Changes to the cerite group nomenclature

Atencio, Daniel; Azzi, Andrezza A.; Qu, Kai; Miyawaki, Ritsuro; Bosi, Ferdinando; Momma, Koichi

doi:https://doi.org/10.5194/ejm-35-1027-2023

Articles | Volume 35, issue 6

https://doi.org/10.5194/ejm-35-1027-2023

Special issue:

New minerals, nomenclature, and classification: EJM support

https://doi.org/10.5194/ejm-35-1027-2023

Articles | Volume 35, issue 6

Research article

23 Nov 2023

Research article |

| 23 Nov 2023

Changes to the cerite group nomenclature

Daniel Atencio, Andrezza A. Azzi, Kai Qu, Ritsuro Miyawaki, Ferdinando Bosi, and Koichi Momma

Abstract

The cerite and merrillite groups belong to the cerite supergroup. Some nomenclature and classification changes have been made to the cerite group, whereas the merrillite group remains unchanged. Minerals of the cerite group have the general formula A₉XM[T₇O₂₄Ø₄]Z₃, where T is Si. The cerite group, from now on, is subdivided into two subgroups, cerite and taipingite. The root name will be cerite and taipingite if the Z anions are dominated by (OH) and F, respectively. The prefix ferri- or alumino- will be added if the M cations are dominated by Fe³⁺ or Al, respectively. If the M cation is Mg, there will be no prefix. Taking into account the valency-imposed double site occupancy and the site total charge approach, a double suffix will be used to represent the essential A constituents in the general chemical formula. Cerite-(Ce), aluminocerite-(Ce), ferricerite-(La), and taipingite-(Ce) have been renamed cerite-(CeCa), aluminocerite-(CeCa), ferricerite-(LaCa), and taipingite-(CeCa), respectively. The newly approved mineral aluminotaipingite-(CeCa) also belongs to the taipingite subgroup.

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Dates

Received: 27 Jul 2023 – Revised: 06 Oct 2023 – Accepted: 13 Oct 2023 – Published: 23 Nov 2023

Table 1Ideal formula, dominant constituents in the general chemical formula, and unit-cell parameters (R3c) for the cerite supergroup minerals.

¹ Moore and Shen (1983). ² Pakhomovsky et al. (2002). ³ Nestola et al. (2009). ⁴ Qu et al. (2020). ⁵ Campostrini et al. (2023). ⁶ Xie et al. (2015). ⁷ Britvin et al. (2016). ⁸ Britvin et al. (2021). ⁹ Hwang et al. (2019). ¹⁰ Galuskin et al. (2023). ¹¹ Li et al. (2022). ¹² Calvo and Gopal (1975). ¹³ Britvin et al. (1991). ¹⁴ Witzke et al. (2015). ¹⁵ Cooper et al. (2013).

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The cerite supergroup (Atencio and Azzi, 2020) consists of two groups of isostructural trigonal R3c (no. 161) minerals, namely, cerite (silicates) and merrillite (phosphates) groups. The merrillite group is subdivided into two subgroups: merrillite (without OH in the Ø site) and whitlockite (with OH in the Ø site). The nomenclature introduced by Atencio and Azzi (2020) is based on the dominant species of the dominant valence at each site.

The recent discoveries of four new members in the cerite group, following the four valid members already approved, make it necessary to revise the nomenclature of this group. One of these new species, aluminotaipingite-(CeCa) IMA2022-126, has already been approved by the CNMNC-IMA (Commission on New Minerals, Nomenclature and Classification of the International Mineralogical Association) and published (Campostrini et al., 2023); two are under review by the CNMNC-IMA; and one is under study.

The crystal structure of these minerals involves three 8- and 9-fold coordinated A sites, one 6-fold coordinated X site, one octahedral M site, and three [TO₃(Ø)] tetrahedral groups. The crystal structure of cerite supergroup minerals consists of [M(TO₄)₆] clusters linked by {A₉X(TO₃Ø)} groups.

The general chemical formula of cerite supergroup minerals is A₉XM[T₇O₂₄Ø₄]Z₃, where the letters, except for O for oxygen, represent groups of atoms (and not structural sites) on which to apply the dominant constituent and valency rule and the endmember concept. A = REE, Ca, Sr, Na, and □; X = □, Ca, Na, and Fe²⁺; M = Mg, Fe²⁺, Fe³⁺, Al, and Mn; T = Si and P; Ø = O and OH; and Z = □, OH, and F, where REE is rare earth elements of yttrium and lanthanoids (La–Lu) (Atencio and Azzi, 2020). The general structural formula of cerite supergroup minerals is A1₃A2₃A3₃XM1[T1₃T2₃T3O₂₄Ø1₃Ø10]Z1Z2Z3. The letter Z represents the set of anions occurring at three nonequivalent Z1, Z2, and Z3 sites; thus, the composition Z = F_1.8(OH)_1.2 is consistent with the endmember composition Z = F₃ (as F > OH). Grouping atoms over similar sites, such as A(1,2,3), T(1,2,3), and Z(1,2,3), helps prevent the proliferation of mineral species with endmember formulae based on the structural formula, where each structural sites can be used (Nickel and Grice, 1998) to define an endmember formula (Hawthorne, 2002). For example, the three independent anion Z sites may result in an endmember composition like F₂(OH). In this way, cerite nomenclature is based on the chemical formula, and, in principle, only the chemical information is needed for the mineral identification.

