Hostname: page-component-586b7cd67f-g8jcs Total loading time: 0 Render date: 2024-11-22T06:00:35.034Z Has data issue: false hasContentIssue false

A brief comment on Hawthorne (2023): “On the definition of distinct mineral species: A critique of current IMA-CNMNC procedures”

Published online by Cambridge University Press:  24 May 2023

Ferdinando Bosi*
Affiliation:
Department of Earth Sciences, Sapienza University of Roma, Piazzale Aldo Moro 5, I-00185 Rome, Italy
Frédéric Hatert
Affiliation:
Laboratory of Mineralogy, University of Liège, Bâtiment B-18, B-4000 Liège, Belgium
Marco Pasero
Affiliation:
Department of Earth Sciences, University of Pisa, Via S. Maria 53, I-56126 Pisa, Italy
Stuart J. Mills
Affiliation:
Geosciences, Museums Victoria, P.O. Box 666, Melbourne, Victoria 3001, Australia
Ritsuro Miyawaki
Affiliation:
Department of Geology and Paleontology, The National Museum of Nature and Science, 4-1-1, Amakubo, Tsukuba 305-0005, Japan
Ulf Hålenius
Affiliation:
Department of Geosciences, Swedish Museum of Natural History, P.O. Box 50 007, SE-104 05 Stockholm, Sweden
*
Corresponding author: Ferdinando Bosi; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

In this communication we present a brief response to Hawthorne (2023) who, in a paper in volume 87, doi.org/10.1180/mgm.2023.8 (this journal), claims evidence for violations of the electroneutrality principle in mineral formulae derived through IMA–CNMNC procedures: i.e. the dominant-constituent rule, the valency-imposed double site-occupancy, the dominant-valency rule, and the site-total-charge approach (STC).

His statement is not correct as the STC method is based on the end-member definition; thus, it cannot violate the requirements of an end-member, particularly the laws of conservation of electric charge. The STC was developed to address the shortcomings in the previous IMA–CNMNC procedures.

The real question is: which method to use to define an end-member formula? Currently, there are two approaches: (1) STC, which first identifies the dominant end-member charge arrangement and then leads to the dominant end-member composition; (2) the dominant end-member approach.

Type
Comment
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of The Mineralogical Society of the United Kingdom and Ireland

Introduction

We are commenting on a paper (Hawthorne, Reference Hawthorne2023) in which the author expressed criticisms about the procedures of the Commission on New Minerals, Nomenclature and Classification (CNMNC) of the International Mineralogical Association (IMA) for the definition of a new mineral species. Hawthorne (Reference Hawthorne2023) stated that the dominant-constituent rule, the valency-imposed double site-occupancy, the dominant-valency rule, and the site-total-charge (STC) approach can violate the laws of conservation of electric charge. Thus, according to this author, the chemical formulae resulting from application of the IMA–CNMNC rules can violate the requirements of an end-member, particularly that of electroneutrality, and these cannot derive end-member formulae for some groups of minerals.

In this discussion, we will show that such a statement is incorrect.

Discussion

The STC method (Bosi et al., Reference Bosi, Hatert, Hålenius, Pasero, Miyawaki and Mills2019a, Reference Bosi, Biagioni and Oberti2019b) is based on the end-member definition, thus it cannot violate the requirements of an end-member, particularly the laws of conservation of electric charge, by definition. The application of the STC method is divided in two steps: one, identifying the dominant end-member charge arrangement from the empirical formula, and two, deriving the dominant end-member formula from this end-member charge arrangement. There are several examples where the STC method was successfully applied to obtain end-member formulae, including those related to the complex chemistry of pyrochlore-supergroup minerals (Bhattacharjee et al., Reference Bhattacharjee, Dey, Chakarabarty, Mitchell and Ren2022).

Hawthorne (Reference Hawthorne2023) nicely discusses specific examples where the dominant-constituent rule and dominant-valency rule lead to non-electroneutral formulae, thus violating the conservation of electric charge. However, the application of the dominant-constituent rule, the valency-imposed double site-occupancy, and the dominant-valency rule generally leads to valid end-member formulae (Hatert and Burke, Reference Hatert and Burke2008). Moreover, it is important to note that the deficiency in these IMA–CNMNC rules was already noted by Bosi (Reference Bosi2018) and successively addressed by the CNMNC with the paper by Bosi et al. (Reference Bosi, Hatert, Hålenius, Pasero, Miyawaki and Mills2019a). In fact, Hawthorne (Reference Hawthorne2023) could show only examples of minerals with end-member formulae derived from the STC method.

