{"refrec":{"BRefID":353667,"RR":"<b>Humphreys, M.P.; Waters, J.F.; Turner, D.R.; Dickson, A.G.; Clegg, S.L.</b> (2022). Chemical speciation models based upon the Pitzer activity coefficient equations, including the propagation of uncertainties: Artificial seawater from 0 to 45 °C. <i>Mar. Chem. 244</i>: 104095. <a href=\"https://dx.doi.org/10.1016/j.marchem.2022.104095\" target=\"_blank\">https://dx.doi.org/10.1016/j.marchem.2022.104095</a>","BEntID":351377,"PublicFlag":1,"CheckedFlag":0,"wosflag":1,"vabbflag":1,"RefStringPartII":". <i>Mar. Chem. 244</i>: 104095. <a href=\"https://dx.doi.org/10.1016/j.marchem.2022.104095\" target=\"_blank\">https://dx.doi.org/10.1016/j.marchem.2022.104095</a>","DocTypID":8,"DocType":"Journal article","MarineFlag":0,"FreshFlag":0,"BrackishFlag":0,"TerrestrialFlag":0,"Authorstring":"Humphreys, M.P.; Waters, J.F.; Turner, D.R.; Dickson, A.G.; Clegg, S.L.","OrigTitleTranslFlag":0,"Authorstringtrunc":"Humphreys, M.P. <i>et al.</i>","Englishabstract":"<p>    Accurate    <a        href=\"https://www.sciencedirect.com/topics/chemistry/chemical-speciation\"        title=\"Learn more about chemical speciation from ScienceDirect's AI-generated Topic Pages\"    >        chemical speciation    </a>    models of solutions containing the ions of    <a        href=\"https://www.sciencedirect.com/topics/chemistry/seawater\"        title=\"Learn more about seawater from ScienceDirect's AI-generated Topic Pages\"    >        seawater    </a>    have applications in the calculation of    <a        href=\"https://www.sciencedirect.com/topics/earth-and-planetary-sciences/carbonate-system\"        title=\"Learn more about carbonate system from ScienceDirect's AI-generated Topic Pages\"    >        carbonate system    </a>    equilibria and trace metal speciation in natural waters, and the    determination of pH. Existing models, based on the Pitzer formalism for the    calculation of    <a        href=\"https://www.sciencedirect.com/topics/earth-and-planetary-sciences/activity-coefficient\"        title=\"Learn more about activity coefficients from ScienceDirect's AI-generated Topic Pages\"    >        activity coefficients    </a>    , do not yet agree with key experimental data (potentiometric    determinations of H<sup>+</sup> and Cl<sup>−</sup> activity products in    acidified artificial seawaters) and, critically, do not include uncertainty    estimates. This hampers applications of the models, and also their further    development (for which the uncertainty contributions of individual ion    interactions and    <a        href=\"https://www.sciencedirect.com/topics/chemistry/equilibrium-constant\"        title=\"Learn more about equilibrium constants from ScienceDirect's AI-generated Topic Pages\"    >        equilibrium constants    </a>    need to be known). We have therefore implemented the models of Waters and    Millero (Mar. Chem. 149, 8-22, 2013) and Clegg and Whitfield (Geochim. et    Cosmochim. Acta 59, 2403-2421, 1995) for artificial seawater, within a    generalised treatment of uncertainties, as a first step towards a more    complete model of standard seawater and pH buffers. This addition to the    models enables both the total uncertainty of any model-calculated quantity    (e.g., pH, speciation) to be estimated, and also the contributions of all    interaction parameters and equilibrium constants. Both models have been    fully documented (and some corrections made). Estimates of the variances    and covariances of the interaction parameters were obtained by    <a        href=\"https://www.sciencedirect.com/topics/chemistry/monte-carlo-method\"        title=\"Learn more about Monte Carlo simulation from ScienceDirect's AI-generated Topic Pages\"    >        Monte Carlo simulation    </a>    , with simplifying assumptions. The models were tested against measured    <a        href=\"https://www.sciencedirect.com/topics/chemistry/electromotive-force\"        title=\"Learn more about electromotive forces from ScienceDirect's AI-generated Topic Pages\"    >        electromotive forces    </a>    (EMFs) of cells containing acidified artificial seawaters. The mean offsets    (measured – calculated) at 25 °C for the model of Waters and Millero are:    0.046 ± 0.11 mV (artificial seawater without    <a        href=\"https://www.sciencedirect.com/topics/earth-and-planetary-sciences/sulphate\"        title=\"Learn more about sulphate from ScienceDirect's AI-generated Topic Pages\"    >        sulphate    </a>    , 0.280 mol kg<sup>−1</sup> to 0.879 mol kg<sup>−1</sup> ionic strength);    and −0.199 ± 0.070 mV (artificial seawater, salinities 5 to 45). Results    are similar at other temperatures. These differences compare with an    overall uncertainty in the measured EMFs of about 0.04 mV. Total    uncertainties for calculated EMFs of the solutions were dominated by just afew contributions: mainly H<sup>+</sup>-Cl<sup>−</sup>, Na<sup>+</sup>-Cl    <sup>−</sup>, and H<sup>+</sup>-Na<sup>+</sup>-Cl<sup>−</sup>    <a        href=\"https://www.sciencedirect.com/topics/earth-and-planetary-sciences/ionic-interaction\"        title=\"Learn more about ionic interactions from ScienceDirect's AI-generated Topic Pages\"    >        ionic interactions    </a>    , and the thermodynamic    <a        href=\"https://www.sciencedirect.com/topics/chemistry/dissociation-constant\"        title=\"Learn more about dissociation constant from ScienceDirect's AI-generated Topic Pages\"    >        dissociation constant    </a>    of HSO<sub>4</sub><sup>−</sup>. This makes it likely that the accuracy of    the models can readily be improved, and recommendations for further work    are made. It is shown that standard EMFs used in the calibration of the    marine ‘total’ pH scale can be accurately predicted with only slight    modification to the original models, suggesting that they can contribute to    the extension of the scale to lower salinities.</p>","AbstractOtherLang":null,"BibLvlCode":"AS","StandardTitle":"Chemical speciation models based upon the Pitzer activity coefficient equations, including the propagation of uncertainties: Artificial seawater from 0 to 45 °C","OrigTitleLangCode":"en","OrigTitleLangCodeExtended":"eng","OrigTitleLangID":15,"DateLastModified":{"date":"2026-06-10 01:32:44.073051","timezone_type":1,"timezone":"+02:00"},"UserAccessRight":null,"UserAccID":null,"AuthorKeywords":"Seawater; Chemical speciation; Activity coefficient; pH","OtherDescriptors":null,"Notes":null,"AnaPub":2022,"MonPub":null,"DateUpdate":"2022-07-12","DateCreate":"2022-07-12","SecASFANote":null,"ConfID":null,"PeerRev":1,"VlizCoreFlag":1,"WoScode":"WOS:000861495100003","VABBcode":null,"OpenAcc":1,"DOI":"10.1016/j.marchem.2022.104095"},"refs":null,"anarec":{"AnaID":353667,"PubliDate":2022,"Pagination":"104095","XtraPublOfAnaID":null,"ISBN":null,"Volume":"244","Issue":null,"BRefMon":null,"BRefMonRR":null,"BRefXtra":null,"BRefXtraRR":null,"SerBRefID":43353,"SerRR":"Marine Chemistry. Elsevier: Amsterdam.  ISSN 0304-4203; e-ISSN 1872-7581","StandardTitleSer":"Marine Chemistry","ISSN":"0304-4203","AbbrevSer":"Mar. 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