Isaac Scientific Publishing

Geosciences Research

GR > Volume 3, Issue 4, November 2018

A Note on the Chemical Composition and Origin of Peridot from the Harrat Kishb, Saudi Arabia

Download PDF (794.7 KB) PP. 65 - 73 Pub. Date: November 1, 2018

DOI: 10.22606/gr.2018.34003

Author(s)

  • Adel A. Surour*
    Geology Department, Faculty of Science, Cairo University, 12613 Giza, Egypt

Abstract

Zabarjad (peridot in Arabic) is a common gemstone of valuable importance used in jewelry. It is the mineral olivine that has some gemological characters that classify it as peridot or gem olivine. Although it is not found in huge quantities in Saudi Arabia, there are some mining activities to extract peridot from the Harrat Kishb where the mineral is found scattered in alkali basalt or in the scree and wadi deposits. The basaltic flows at the Harrat Kishb include this gem olivine in the form of mantle xenoliths that comprise both dunite and peridotite. The size of collected peridot lies in the range of 0.4-0.8 cm and it occurs either as free olivine or in the form of cluster with components of host basalt. The collected crystals are transparent olive-green after washing and screening. Using the modern technique of analysis by the electron microprobe, the accurate chemical composition of peridot crystals was obtained. The studied peridot is a Mg-rich end-member of the foresterite (Mg) and fayalite (Fe) solid solution series where the forsterite content is Fo90.35-92.31. Such composition of olivine is similar to majority of olivine in the ultramafic mantle beneath the western Arabian Peninsula. The present work uses the concentrations of some elements such as Mn, Ni and Ca in addition to the forsterite content to characterize the Saudi peridot. It is typically terrsterial when compared to extraterrestrial (pallastic) olivine, and mostly xenocrystic and rarely magmatic. The forsterite content (Fo>90) suggests transition from a residual to cumulate origin.

Keywords

Peridot; Harrat Kishb; xenocryst; peridotite nodules; residual melt

References

[1] T. F. Smith and M. S. Waterman, “Identification of common molecular subsequences,” Journal of molecular biology, vol. 147, no. 1, pp. 195–197, 1981.

[2] P. May, H.-C. Ehrlich, and T. Steinke, “Zib structure prediction pipeline: composing a complex biological workflow through web services,” in Euro-Par 2006 Parallel Processing. Springer, 2006, pp. 1148–1158.

[3] Foster and C. Kesselman, The Grid 2: Blueprint for a new computing infrastructure. Elsevier, 2003.

[4] K. Czajkowski, S. Fitzgerald, I. Foster, and C. Kesselman, “Grid information services for distributed resource sharing,” in High Performance Distributed Computing, 2001. Proceedings. 10th IEEE International Symposium on. IEEE, 2001, pp. 181–194.

[5] Foster, C. Kesselman, J. Nick, and S. Tuecke, “The physiology of the grid: An open grid services architecture for distributed systems integration. 2002,” Globus Project, 2004.

[6] National Center for Biotechnology Information, Available: http://www.ncbi.nlm.nih.gov

[7] Abdel Wahab, M. A. Abul Maaty, F. M. Stuart, H. Awad, and A. Kafafy, “The geology and geochronology of Al Wahbah maar crater, Harrat Kishb, Saudi Arabia,” Quaternary Geochronology, vol. 21, pp. 70–76, 2014.

[8] H. Ahmed, A. M. Moghazi, M. R. Moufti, Y. H. Dawood, and K. A. Ali, “Nature of the lithospheric mantle beneath the Arabian Shield and genesis of Al spinel micropods: evidence from the mantle xenoliths of Harrat Kishb, Western Saudi Arabia,”. Lithos, vol. 240-243, pp. 119–139, 2016.

[9] G. F. Brown, R. O. Jackson, R. G. Bogue, and E. L., Jr. Elberg, “Geologic map of the northwestern Hijaz quadrangle, Kingdom of Saudi Arabia,” U.S. Geological Survey Miscellaneous Geologic Investigations Map I-204A, scale 1:500,000, 1963.

[10] V. E. Camp, and M. J. Roobol, “Upwelling asthenosphere beneath western Arabia and its regional implications,” Journal of Geophysical Research, vol. 97, pp. 15255–15271, 1992.

[11] V. E. Camp, M. J. Roobol, and P. R. Hooper, “The Arabian continental alkali basalt province: Part III. Evolution of Harrat Kishb, Kingdom of Saudi Arabia,” Geological Society of America Bulletin, vol. 104, pp. 379–396, 1992.

[12] R. G. Coleman, R. T. Gregory, and G. F. Brown, “Cenozoic volcanic rocks of Saudi Arabia,” Ministry of Petroleum and Mineral Resources, Deputy Ministry for Mineral Resources, Jeddah, Kingdom of Saudi Arabia, 82 p., 1983.

[13] P. Collenette, and D. J. and Grainger, “Mineral Resources of Saudi Arabia,” Ministry of Petroleum and Mineral Resources Directorate General of Mineral Resources Jeddah, Kingdom of Saudi Arabia, 322 p., 1994.