In this regard, it is instructive to show a misunderstanding by Hawthorne (Reference Hawthorne2023) on the STC method. This author states that “There is a degree of arbitrariness in picking the integer number close or next to the observed site total. For example, Bosi et al. (Reference Bosi, Biagioni and Oberti2019b) consider the composition KM(Li1.49Mn3+1.02Al0.49)Si4O10A(O1.02F0.98) intermediate between norrishite, ideally KM(LiMn3+2)Si4O10AO2, and polylithionite, ideally KM(Li2Al)Si4O10AF2. The relevant sums of the STC are M6.02+ and A3.02–, and Bosi et al. (Reference Bosi, Biagioni and Oberti2019b) arbitrarily pick the alternative values M7+ and A4– and assign the end-member as norrishite. However, according to the explanation of the STC method that they provide, they could also have picked the STC pair M5+ and A2– to give the end-member as polylithionite. The STC values of the empirical formula are slightly closer to those of norrishite than those of polylithionite, but this is not given as a criterion in the rule”.

However, reading the papers by Bosi (Reference Bosi, Hatert, Hålenius, Pasero, Miyawaki and Mills2019a, Reference Bosi, Biagioni and Oberti2019b), it becomes clear that there is no arbitrariness in picking integer numbers, instead of this is a mathematically-driven procedure: an integer number must be selected for which possible charge and atomic arrangements can be identified in accord with mineral composition. If (and only if) those arrangements satisfy all the criteria of an end-member, the mineral formula may be defined. Note that if the integer number closest to the STC is not consistent with an end-member, because of lack of consideration of all the potential end-members involved in the chemical substitution and/or the degree of atom disorder over structural sites, another integer number in line with the end-member definition must be selected.

To complete the information on the mica example given above, we report what is written in Bosi et al. (Reference Bosi, Biagioni and Oberti2019b). Minerals occurring between norrishite, KM(LiMn3+2)Si4O10A(O)2, and polylithionite, KM(Li2Al)Si4O10A(F)2, are related by the substitution:

$$\eqalign{^{\rm M} ( {\rm Li} + 2{\rm M}{\rm n}^{3 + }) ^{\Sigma 7 + } + \ ^{\rm A}\!\!( 2{\rm O}^{2- }) ^{\Sigma 4- } \cr =\; ^{\rm M}\!\!( {2{\rm Li} + {\rm Al}} ) ^{\Sigma 5 + } +\ ^{\rm A}\!\!( {2{\rm F}^- } ) ^{\Sigma 2- }.}$$

The boundary between these two minerals lies at the composition KM(Li1.5Mn3+1.0Al0.5)Σ6+Si4O10A(OF)Σ3–, corresponding to the sum of charges M6+ and A3–. Thus, mineral compositions with M > +6 and A < –3 belong to the norrishite compositional field, whereas those with STC for the M < +6 and A > –3 belong to the polylithionite field. Consider the hypothetical norrishite composition KM(Li1.49Mn3+1.02Al0.49)Si4O10A(O1.02F0.98) with M6.02+ and A3.02–, very close to the integer numbers +6 and –3. These numbers are compatible with the atomic arrangements M(Li1.50R3+1.50)Σ6+ and A(O1.00F1.00)Σ3–, but such arrangements are inconsistent with the end-member definition (double occupancy of two sites). In order to identify the end-member formula, we need to consider integer numbers next to +6 and –3, that is, +7 and –4 which are compatible with M(Li1.00R3+2.00)Σ7+ and A(O2.00)Σ4–, leading to the end-member K(LiMn3+2)Si4O10(O)2, that is norrishite.

What can we learn from this example?

(1) The STD method always leads to a charge-balanced mineral formula, which in this case corresponds to that defined by the end-member approach (51% norrishite and 49% polylithionite).

(2) The end-member formula is an overriding condition to identify minerals, something that Bosi et al. (Reference Bosi, Hatert, Hålenius, Pasero, Miyawaki and Mills2019a, Reference Bosi, Biagioni and Oberti2019b) mentioned in their papers but which seems to have been overlooked by Hawthorne (Reference Hawthorne2023) who cited their results.

Other inconsistencies are reported by Hawthorne (Reference Hawthorne2023), but they need a separate paper to be addressed. The purpose of this discussion is (1) to point out that Hawthorne (Reference Hawthorne2023) criticises things already known in the mineralogical literature, and (2) to reiterate that the STC method does not violate any fundamental law of Physics.

Real discussion point

As already pointed out by Bosi et al. (Reference Bosi, Hatert, Hålenius, Pasero, Miyawaki and Mills2019a, Reference Bosi, Biagioni and Oberti2019b), the real discussion is how to define the end-member formula of minerals, and this can be achieved through two different approaches: (1) the STC approach, and (2) the dominant end-member approach. Graphically, figure 1 from Bosi et al. (Reference Bosi, Hatert, Hålenius, Pasero, Miyawaki and Mills2019a), which is also repeated by Hawthorne (Reference Hawthorne2023) for the feldspar system, shows the fundamental differences between these two approaches, and how they are relevant only for particular intermediate compositions.

