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Discussion of the paper by Galuskin and Galuskina (2003), “Evidence of the anthropogenic origin of the ‘Carmel sapphire’ with enigmatic super-reduced minerals”

Published online by Cambridge University Press:  24 May 2023

William L. Griffin*
Affiliation:
ARC Centre of Excellence for Core to Crust Fluid Systems (CCFS) and GEMOC, School of Natural Sciences, Macquarie University, NSW 2109, Australia
Vered Toledo
Affiliation:
Independent Researcher, Netanya 4210602, Israel, Email: vered.toledo1@gmail.com
Suzanne Y. O'Reilly
Affiliation:
ARC Centre of Excellence for Core to Crust Fluid Systems (CCFS) and GEMOC, School of Natural Sciences, Macquarie University, NSW 2109, Australia
*
Corresponding author: William L. Griffin; Email: bill.griffin@mq.edu.au
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Abstract

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

We thank the Galuskins for their detailed study of the explosion breccias and the nitrides included in corundum aggregates from Mt Carmel; space considerations have limited our previous publication of such detailed data on this interesting aspect of these important samples. Their images of other samples of the ‘Carmel Sapphire’ are a useful supplement to those we have published elsewhere.

However, we deem it necessary to correct some unfortunate mistakes in the presentation. These do not affect the descriptions of the images but can improve the usefulness of the article. Material in quotation marks are from the manuscript in Mineralogical Magazine, vol. 87, https://doi.org/10.1180/mgm.2023.25 by Galuskin and Galuskina (Reference Galuskin and Galuskina2023).

1. The authors do not identify the location of their sample (there is no “Carmel locality at the Kishon River”), the methods by which it was obtained, nor the other minerals found in the heavy concentrate. This is unfortunate because it would have improved the scientific usefulness of the paper.

2. “Typically the Carmel Sapphire is in small fragments of breccia with white cement”. This is incorrect; the vast bulk of Carmel sapphire grains investigated by us have no coating and are not associated with the breccias.

3. “skeletal osbornite occurring as inclusions in corundum”. The illustrated nitrides are not ‘skeletal crystals’ – they may appear to be so because they are controlled by crystallographically controlled void spaces in skeletal corundum (Griffin et al., Reference Griffin, Gain, Adams, Huang, Saunders, Toledo, Pearson and O'Reilly2016; Reference Griffin, Gain, Saunders, Alard, Shaw, Toledo and O'Reilly2021a, Reference Griffin, Gain, Saunders, Huang, Alard, Toledo and O'Reilly2022; Oliveira et al., Reference Oliveira, Griffin, Gain, Saunders, Shaw, Toledo, Afonso and O'Reilly2021). These spectacular structures are only one form of TiN in the Carmel sapphire; it also occurs in large inclusions coexisting with Fe–Ti silicides and TiB2, and as regular crystals that appear to have crystallised directly from Fe–Ti silicide melts (Griffin et al., Reference Griffin, Gain, Camara, Bindi, Shaw, Alard, Saunders, Huang, Toledo and O'Reilly2020a, Reference Griffin, Gain, Saunders, Bindi, Alard, Toledo and O'Reilly2021a, Reference Griffin, Gain, Saunders, Alard, Shaw, Toledo and O'Reilly2022).

4. “as a result of CH4+H2 fluid flowing through the magmatic melt”. This is not quite correct; we have proposed that such fluids interacted with melts, and may have flowed through melt-escape channels together with melts, to produce the skeletal crystals of the Carmel sapphire (Oliveira et al., Reference Oliveira, Griffin, Gain, Saunders, Shaw, Toledo, Afonso and O'Reilly2021).

