 FEMS Microbiol. Rev. 25, 175-243 selenium and molybdenite
1 VGT92 O. Vidal, B. Goffé and T. Theye 1992 J. Metamorphic Geol. 10, 603-614 sudoite
3 MS97.1 T. M. McCollom and E. L. Shock 1997 Geochim. Cosmochim. Acta 61, 4375-4391 sulfur
SPRONS92.1 H. C. Helgeson et al. 1992 sprons92.dat computer data file titanite: @BH83 + "Gibbs free energies and enthalpies were corrected to be consistent with updated values of Gibbs free energies of Ca2+ and CO32- [@SH88] together with the solubilities of calcite and aragonite reported by @PB82 "
DEW17.39 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet toluene: @PS01 with new a1 to a4 predicted with revised a1 consistent with @SHA14
1 DLH06.5 J. M. Dick, D. E. LaRowe and H. C. Helgeson 2006 Biogeosciences 3, 311-336 triglycine Cp, V, and HKF c1, c2, ω parameters
1 PD15 G. S. Pokrovski and J. Dubessy 2015 Earth Planet. Sci. Lett. 411, 298-309 trisulfur radical ion
4 LD12.1 D. E. LaRowe and J. M. Dick 2012 Geochim. Cosmochim. Acta 80, 70-91 updated and corrected parameters for cysteine, glycine, leucine, and methionine
1 SSB97.1 E. L. Shock, D. C. Sassani and H. Betz 1997 Geochim. Cosmochim. Acta 61, 4245-4266 uraninite
15 SSB97 E. L. Shock, D. C. Sassani and H. Betz 1997 Geochim. Cosmochim. Acta 61, 4245-4266 uranium species
DEW17.40 D. A. Sverjensky et al. 2017 Deep Earth Water (DEW) spreadsheet urea: Revised Feb. 2015 by Dimitri: c1, c2, and omega from PS01 based on Stokes (1967) data; V from Cabani et al. (1981) with a1-a4 predicted.
25 SH88.1 E. L. Shock and H. C. Helgeson 1988 Geochim. Cosmochim. Acta 52, 2009-2036 values of GHS
1 BKK77 I. Barin, O. Knacke and O. Kubaschewski 1977 Thermochemical Properties of Inorganic Substances: Supplement willemite Cp
2 SSWS97.1 E. L. Shock, D. C. Sassani et al. 1997 Geochim. Cosmochim. Acta 61, 907-950 zincite and litharge
1 SLOP98.1 E. L. Shock et al. 1998 slop98.dat computer data file zincite and litharge; "These data were used in @SSWS97, but were not tabulated in the paper."
4 Got04 M. Gottschalk 2004 Rev. Mineral. Geochem. 56, 83-124 zoisite, clinozoisite, and epidote