The next step is to decide which of these two approaches best reflects the mineral properties. Currently, the CNMNC recommends the STC approach (coupled with the dominant-constituent and dominant-valency rules) as it overcomes the fundamental flaw introduced in some cases by the previous IMA–CNMNC rules.

The simple example by Hawthorne (Reference Hawthorne2023), on the hypothetical compound with a composition (Ca0.40Sc0.35Y0.25)(S0.4P0.6)O4, perfectly demonstrates the essential differences between the two approaches. With respect to the root composition ScPO4 (arbitrarily chosen), the relations between end-member constituents in terms of ion replacements are as follows: Y3+ → Sc3+ gives YPO4 and Ca2+ + P5– → Y3+ + S6– gives CaSO4. By applying the end-member approach, the following end-member compositions may be obtained: 40% CaSO4, 35% ScPO4 and 25% YPO4, thus leading to CaSO4 as the dominant end-member. However, the dominant cation at the tetrahedrally-coordinated sites is P5+, so why should we not consider this sample as a phosphate? By applying the dominant-valency rule, the larger trivalent REE cations are dominant at non-tetrahedrally coordinated sites, and among them, Sc3+ is the dominant cation. This mineral may consequently be regarded as [(Sc,Y),Ca](P,S)O4, a Y-, Ca- and S-bearing ScPO4: a phosphate, indeed. In this regard, it is also interesting to consider the effect of homovalent and heterovalent substitutions on the bond-valence variations that correlate with some mineral properties such as thermal expansion and force constant (Brown, Reference Brown2016). Homovalent substitutions generally introduce only slight changes in bond valences due to relaxation of bond distances, whereas heterovalent substitutions produce significant changes in the pattern of bond valences due to the different arrangements of formal charges in the structure (Gagné and Hawthorne, Reference Gagné and Hawthorne2016). Hence, a homovalent substitution such as Sc3+ → Y3+ is expected to produce a smaller variation in the mineral properties than a heterovalent substitution such as Ca2+ + P5– → (Y,Sc)3+ + S6–.

As a final comment, it should be noted that the CNMNC does not aim at imposing an arbitrary set of rigid rules on the mineralogical community, but rather at defining a set of coherent guidelines that provide a reasonably consistent approach for the introduction of new minerals and the application of mineral nomenclature (Nickel and Grice, Reference Nickel and Grice1998). Exceptions to the CNMNC rules are possible and welcome if soundly argued, as Nature does not read mineralogical papers. In this regard, it is important to note that CNMNC welcomes proposals that may improve existing procedures, mineral classification and mineral nomenclature. Constructive proposals for alternative improved procedures are always desirable. CNMNC is an IMA Commission with elected representatives from national mineralogical societies. The proper places for constructive discussions on matters handled by the CNMNC would primarily be those societies and through their representatives in CNMNC.

Footnotes

Associate Editor: Sergey V Krivovichev

References

Bhattacharjee, S., Dey, M., Chakarabarty, A., Mitchell, R.H. and Ren, M. (2022) Zero-valent-dominant pyrochlores: Endmember formula calculation and petrogenetic significance. The Canadian Mineralogist, 60, 469484.Google Scholar
Bosi, F. (2018) On the mineral nomenclatures: the dominant-valency rule. Abstract to XXII meeting of the IMA, Melbourne, Australia, p. 354.Google Scholar
Bosi, F., Hatert, F., Hålenius, U., Pasero, M., Miyawaki, R. and Mills, S.J. (2019a) On the application of the IMA-CNMNC dominant-valency rule to complex mineral compositions. Mineralogical Magazine, 83, 627632.Google Scholar
Bosi, F., Biagioni, C. and Oberti, R. (2019b) On the chemical identification and classification of minerals. Minerals, 9, 591.CrossRefGoogle Scholar
Brown, I.D. (2016) The Chemical Bond in Inorganic Chemistry: The Bond Valence Model. International Union of Crystallography Monographs on Crystallography, vol. 12, Oxford University Press, UK, 352 pp.Google Scholar
Gagné, O.C. and Hawthorne, F.C. (2016) Chemographic exploration of the milarite-type structure, The Canadian Mineralogist, 54, 12291247.Google Scholar
Hatert, F. and Burke, E.A.J. (2008) The IMA–CNMNC dominant-constituent rule revisited and extended. The Canadian Mineralogist, 46, 717728.Google Scholar
Hawthorne, F.C. (2023) On the definition of distinct mineral species: A critique of current IMA-CNMNC procedures. Mineralogical Magazine, 87, 494–504, doi.org/10.1180/mgm.2023.8.Google Scholar
Nickel, E.H. and Grice, J.D. (1998) The IMA commission on new minerals and mineral names: procedures and guidelines on mineral nomenclature. The Canadian Mineralogist, 36, 913926.Google Scholar