5. “On only one occasion the amorphous carbon is recorded in the cement of the ‘white breccia’.” The authors confuse the white material that coats some grains with the explosion breccias illustrated by us (Xiong et al., Reference Xiong, Griffin, Huang, Gain, Toledo, Pearson and O'Reilly2017; Griffin et al., Reference Griffin, Huang, Thomassot, Gain, Toledo and O'Reilly2018b). The matrix of the explosion breccias, which may include the one large grain described by the authors, are dominated by amorphous carbon, as identified by petrographic, EBSD and TEM studies. We have noted micro-inclusions of corundum, but not bauxite, in the matrix of the explosion breccias. The authors provide no evidence that bauxite, or any other Al-hydroxide, is present in the matrices. The EDS spectra given for “böhmite-like material” are equally consistent with corundum. We suggest that the report of böhmite /bauxite represents analyses of spots consisting of amorphous carbon plus micro-inclusions of corundum; this would be consistent with the apparently higher C content of the EDS spectrum. If böhmite actually is present, it may equally reflect partial alteration of corundum fragments. Whether this fine-grained material could be considered as an ash component is a semantic question.

6. “Osbornite from Carmel sapphire grains…as a rule are confined to glass inclusions”. This is not correct. The osbornite ‘skeletal crystals’ typically extend well outside the melt pockets, and occur as isolated inclusions in the corundum (as seen in 3D-μCT as well as 2-D slices; Griffin et al., Reference Griffin, Gain, Saunders, Alard, Shaw, Toledo and O'Reilly2021a, Reference Griffin, Gain, Saunders, Huang, Alard, Toledo and O'Reilly2022). See also point (3) above.

7. “Griffin et al. (Reference Griffin, Gain, Saunders, Cámara, Bindi, Spartà, Toledo and O'Reilly2021b) underline the non-stable composition of osbornite”. This is simply not correct; we have done no such thing. The cited reference presents analytical data and shows that they are consistent with experimental studies on the Ti–O–N system. There is nothing “non-stable” there.

8. “Bigger corundum aggregates contain silica glass”; “usually squeezed out between corundum grains”. This is misleading; the glasses in the melt pockets are calcium–aluminium–silicate (CAS) glasses (typically with 40–45 wt.% SiO2) with moderate levels of Mg, Ti and S, as well as high levels of REE and Zr. In some parageneses with cumulate-like structures the melts are indeed concentrated along grain boundaries, whereas in the more skeletal corundum aggregates the melts occur both along grain boundaries and as isolated inclusions. 3μCT images (Griffin et al., Reference Griffin, Gain, Saunders, Alard, Shaw, Toledo and O'Reilly2021a) illustrate this very clearly.

9. “.. ‘white breccia’ … as a source of Carmel sapphire”. This is misleading; nearly all investigated grains of Carmel sapphire have no traces of the white coating, and there is no evidence that they have been brecciated.

10. Zr-bearing glass as debris from “special laboratory glassware”. As noted above, the internal melts in the Carmel sapphire are high in Zr and the Carmel sapphire contains many Zr-bearing phases. Some corundum-aggregate xenoliths have thick rims of a Ba-rich or K-rich glass full of tiny crystals of zircon or baddeleyite. The high Zr contents reflect the fact that most of the melts left in the corundum aggregates by the time of eruption were highly differentiated. The spectrum in fig. 7d in the author's manuscript is very similar to those of the glasses in melt pockets in one type of Carmel Sapphire. It is unfortunate that these spectra were not accompanied by quantitative chemical analyses, which would have aided comparison with published data.

11. “.. terrestrial examples [of krotite and grossite] are questionable and require verification.” The authors might read our papers (Griffin et al. Reference Griffin, Gain, Huang, Saunders, Shaw, Toledo and O'Reilly2019a, Reference Griffin, Gain, Saunders, Alard, Shaw, Toledo and O'Reilly2020a) on the coarse-grained xenoliths of hibonite+ grossite+V0, which require a very H2-rich atmosphere and show the crystallisation sequence:

corundum + Liq → (low-REE) hibonite → grossite + spinel ± krotite → Ca4Al6F2O12 + fluorite. The occurrence of grossite in meteorites cannot invalidate the existence of these samples; their disaggregation during eruption is responsible for inclusions of krotite, hibonite and grossite in the breccias. These clearly did not result from the hydration of hypothetical precursor minerals.

12. “Glass fragments with inclusions of mullite”. Mullite does appear in some melt inclusions in the corundum aggregates. This is expected because the compositions of some residual melts fall into the liquidus field of mullite in CAS space at low P, and the crystallisation of mullite might be expected to occur during eruption.