The cerite group, from now on, is subdivided into two subgroups, cerite and taipingite.

The root name will be cerite and taipingite if the Z anions are dominated by (OH) and F, respectively. The prefix ferri- or alumino- will be added if the M cations are dominated by Fe³⁺ or Al, respectively. If the M cation is Mg, there will be no prefix. Taking into account the valency-imposed double site occupancy (Hatert and Burke, 2008; Hatert et al., 2013) and the site total charge approach of Bosi et al. (2019), a double suffix will be used to represent the essential A constituents in the general chemical formula. Cerite-(Ce), aluminocerite-(Ce), ferricerite-(La), and taipingite-(Ce) have been renamed cerite-(CeCa), aluminocerite-(CeCa), ferricerite-(LaCa), and taipingite-(CeCa), respectively. The newly approved mineral aluminotaipingite-(CeCa) also belongs to the taipingite subgroup.

The charge balance of cerite group minerals is according to the following substitution mechanism: ^A[REE₈□]⁺²⁴ + ^M(Fe,Al)³⁺ = ^A[REE₆(Ca,Sr)₃]⁺²⁴ +^M(Fe,Al) $^{3 +} =^{A}$ [REE₇(Ca,Sr)₂]⁺²⁵ + ^M(Mg,Fe)²⁺.

The nomenclature of merrillite group remains as it current is. Table 1 summarizes all the currently valid species in the cerite supergroup.

Data availability

No data sets were used in this article.

Author contributions

All authors contributed to the conception of the project and the writing of the paper.

Competing interests

At least one of the (co-)authors is a guest member of the editorial board of European Journal of Mineralogy for the special issue “New minerals, nomenclature, and classification: EJM support”. The peer-review process was guided by an independent editor, and the authors also have no other competing interests to declare.

Disclaimer

Publisher’s note: Copernicus Publications remains neutral with regard to jurisdictional claims made in the text, published maps, institutional affiliations, or any other geographical representation in this paper. While Copernicus Publications makes every effort to include appropriate place names, the final responsibility lies with the authors.

Special issue statement

This article is part of the special issue “New minerals: EJM support”. It is not associated with a conference.

Acknowledgements

We acknowledge Sergey Krivovichev, Anthony Kampf, the anonymous referee, and all members of the IMA Commission on New Minerals, Nomenclature and Classification for their helpful suggestions and comments.

Financial support

This research has been supported by FAPESP (Fundação de Amparo à Pesquisa do Estado de São Paulo; project 2019/23498-0) and CNPq (Conselho Nacional de Desenvolvimento Científico e Tecnológico; project 303431/2019-9).

Review statement

This paper was edited by Sergey Krivovichev and reviewed by Anthony Kampf and one anonymous referee.

References

Atencio, D. and Azzi A. A.: Cerite: a new supergroup of minerals and cerite-(La) renamed ferricerite-(La), Mineral. Mag., 84, 928–931, 2020.

Bosi, F., Hatert, F., Hålenius, U., Pasero, M., Miyawaki, R., and Mills, S. J.: On the application of the IMA–CNMNC dominant-valency rule to complex mineral compositions, Mineral. Mag., 83, 627–632, 2019.

Britvin, S. N., Pakhomovskii, Y. A., Bogdanova, A. N., and Skiba, V. I.: Strontiowhitlockite, Sr₉Mg(PO₃OH)(PO₄)₆, a new mineral from the Kovdor deposit Kola Peninsula U.S.S.R, Can. Mineral., 29, 87–93, 1991.

Britvin, S. N., Krivovichev, S. V., and Armbruster, T.: Ferromerrillite, Ca₉NaFe²⁺(PO₄)₇, a new mineral from the Martian meteorites and some insights into merrillite–tuite transformation in shergottites, Eur. J. Mineral., 28, 125–136, 2016.

Britvin, S. N., Galuskina, I. O., Vlasenko, N. S., Vereshchagin, O. S., Bocharov, V. N., Krzhizhanovskaya, M. G., Shilovskikh, V. V., Galuskin, E. V., Vapnik, E. V., and Obolonskaya, E. V.: Keplerite, Ca₉(Ca_0.5□_0.5)Mg(PO₄)₇, a new meteoritic and terrestrial phosphate isomorphous with merrillite, Ca9NaMg(PO₄)₇, Am. Mineral., 106, 1917–1927, 2021.

Calvo, C. and Gopal, R.: The crystal structure of whitlockite from the Palermo quarry, Am. Mineral., 60, 120–133, 1975.