[14] Sh. Gao, R. L. Rudnick, W. –L. Xu, H. L. Yuan, Y. –S. Liu, R. J. Walker, I. S. Puchtel, X. Liu,, H. Huang, X. –R., Wang, and J. Yang, “Recycling deep cratonic lithosphere and generation of intraplate magmatism in the North China Craton,” 9 p., 2008. Accessed in 11 May 2018 at: http://www.mantleplumes.org/ RecycledLithosphere.html

[15] Hadnott, B. L. Ehlmann, and B. L. Jolliff, “Mineralogy and chemistry of San Carlos high-alkali basalts: Analyses of alteration with application for Mars exploration,” American Mineralogist, Vol. 102, pp. 284–301, 2017.

[16] J. Hopp, M. Trieloff, and R. Altherr, “Neon isotopes in mantle rocks from the Red Sea region reveal large-scale plume–lithosphere interaction,” Earth and Planetary Science Letters, vol. 219, pp. 61–76, 2004.

[17] K. Konrad, D. W. Graham, C. R. Thornber, R. A. Duncan, A. J. R. Kent, and A. M. Al-Amri, “Asthenosphere-lithosphere interactions in Western Saudi Arabia: Inferences from 3He/4He in xenoliths and lava flows from Harrat Hutaymah,” Lithos, vol. 248-251, pp. 339–352, 2016.

[18] L. –C. Kuo, E. J. and Essene, “Petrology of spinel harzburgite xenoliths from the Kishb Plateau, Saudi Arabia,” Contributions to Mineralogy and Petrology, vol. 93, pp. 335–346, 1986.

[19] S. Lauretta, D. H. Hill, D. N. Della-Giustina, and M. Killgore, “The Fukang pallasite: evidence for non-equilibrium shock processing," The 37th Annual Lunar and Planetary Science Conference (Extended Abstract), League City, March 13-17, No. 2250, 2006.

[20] M. R. Moufti, A. M. Moghazi, and K. A. Ali, “Geochemistry and Sr-Nd-Pb isotopic composition of the Harrat Al-Madinah Volcanic Field, Saudi Arabia,” Gondwana Research, vol. 21, pp. 670–689, 2012.

[21] M. R. Moufti, K. Nemeth, N. El-Masry, and A. Qaddah, “Geoheritage values of one of the largest maar craters in the Arabian Peninsula: the Al Wahbah Crater and other volcanoes (Harrat Kishb, Saudi Arabia),” Central European Journal of Geosciences, vol. 5, pp. 254–271, 2013.

[22] H. Murcia, J. M. Lindsay, S. Niedermann, S. J. Cronin, I. E. Smith, N. N. El-Masry, M. R. H. Moufti, K. Németh, “The potential use of cosmogenic nuclides for dating in Harrat Rahat,” VORISA Scientific Meeting (Extended Abstract), Jeddah, Nov. 17–18, pp. 24–28, 2013.

[23] J. H. Natland, “Why olivine control arguments cannot be used to infer high temperature at Samoa,” http://www.mantleplumes.org/CoolSamoa.html

[24] M. J. Roobol, and V. E. Camp, “Geological Map of the Cenozoic Lava Fields of Harrat Khaybar, Ithnayen and Kurs,” Saudi Arabian Directorate General of Mineral Resources, Kingdom of Saudi Arabia, Geoscience Map (with text) GM-131, scale 1:250,000, 88 p.

[25] E. Rubin, and C. Ma, “Meteoritic minerals and their origin,” Chemie der Erde, vol. 77, pp. 325–385, 2017.

[26] M. Sahl, and J. W. Smith, “Geology of the Al Muwayh Quadrangle Sheet 22E,” Saudi Arabian Deputy Ministry for Mineral Resources, Kingdom of Saudi Arabia, Geoscience Map (with text) GM-88, 1:250,000 scale, 29 p., 1986.

[27] S. I. Salf, and S. M. A. Shah, “Field and petrographic characteristics of Cenozoic basaltic rocks, Northwestern Saudi Arabia,” Journal of African Earth Sciences, vol. 7, pp. 805–809, 1988.

[28] H. Shen, J. I. Koivula, and J. E. Shigley, “Identification of extraterrestrial peridot by trace elements,” Gems and Gemology, Notes and New Techniques, Fall 2011, pp. 208–213, 2001.

[29] J. E. Shigley, D. M. Dirlam, B. M. Laurs, E. W. Boehm, G. Bosshart, and W. F. Larson, “Gem localities of the 1990's,” Gems and Gemology, vol. 36, pp. 292–335, 2000.

[30] R. Thornber, “The petrology, geochemistry and origin of ultramafic inclusions and mafic alkaline magmas from Harrat Hutaymah, Saudi Arabia,” Open-File Report USGS-OF-92-6, Saudi Arabian Ministry of Petroleum and Mineral resources, Deputy Ministry of Mineral Resources, Jeddah, Kingdom of Saudi Arabia, 244 p., 1992.

[31] USGS, “An Overview of production of specific U.S. gemstones,” U.S. Bureau of Mines Special Publication, 2016.

[32] R. W. Wise, “Secrets of the gem trade, the connoisseur's guide to precious gemstones,” Brunswick House Press, Massachusetts, 220 p., 2016.