Инд. авторы: Likhanov I.I., Zinoviev S.V.
Заглавие: Early Stage in the Evolution of the Paleoasian Ccean at the Western Margin of the Siberian Craton: Geochemical and Geochronological Evidence
Библ. ссылка: Likhanov I.I., Zinoviev S.V. Early Stage in the Evolution of the Paleoasian Ccean at the Western Margin of the Siberian Craton: Geochemical and Geochronological Evidence // Geochemistry International. - 2018. - Vol.56. - Iss. 2. - P.111-124. - ISSN 0016-7029. - EISSN 1531-8397.
Идентиф-ры: DOI: 10.1134/S0016702918020040; РИНЦ: 35531616; SCOPUS: 2-s2.0-85042290524; WoS: 000424015600002;
Реферат: eng: The discovery of glaucophane relicts in the high-pressure tectonites of the Yenisei suture zone of the Yenisei Ridge suggests the manifestation of the "Chilean-type" convergent margin on the western Siberian Craton, which was controlled by subduction of oceanic crust beneath the continental margin. These rocks are restricted to the tectonic suture between the craton and the Isakovka ocean-island terrane and experienced two metamorphic stages. Petrogeochemical characteristics of the mafic tectonites indicate that their protoliths are N-MORB and E-MORB basalts. More primitive N-MORB basalts were formed at the initial spreading stages through melting of the upper depleted mantle. Higher Ti basalts were formed by melting of enriched mantle protolith at the later spreading stages. U-Pb zircon age of 701.6 +/- 8.4 Ma of the metamorphosed analogues of normal basalts marks the initiation of oceanic crust in the region. Revealed sequence of spreading, subduction (640-620 Ma), and shear deformations (similar to 600 Ma) records the early stages in the evolution of the Paleoasian ocean in its junction zone with the western margin of the Siberian craton: from formation of fragments of oceanic crust to the completion of accretionary-subduction events.
Ключевые слова: BASALTS; RANGE; MAGMATISM; AGE; TRANSANGARA REGION; FE-RICH; COLLISIONAL METAMORPHISM; AL-RICH METAPELITES; Paleoasian ocean; Yenisei Ridge; U-Pb and Ar-Ar dating; protolith; geochemistry; high-pressure tectonites; YENISEI-RIDGE; COMPLEX;
Издано: 2018
Физ. хар-ка: с.111-124
Цитирование: 1. G. E. Bebout, J. G. Ryan, W. P. Leeman, and A. E. Bebout, “Fractionation of trace elements by subduction-zone metamorphism–effect of convergent-margin thermal evolution,” Earth Planet. Sci. Lett. 171, 63–81 (1999).
2. W. V. Boynton, “Cosmochemistry of the rare earth elements: meteorite studies,” in Rare Earth Element Geochemistry, Ed. by P. Henderson (Elsevier, Amsterdam, 1984), pp. 63–114.
3. J.-P. Burg and T. V. Gerya, “The role of viscous heating in Barrovian metamorphism: thermomechanical models and application to the Lepontine Dome in the Central Alps,” J. Metamorph. Geol. 23, 75–95 (2005).
4. K. Condie, “High field strength element ratios in Archean basalts: a window to evolving sources of mantle plumes?” Lithos 79, 491–504 (2005).
5. M. Corsini, V. Bosse, G. Feraud, F. Demoux, and G. Crevola, “Exhumation processes during post-collisional stage in the Variscan belt revealed by detailed 40Ar/39Ar study (Tanneron Massif, SE France),” Int. J. Earth Sci. 99, 327–341 (2010).
6. N. L. Dobretsov, “Evolution of structures of the Urals, Kazakhstan, Tien Shan, and Altai-Sayan region within the Ural-Nongolian fold belt (Paleoasian ocean),” Russ. Geol. Geophys. 44 (1–2), 3–26 (2003).
7. A. S. Egorov, Deep Structure and Geodynamics of the Lithosphere of Northern Eurasia: Data from Geological–Geophysical Modeling along Russian Geotraverses, (VSEGEI, St.-Petersburg, 2004) [in Russian].
8. W. G. Ernst, “Petrogenesis of glaucophane schists,” J.Petrol. 4, 1–30 (1963).
9. J. G. Fitton, A. D. Saunders, M. J. Norry, B. S. Hardarson, and R. N. Taylor, “Thermal and chemical structure of the Iceland plume,” Earth Planet. Sci. Lett. 153, 197–208 (1997).
10. K. F. Fornash, M. A. Cosca, and D. L. Whitney “Tracking the timing of subduction and exhumation using 40Ar/39Ar phengite ages in blueschist-and eclogite facies rocks (Sivrihisar, Turkey),” Contrib. Mineral. Petrol. 171, 67 (2016). doi 10.1007/s00410-016-1268-2
11. T. V. Gerya, B. Stockhert, and A. L. Perchuk, “Exhumation of high-pressure metamorphic rocks in subduction channel: a numerical simulation,” Tectonics 21, 6-1-6-19 (2002).