Campostrini, I., Demartin, F., Finello, G., and Vignola, P.: Aluminotaipingite-(CeCa), (Ce₆Ca₃)Al(SiO₄)₃[SiO₃(OH)]₄F₃, a new member of the cerite-supergroup minerals, Mineral. Mag., 87, 741–747, https://doi.org/10.1180/mgm.2023.51, 2023.

Cooper, M. A., Hawthorne, F. C., Abdu, Y. A., Ball, N. A., Ramik, R. A., and Tait, K. T.: Wopmayite, ideally Ca₆Na₃Mn(PO₄)₃(PO₃OH)₄, a new phosphate mineral from the Tanco Mine Bernic Lake Manitoba: description and crystal structure, Can. Mineral., 51, 93–106, 2013.

Galuskin, E. V., Stachowicz, M., Galuskina, I. O., Woźniak, K., Vapnik, Y., Murashko, M. N., and Zieliński, G.: Deynekoite, Ca₉Fe³⁺(PO₄)₇ – a new mineral of the merrillite group from phosphide-bearing contact facies of paralava, Hatrurim Complex, Daba-Siwaqa, Jordan. Mineral. Mag., https://doi.org/10.1180/mgm.2023.71, online first, 2023.

Hatert, F. and Burke, E. A. J.: The IMA-CNMNC dominant-constituent rule revisited and extended, Can. Mineral., 46, 717–728, 2008.

Hatert, F., Mills, S. J., Pasero, M., and Williams P. A.: CNMNC guidelines for the use of suffixes and prefixes in mineral nomenclature, and for the preservation of historical names, Eur. J. Mineral., 25, 113–115, https://doi.org/10.1127/0935-1221/2013/0025-2267, 2013.

Hawthorne, F. C.: The use of end-member charge-arrangements in defining new mineral species and heterovalent substitutions in complex minerals, Can. Mineral., 40, 699–710, 2002.

Hwang, S. L., Shen, P., Chu, H. T., Yui, T. F., Varela, M. E., and Iizuka, Y.: New minerals tsangpoite Ca₅(PO₄)₂(SiO₄) and matyhite Ca₉(Ca_0.5□_0.5)Fe(PO₄)₇ from the D'Orbigny angrite, Mineral. Mag., 83, 293–313, 2019.

Li, T., Li, Z., Huang, Z., Zhong, J., Fan, G., Guo, D., Qin, M., Zhang, J., Li, J., Liu, H., Qiu, L., Wang, F., He, S., Yu, A., Liu, R., Wu, Y., Deng, L., Tai, Z., He, Y., and Lin, Y.: Changesite-(Y), IMA 2022-023, in: CNMNC Newsletter 69, Eur. J. Mineral., 34, https://doi.org/10.5194/ejm-34-463-2022, 2022.

Moore, P. B. and Shen, J. C.: Cerite, RE9 (Fe³⁺,Mg)(SiO₄)₆(SiO₃OH)(OH)₃: Its crystal structure and relation to whitlockite, Am. Mineral., 68, 996–1003, 1983.

Nestola, F., Guastoni, A., Cámara, F., Secco, L., Dal Negro, A., Pedron, D., and Beran, A.: Aluminocerite-Ce: A new species from Baveno, Italy: Description and crystal-structure determination, Am. Mineral., 94, 487–493, 2009.

Nickel, E. H. and Grice, J. D.: The IMA Commission on New Minerals and Mineral Names: procedures and guidelines on mineral nomenclature, Can. Mineral., 36, 913–926, 1998.

Pakhomovsky, Y. A., Men'Shikov, Y. P., Yakovenchuk, V. N., Ivanyuk, G. Y., Krivovichev, S. V., and Burns, P. C.: Cerite-(La), (La,Ce,Ca)₉(Fe,Ca,Mg)(SiO₄)₃[SiO₃(OH)]₄(OH)₃, a new mineral species from the khibina alkaline massif: occurrence and crystal structure, Can. Mineral., 40, 1177–1184, 2002.

Qu, K., Sima, X. Z., Fan, G., Li, G. W., Shen, G. F., Chen, H. K., Liu, X., Yin, Q. Q., Li, T., and Wang, Y. J.: Taipingite-(Ce), (Ce₇Ca₂)∑₉Mg(SiO₄)₃[SiO₃(OH)]₄F₃, a new mineral from the Taipingzhen REE deposit, North Qinling Orogen, Central China, Geosci. Front., 11, 2339–2346, 2020.

Xie, X., Yang, H., Gu, X., and Downs, R. T.: Chemical composition and crystal structure of merrillite from the Suizhou meteorite, Am. Mineral., 100, 2753–2756, 2015.

Witzke, T., Phillips, B. L., Woerner, W., Coutinho, J. M. V., Färber, G., and Contreira Filho, R. R.: Hedegaardite, IMA 2014-069, in: CNMNC Newsletter 23, Mineral. Mag., 79, 51–58, 2015.

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