ІНТРУЗИВНО-МАГМАТИЧНІ УТВОРЕННЯ АРХІПЕЛАГУ ВІЛЬГЕЛЬМА ЗАХІДНОЇ АНТАРКТИКИ (ЧАСТИНА 1 – ІНТРУЗИВИ ГАБРОЇДІВ, ДІОРИТІВ ТА ГРАНІТОЇДІВ)

О. Митрохин; В. Бахмутов; А. Алексєєнко; Т. Митрохина; О. Марущенко

doi:10.17721/1728-2713.95.01

Authors

O. Mytrokhyn Taras Schevchenko National University of Kyiv, Institute of Geology, 90 Vasylkivska Str., Kyiv, 03022 Ukraine
V. Bakhmutov Institute of Geophysics, National Academy of Sciences of the Ukraine 32 Palladin Avе., 03680, Kyiv, Ukraine; National Antarctic Scientific Center
А. Аleksieienko Taras Schevchenko National University of Kyiv, Institute of Geology, 90 Vasylkivska Str., Kyiv, 03022 Ukraine
T. Mytrokhina Taras Schevchenko National University of Kyiv, Institute of Geology, 90 Vasylkivska Str., Kyiv, 03022 Ukraine
О. Marushchenko Taras Schevchenko National University of Kyiv, Institute of Geology, 90 Vasylkivska Str., Kyiv, 03022 Ukraine

DOI:

https://doi.org/10.17721/1728-2713.95.01

Keywords:

geology, calc-alkaline magmatism, Antarctic Peninsula

Abstract

The Wilhelm Archipelago and the adjacent coast of Graham Land are typical areas of calc-alkaline magmatism associated with the protracted evolution of the Antarctic Peninsula igneous belt. The authors studied intrusive complexes of the Wilhelm Archipelago (WA) in order to characterize their geographical distribution, geological occurrence and age, mineralogical and petrographical features. Geological surveys revealed that gabbro, diorite, and granitoid intrusions are widespread on the WA. Due to the processes of tectonic uplift and exhumation, both apical and bottom parts of individual intrusive bodies can be exposed on the modern erosion level. Recent geological observations have shown that plutons of different ages intersect each other in a complex sequence. This made it possible to determine their relative geological age and reconstruct the general direction of the deep magmatic development from the Early Cretaceous to the Early Paleogene, inclusive. It has been proved that the oldest massifs of gabbroids are parts of much larger intrusive bodies. They were formed in the period between the Jurassic and the Early Cretaceous periods. Crystallization differentiation of basaltic magmas gave them various scale layering. In the bottom parts of gabroid intrusions there were conditions for the formation of Fe-Ti-V and Cu-Ni-EPG mineralization. Diorite and granitoid intrusions occupy much larger areas compared to gabbroids. The formation of diorite intrusions took place in the period between the Early Cretaceous and the Paleocene. Although the oldest gabbroids were formed much earlier than diorites, the phenomena of magmatic mingling in the latter indicate that magmas of basic and intermediate composition could also synchronously intrude in common magmatic chambers. Granitoid magmatism on the WA covers the Late Cretaceous and the Paleogene periods. Most granitoid intrusions formed in the Paleocene after the main phase of tectonic deformations. Cu-Mo mineralization may be associated with these intrusions.

References

Bakhmutov, V.G., Gladkochub, D.P., Shpira, V.V. (2013). Age position, geodynemic specifics and paleomagnetism of intrusive complexes of the western coast of the Antarctic Peninsula. Geophysical Journal, 35, 3, 3-30. doi.org/10.24028/gzh.0203-3100.v35i3.2013.116387

Burton-Johnson, A., Riley, T.R. (2015). Autochthonous v. accreted terrane development of continental margins: a revised in situ tectonic history of the Antarctic Peninsula. Journal of the Geological Society, 172, 822-835. doi.org/10.1144/jgs2014-110

Curtis, R. (1966). The petrology of the Graham Coast, Graham Land. British Antarctic Survey Scientifif Reports, 50, 51.

Elliot, D.H. (1964). The petrology of the Argentine Islands. British Antarctic Survey Scientific Reports, 41, 31.

Jordan, T.A., Riley, T.R., Siddoway, C.S. (2020). The geological history and evolution of West Antarctica. Nature Reviews Earth & Environment, 1, 117–133. doi.org/10.1038/s43017-019-0013-6

Leat, P.T., Scarrow, J.H., Millar, I.L. (1995). On the Antarctic Peninsula Batholith. Geological Magazine, 132, 4, 399-412. doi.org/10.1017/S0016756800021464

Mytrokhyn, O.V., Bakhmutov, V.G. (2019). Stratigraphy of the district of the Ukrainian Antarctic Station "Academician Vernadsky". Ukrainian Antarctic Journal, 1, 18, 45-61. doi.org/10.33275/1727-7485.1(18).2019.129 [in Ukrainian]

Pankhurst, R.J. (1982). Rb-Sr geochronology of Graham Land, Antarctica. Journal of the Geological Society, 139, 6, 701–711. doi.org/10.1144/gsjgs.139.6.0701

Rex, D.C. (1976). Geochronology in relation to the stratigraphy of the Antarctic Peninsular. British Antarctic Survey Bulletin, 43, 49–58.

Riley, T.R., Flowerdew, M.J., Haselwimmer, C.C. (2011). Geological map of Eastern Graham Land, Antarctic Peninsula (1:625000 scale). BAS GEOMAPS 2 Series, sheet 1, British Antarctic Survey, Cambridge, UK.

Ryan, C.J. (2007). Mesozoic to Cenozoic igneous rocks from Northwestern Graham Land: constraints on the tectono-magmatic evolution of the Antarctic Peninsula. University of Brighton, 495.

Tangeman, J.A., Mukasa, S.B., Grunov, A.M. (1996). Zircon U-Pb geochronology of plutonic rocks from the Antarctic Peninsular: Confirmation on presence of unexposed Paleozoic crust. Tectonics, 15, 6, 1309-1324. https://doi.org/10.1029/96TC00840

Zheng, G.G., Liu, X., Liu, S., Zhang, S.H., Zhao, Y. (2018). Late Mesozoic–early Cenozoic intermediate–acid intrusive rocks from the Gerlache Strait area, Antarctic Peninsula: Zircon U–Pb geochronology, petrogenesis and tectonic implications. Lithos, 312-313, 204-222. doi:10.1016/j.lithos.2018.05.008