12. D. P. Gladkochub, S. A. Pisarevsky, A. M. Stanevich, T. V. Donskaya, and A. M. Mazukabzov, “When Siberia broke up from Rodinia? Evidence from detrital zircon geochronology,” Rodinia 2013: Supercontinental Cycles and Geodynamics Symposium 2013, Ed. by R. Veselovskiy and N. Lubnina, (PERO Press, Moscow, 2013), p. 31.
13. P. R. Hooper, “The Columbia river basalts,” Science 215, 1463–1468 (1982).
14. Igneous Rocks. Acid and Intermediate Rocks, Ed. by V. V. Yarmolyuk and V. I. Kovalenko (Nauka, Moscow, 1987).
15. T. N. Kheraskova, S. A. Kaplan, and V. I. Galuev, Structure of the Siberian Platform and Its Western Margin in the Riphean–Early Paleozoic,” Geotectonics 43 (2), 115–132 (2009).
16. T. N. Kheraskova, S. A. Kaplan, V. P. Bubnov, and V. I. Galuev, “New data on the structure of the Kan Block in the basement of the West Siberian Plate,” Geotectonics 47 (2), 101–114 (2013).
17. P. S. Kozlov, I. I. Likhanov, V. V. Reverdatto, and S. V. Zinoviev, “Tectonometamorphic evolution of the Garevka polymetamorphic complex (Yenisei Ridge),” Russ. Geol. Geophys. 53 (11), 1133–1149 (2012).
18. A. B. Kuzmichev and E. V. Sklyarov, “The Precambrian of Transangaria, Yenisei Ridge (Siberia): Neoproterozoic microcontinent, Grenville-age orogeny, or reworked margin of the Siberian craton,” J. Asian Earth Sci. 115, 419–441 (2016).
19. A. B. Kuzmichev, I. P. Paderin, and A.V. Antonov, “Late Riphean Borisikha ophiolite (Yenisei Ridge): U-Pb zircon age and tectonic setting,” Russ. Geol. Geophys. 49 (12), 883–893 (2008).
20. M. L. Leech and D. F. Stockli, “The late exhumation history of the ultrahigh-pressure Maksyutov Complex, south Ural Mountains, from new apatite fission track data,” Tectonics 19(1), 153–167 (2000).
21. Legend of the Yenisei Series of the State Geologucal Map of the Russian Federation on a Scale 1: 200 000 (2nd Edition), Ed. by L. K. Kachevskii (PGO Krasnoyarskgeologiya, Krasnoyarsk, 2002) [in Russian].
22. I. I. Likhanov, “Mineral reactions in high-alumina ferriferous metapelitic hornfelses: the problem of stability of rare parageneses of contact metamorphism,” Russ. Geol. Geophys. 44 (4), 305–316 (2003).
23. I. I. Likhanov and V. V. Reverdatto, “Lower Proterozoic metapelites in the northern Yenisei Range: nature and age of the protolith and the behavior of material during collisional metamorphism,” Geochem. Int. 49 (3), 224–252 (2011).
24. I. I. Likhanov and V. V. Reverdatto, “Geochemistry, age, and petrogenesis of rocks from the Garevka metamorphic complex, Yenisey Ridge,” Geochem. Int. 52 (1), 1–22 (2014a).
25. I. I. Likhanov and V. V. Reverdatto, P-t-t constraints on the metamorphic evolution of the Transangarian Yenisei Ridge: geodynamic and petrological implications,” Russ. Geol. Geophys. 55 (3), 299–322 (2014b).
26. I. I. Likhanov and V. V. Reverdatto, “Evidence of Middle Neoproterozoic extensional tectonic settings along the western margin of the Siberian Craton: implications for the breakup of Rodinia,” Geochem. Int. 53 (8), 671–689 (2015).
27. I. I. Likhanov and V. V. Reverdatto, “Geochemistry, petrogenesis and age of metamorphic rocks of the Angara Complex at the junction of south and north Yenisei Ridge,” Geochem. Int. 54 (2), 127–148 (2016).
28. I. I. Likhanov, O. P. Polyansky, V. V. Reverdatto, P. S. Kozlov, A. E. Vershinin, M. Krebs, and I. Memmi, “Metamorphic evolution of high-alumina metapelites near the Panimba overthrust (Yenisei Range): mineral associations, PT-conditions, and tectonic model,” Russ. Geol. Geophys. 42 (8), 1205–1220 (2001).
29. I. I. Likhanov, O. P. Polyansky, V. V. Reverdatto, and I. Memmi, “Evidence from Fe-and Al-rich metapelites for thrust loading in the Transangarian Region of the Yenisey Ridge, eastern Siberia,” J. Metamorph. Geol. 22, 743–762 (2004).