13. “There is no mechanism for the simultaneous removal of Fe and Si from natural melt systems”. This is not correct. Reduction of an FeO-bearing silicate melt to f O2 = IW-5 (as documented by the abundance of Ti3+-bearing minerals in Carmel sapphire) will lead to immiscibility of Fe–Ti–Si silicides and supersaturation in Al2O3, leading to corundum crystallisation. Comparison of the analysed silicide-melt compositions with experimental data shows that this occurred at normal magmatic temperatures (1200–1400°C; Weitzer et al., Reference Weitzer, Schuster, Naka, Stein and Palm2008; Griffin et al., Reference Griffin, Gain, Saunders, Huang, Alard, Toledo and O'Reilly2022). It is also worth noting that the presence of hydrogen can lower the melting points of metals and alloys by several hundred degrees (Fukai, Reference Fukai2005). Thus the 2000°C temperature of the industrial process is irrelevant to the natural case, although the observation that the silicide melts do sink to the bottom is a nice illustration of the process that we have proposed. We would appreciate a reference to the industrial process, which was not provided in the paper.

14. “formation from the melt requires extremely rapid quenching”. We agree; this is consistent with the very rapid eruption rate of the host basalts (pyroclastics) of the Carmel sapphire, which carry mantle-derived peridotite xenoliths (O'Reilly et al., Reference O'Reilly, Griffin, Dosetto, Turner and Van Orman2010)

15. “Therefore all new minerals [from] Carmel sapphire should be discredited by the IMA–CNMNC”. This is surely misguided (see below) and in any case is not appropriate to a journal article.

Finally, we must point out that a similarity between synthetic products (laboratory or industrial) and natural materials provides keys to the interpretation of natural processes (indeed, it is the raison d'etre of experimental petrology). However, such similarity cannot be taken as evidence for anthropogenic origin of the natural material. Duplication of mantle minerals in experiments does not imply that the minerals cannot exist in nature. This is the fundamental fallacy of the persistent criticisms by Litasov et al. (Reference Litasov, Kagi and Bekker2019a,Reference Litasov, Bekker and Kagib,Reference Litasov, Kagi, Voropaev, Hirata, Ohfuji, Ishibashi, Makino, Bekker, Sevastyanov, Afanasiev and Pokhilenkoc) and Ballhaus et al. (Reference Ballhaus, Wirth, Fonseca, Blanchard, Pröll, Bragagni, Nagel, Schreiber, Dittrich and Thome2017, Reference Ballhaus, Helmy, Fonseca, Wirth, Schreiber and Jöns2021) of the Mt Carmel work and many studies of similar mineral associations from numerous ophiolites by many researchers worldwide. Unfortunately, the experimental petrologists involved in this criticism have not followed scientific method; that would have included taking into account the overwhelming geological and geochemical evidence that makes an anthropogenic origin impossible, at least in the case of Mt Carmel (Griffin et al., Reference Griffin, Gain, Saunders, Cámara, Bindi, Spartà, Toledo and O'Reilly2021b).

This evidence includes:

The Mt Carmel mineral assemblages show significant differences to the synthetic materials produced and/or described by those arguing for a contamination origin (Litasov et al., Reference Litasov, Kagi and Bekker2019a,Reference Litasov, Bekker and Kagib,Reference Litasov, Kagi, Voropaev, Hirata, Ohfuji, Ishibashi, Makino, Bekker, Sevastyanov, Afanasiev and Pokhilenkoc).

This evidence indicates that there is no scientific basis for the authors’ conclusion that “the contamination of geological samples with anthropogenic material has led to popularisation of biased views”. The responsibility for “popularisation of biased views” must lie solely with those who refuse to consider straightforward geological and geochemical evidence for the natural origin of the Mt Carmel samples.

Acknowledgements

This is contribution 1762 from the ARC Centre of Excellence for Core to Crust Fluid Systems (http://www.ccfs.mq.edu.au) and 1531 in the GEMOC Key Centre (http://www.gemoc.mq.edu.au).

Competing interests declaration

None of the authors have competing interests regarding this publication, and all authors have contributed to the authorship.

Footnotes

Principal Editor: Roger Mitchell

References

Ballhaus, C., Helmy, H.M., Fonseca, R.O.C., Wirth, R., Schreiber, A. and Jöns, N. (2021) Ultra-reduced phases in ophiolites cannot come from the Earth's mantle. American Mineralogist, 106, 10531063.CrossRefGoogle Scholar
Ballhaus, C., Wirth, R., Fonseca, R.O.C., Blanchard, H., Pröll, W., Bragagni, A., Nagel, T, Schreiber, A., Dittrich, S., Thome, V. et al. (2017) Ultra-high pressure and ultra-reduced minerals in ophiolites may form by lightning strikes. Geochemical Perspectives Letters, 5, 4246.CrossRefGoogle Scholar
Fukai, Y. (2005) The Metal-Hydrogen system. Basic Bulk Properties. Springer-Verlag Berlin, 505 pp.CrossRefGoogle Scholar
Galuskin, E. and Galuskina, I. (2023) Evidence of the anthropogenic origin of the “Carmel sapphire” with enigmatic super-reduced minerals. Mineralogical Magazine, 87, https://doi.org/10.1180/mgm.2023.25Google Scholar
Griffin, W.L., Gain, S.E.M., Adams, D.T., Huang, J-X., Saunders, M., Toledo, V., Pearson, N.J. and O'Reilly, S.Y. (2016) First terrestrial occurrence of tistarite (Ti2O3): Ultra-low oxygen fugacity in the upper mantle beneath Mount Carmel, Israel. Geology, 44, 815818, https://doi.org/10.1130/G37910.1.CrossRefGoogle Scholar
Griffin, W.L., Gain, S.E.M., Bindi, L., Toledo, V., Camara, F., Saunders, M. and O'Reilly, S.Y. (2018a) Carmeltazite, ZrAl2Ti4O11, a new mineral trapped in corundum from volcanic rocks of Mt Carmel, northern Israel. Minerals, 8, 601612.CrossRefGoogle Scholar
Griffin, W.L., Huang, J-X., Thomassot, E., Gain, S.E.M., Toledo, V. and O'Reilly, S.Y. (2018b) Super-reducing conditions in ancient and modern volcanic systems: Sources and behaviour of carbon-rich fluids in the lithospheric mantle. Mineralogy and Petrology, 112, Supplement 1, 101114.CrossRefGoogle Scholar
Griffin, W.L., Gain, S.E.M., Huang, J-X., Saunders, M., Shaw, J., Toledo, V. and O'Reilly, S.Y. (2019a) A terrestrial magmatic hibonite-grossite-vanadium assemblage: desilication and extreme reduction in a volcanic plumbing system, Mt Carmel, Israel. American Mineralogist, 104, 207217.CrossRefGoogle Scholar
Griffin, W.L., Toledo, V. and O'Reilly, S.Y. (2019b) Discussion of “Enigmatic super-reduced phases in corundum from natural rocks: Possible contamination from artificial abrasive materials or metallurgical slags” by Litasov et al. Lithos, 348–349, 105122.Google Scholar
Griffin, W.L., Gain, S.E.M., Camara, F., Bindi, L., Shaw, J., Alard, O. Saunders, M., Huang, J-X., Toledo, V. and O'Reilly, S.Y. (2020a) Extreme reduction: mantle-derived oxide xenoliths from a hydrogen-rich environment. Lithos, 358–359, 105404.Google Scholar
Griffin, W.L., Gain, S.E.M., Saunders, M., Bindi, L., Alard, O., Toledo, V. and O'Reilly, S.Y. (2020b) Parageneses of TiB2 in corundum xenoliths from Mt Carmel, Israel: Siderophile behaviour of boron under reducing conditions. American Mineralogist, 105, 16091621.CrossRefGoogle Scholar
Griffin, W.L., Gain, S.E.M., Saunders, M., Alard, O., Shaw, J., Toledo, V. and O'Reilly, S.Y. (2021a) Nitrogen under super-reducing conditions: Ti oxynitride melts in xenolithic corundum aggregates from Mt Carmel (N. Israel). Minerals, 11, 780.Google Scholar