30. I. I. Likhanov, P. S. Kozlov, N. V. Popov, V. V. Reverdatto, and A. E. Vershinin, “Collisional metamorphism as a result of thrusting in the Transangara region of the Yenisei Ridge,” Dokl. Earth Sci. 411, 1313–1317 (2006a).
31. I. I. Likhanov, V. V. Reverdatto, and A. E. Vershinin, “Geochemical evidence for protolith origin of Fe-and Alrich metapelites from the Kuznetsk Alatau and Yenisei Ridge,” Russ. Geol. Geophys. 47 (1), 120–133 (2006b).
32. I. I. Likhanov, P. S. Kozlov, O. P. Polyansky, N. V. Popov, V. V. Reverdatto, A. V. Travin, and A. E. Vershinin, “Neoproterozoic age of collisional metamorphism in the Transangara region of the Yenisei Ridge (based on 40Ar/39Ar data),” Dokl. Earth Sci. 412, 234–237 (2007).
33. I. I. Likhanov, V. V. Reverdatto, and A. E. Vershinin, “Feand Al-rich metapelites of the Teiskaya Group, Yenisei Range: geochemistry, protoliths, and the behavior of their material during metamorphism,” Geochem. Int. 46 (1), 17–36 (2008a).
34. I. I. Likhanov, V. V. Reverdatto, P. S. Kozlov, and N. V. Popov, “Collision metamorphism of Precambrian complexes in the Transangarian Yenisei Range,” Petrology 16 (2), 136–160 (2008b).
35. I. I. Likhanov, V. V. Reverdatto, P. S. Kozlov, V. V. Khiller, and V. P. Sukhorukov, “Three metamorphic events in the Precambrian P-T-t history of the Transangarian Yenisey Ridge recorded in garnet grains in metapelites,” Petrology 21 (6), 561–578 (2013a).
36. I. I. Likhanov, V. V. Reverdatto, P. S. Kozlov, and S. V. Zinoviev, “The Neoproterozoic Trans-Angara Dike Belt, Yenisei Range, as an Indicator of Extension and Breakup of Rodinia,” Dokl. Earth Sci. 450, 613–617 (2013b).
37. I. I. Likhanov, A. D. Nozhkin, V. V. Reverdatto, and P. S. Kozlov, “Grenville tectonic events and evolution of the Yenisei Ridge at the western margin of the Siberian Craton,” Geotectonics 48 (5), 371–389 (2014).
38. I. I. Likhanov, V. V. Reverdatto, P. S. Kozlov, S. V. Zinoviev, and V. V. Khiller, “P-T-t reconstructions of south Yenisei Ridge metamorphic history (Siberian Craton): petrological consequences and application to the supercontinental cycles,” Russ. Geol. Geophys. 56 (6), 805–824 (2015).
39. I. I. Likhanov, V. V. Reverdatto, P. S. Kozlov, V. V. Hiller, and V. P. Sukhorukov, “P-T-t constraints on polymetamorphic complexes of the Yenisey Ridge, East Siberia: implications for Neoproterozoic paleocontinental reconstructions,” J. Asian Earth Sci. 113, 391–410 (2015).
40. I. I. Likhanov, S. V. Zinoviev, P. S. Kozlov, and A. A. Krylov, “Evidence for tectonic stress in the pre-Yenisei suture zone, Yenisei Ridge,” Tectonics and Actual Questions of Earth’s Sciences (IFZ, Moscow, 2016), pp. 139–146 [in Russian].
41. M. T. McCulloch and J. A. Gamble, “Geochemical and geodynamic constraints on subduction zone magmatism,” Earth Planet. Sci. Lett. 102, 358–374 (1991).
42. M. A. Meschide, “A method of discriminating between different types of mid ocean rigde basalts and continental tholeites with Nb–Zr–Y diagram,” Chem. Geol. 56, 207–218 (1986).
43. G. L. Mitrofanov, T. V. Mordovskaya, and F. V. Nikol’skii, “Piling structures of some marginal parts of the Siberian Craton,” Tectonics of Platform Areas, (Nauka, Novosibirsk, 1988), pp. 169–173 [in Russian].
44. A. D. Nozhkin, O. M. Turkina, Yu. K. Sovetov, and A. V. Travin, “The Vendian accretionary event in the southwestern margin of the Siberian Craton,” Dokl. Earth Sci. 415 (6), 782–787 (2007).
45. A. D. Nozhkin, A. S. Borisenko, and P. A. Nevol’ko, “Stages of Late Proterozoic magmatism and periods of Au mineralization in the Yenisei Ridge,” Russ. Geol. Geophys. 52 (1), 124–143 (2011).