Griffin, W.L., Gain, S.E.M., Saunders, M., Cámara, F., Bindi, L., Spartà, D., Toledo, V. and O'Reilly, S.Y. (2021b) Cr2O3 in Corundum: ultra-high contents under reducing conditions. American Mineralogist, 106, 14201437.CrossRefGoogle Scholar
Griffin, W.L., Gain, S.E.M., Saunders, M., Huang, J-X., Alard, O., Toledo, V. and O'Reilly, S.Y. (2022) Immiscible metallic melts in the upper mantle beneath Mount Carmel, Israel: Silicides, phosphides and carbides. American Mineralogist, 107, 532549.CrossRefGoogle Scholar
Huang, J-X., Xiong, Q., Gain, S.E.M., Griffin, W.L., Murphy, T.D., Siryaev, A.A., Li, L., Toledo, V., Tomshin, M.D. and O'Reilly, S.Y. (2020) Immiscible metallic melts in the deep Earth: Clues from moissanite (SiC) in volcanic rocks. Science Bulletin, 65, 14791488.CrossRefGoogle ScholarPubMed
Litasov, K.D., Kagi, H. and Bekker, T.B. (2019a) Enigmatic super-reduced phases in corundum from natural rocks: Possible contamination from artificial abrasive materials or metallurgical slags. Lithos, 340–341, 181190.CrossRefGoogle Scholar
Litasov, K.D., Bekker, T.B. and Kagi, H. (2019b) Reply to the discussion of “Enigmatic super-reduced phases in corundum from natural rocks: Possible contamination from artificial abrasive materials or metallurgical slags” by Litasov et al. (Lithos, 340–341, p.181–190) by W.L. Griffin, V. Toledo and S.Y. O'Reilly. Lithos, 348–349, 105170.Google Scholar
Litasov, K.D., Kagi, H., Voropaev, S.A., Hirata, T., Ohfuji, H., Ishibashi, H., Makino, Y., Bekker, T.B., Sevastyanov, V.S., Afanasiev, V.P. and Pokhilenko, N.P. (2019c) Comparison of enigmatic diamonds from the Tolbachik arc volcano (Kamchatka) and Tibetan ophiolites: Assessing the role of contamination by synthetic materials. Gondwana Research, 75, 1627.CrossRefGoogle Scholar
Oliveira, B.B., Griffin, W.L., Gain, S.E.M., Saunders, M., Shaw, J., Toledo, V. Afonso, J.C. and O'Reilly, S.Y. (2021) Ti3+ in corundum: tracing crystal growth in a highly reduced magma. Scientific Reports, 11, 2439.CrossRefGoogle Scholar
O'Reilly, S.Y. and Griffin, W.L. (2010) Rates of magma ascent: Constraints from mantle-derived xenoliths. Pp. 116124 in: Timescales of Magmatic Processes: From Core to Atmosphere (Dosetto, A., Turner, S. and Van Orman, J.A., editors). Blackwell Publishing Ltd., Hoboken, New Jersey, USA.CrossRefGoogle Scholar
Pack, A. (2021) Isotopic traces of atmospheric O2 in rocks, minerals and melts. Pp. 217240 in: Triple Oxygen Isotope Geochemistry (Bindeman, I.N. and Pack, A., editors). Reviews in Mineralogy and Geochemistry, 86. Mineralogical Society of America and the Geochemical Society, Chantilly, Virginia, USA.Google Scholar
Roup, A., Kamanovitch, E., Baykov, Y and Toledo, V. (2009) Moissanite discovery by Shefa Yamin. Geological Society of Israel Annual Meeting, Abstract, p. 111.Google Scholar
Weitzer, F., Schuster, J., Naka, M., Stein, F. and Palm, M. (2008) On the reaction scheme and liquidus surface in the ternary system Fe-Si-Ti. Intermetallics, 16, 273282.CrossRefGoogle Scholar
Xiong, Q., Griffin, W.L., Huang, J-X., Gain, S.E.M., Toledo, V., Pearson, N.J. and O'Reilly, S.Y. (2017) Super-reduced mineral assemblages in “ophiolitic” chromitites and peridotites: The view from Mt Carmel. European Journal of Mineralogy, 29, 557570.CrossRefGoogle Scholar