46. A. D. Nozhkin, O. M. Turkina, N. V. Dmitrieva, and I. I. Likhanov, “Age and P-T parameters of metamorphism of metaterrigenous–carbonate deposits of the Derba Block (East Sayan),” Dokl. Earth Sci. 461 (5), 390–393 (2015).
47. A. D. Nozhkin, N. V. Dmitrieva, I. I. Likhanov, P. A. Serov, and P. S. Kozlov, “Geochemical, isotopic, and geochronological evidence for subsynchronous island-arc magmatism and terrigenous sedimentation (Predivinsk terrane of the Yenisei Ridge),” Russ. Geol. Geophys. 57 (11), 1570–1590 (2016a).
48. A. D. Nozhkin, O. M. Turkina, I. I. Likhanov, and N. V. Dmitrieva, “Late Paleoproterozoic volcanic associations in the southwestern Siberian Craton (Angara-Kan block),” Russ. Geol. Geophys. 57 (2), 247–264 (2016b).
49. V. V. Reverdatto, I. I. Likhanov, O. P. Polyansky, V. S. Sheplev, and V. Yu. Kolobov, Nature and Model of Metamorphism (SO RAN, Novosibirsk, 2017) [in Russian].
50. A. S. Salnikov, Seismologilca Structure of the Earth’s Crust of Platform and Folds Areas of Siberia based on the Regional Refracted Wave Seismic Studies (SNIIGGiMS, Novosibirsk, 2009) [in Russian].
51. S. M. Schmalholz and Y. Y. Podladchikov, “Tectonic overpressure in weak crustal-scale shear zones and implications for exhumation of high-pressure rocks,” Geophys. Res. Lett. 40, 1984–1988 (2013).
52. S. S. Sun and W. F. McDonough, “Chemical and isotopic systematics of oceanic basalts: implications for mantle composition and processes,” Geol. Soc. Spec. Publ. 42, 313–345 (1989).
53. V. A. Vernikovsky and A. E. Vernikovskaya, “Tectonics and evolution of granitoid magmatism in the Yenisei Ridge,” Russ. Geol. Geophys. 47, 32–50 (2006).
54. V. A. Vernikovsky, A. V. Vernikovskaya, A. D. Nozhkin, and V. A. Ponomarchuk, Riphean ophiolites of the Isakovka belt, Yenisei Range,” Geol. Geofiz., 35 (7–8), 169–181 (1994).
55. V. A. Vernikovsky, A. E. Vernikovskaya, A. I. Chernykh, E. B. Sal’nikova, A. B. Kotov, V. P. Kovach, S. Z. Yakovleva, and A. M. Fedoseenko, “Porozhnaya granitoids of the Enisei ophiolite belt: indicators of Neoproterozoic events on the Enisei Ridge,” Dokl. Earth Sci. 381, 1043–1046 (2001).
56. V. A. Vernikovsky, A. Yu. Kazansky, N. Yu. Matushkin, D. V. Metelkin, and J. K. Sovetov, “The geodynamic evolution of the folded framing and the western margin of the Siberian craton in the Neoproterozoic: geological, structural, sedimentological, geochronological, and paleomagnetic data,” Russ. Geol. Geophys. 50 (4), 372–387 (2009).
57. N. I. Volkova and E. V. Sklyarov, “High-pressure complexes of Central Asian fold belt: geologic setting, geochemistry, and geodynamic implications,” Russ. Geol. Geophys. 48 (1), 625–628 (2007).
58. N. I. Volkova, V. V. Khlestov, V. P. Sukhorukov, and M. V. Khlestov, “Geochemistry of metamorphosed pillow basalts of the Chara Zone, NE Kazakhstan,” Dokl. Earth Sci. 467, 350–354 (2016).
59. V. V. Vrublevskii, V. V. Reverdatto, A. E. Izokh, I. F. Gertner, D. S. Yudin, and P. A. Tishin, “Neoproterozoic carbonatite magmatism of the Yenisei Ridge, Central Siberia: 40Ar/39Ar geochronology of the Penchenga rock complex,” Dokl. Earth Sci. 437, 443–448 (2011).
60. D. A. Wood, “The application of a Th-Hf-Ta diagram to problems of tectonomagmatic classification and to establishing the nature of crustal contamination of basaltic lavas of the British Tertiary volcanic province,” Earth Planet. Sci. Lett. 50, 11–30 (1980).
61. V. V. Yarmolyuk, V. I. Kovalenko, V. P. Kovach, E. Yu. Rytsk, I. K. Kozakov, A. B. Kotov, and E. B. Sal’nikova, “Early stages of the paleoasian ocean formation: results of geochronological, isotopic, and geochemical investigations of Late Riphean and Vendian–Cambrian complexes in the Central Asian Foldbelt,” Dokl. Earth Sci. 410 (5), 1184–1189 (2006).