O'LEARY, N., WHITE, N., TULL, S., BASHILOV, V., KUPRIN, V., NATAPOV, L., MACDONALD, D. (2004) Evolution of the Timan–Pechora and South Barents Sea basins. Geological Magazine, 141 (2) 141-160 doi:10.1017/s0016756804008908

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Reference Type	Journal (article/letter/editorial)
Title	Evolution of the Timan–Pechora and South Barents Sea basins
Journal	Geological Magazine
Authors	O'LEARY, N.		Author
	WHITE, N.		Author
	TULL, S.		Author
	BASHILOV, V.		Author
	KUPRIN, V.		Author
	NATAPOV, L.		Author
	MACDONALD, D.		Author
Year	2004 (March)	Volume	141
Issue	2
Publisher	Cambridge University Press (CUP)
DOI	doi:10.1017/s0016756804008908Search in ResearchGate
	Generate Citation Formats
Mindat Ref. ID	259386	Long-form Identifier	mindat:1:5:259386:3
GUID	0
Full Reference	O'LEARY, N., WHITE, N., TULL, S., BASHILOV, V., KUPRIN, V., NATAPOV, L., MACDONALD, D. (2004) Evolution of the Timan–Pechora and South Barents Sea basins. Geological Magazine, 141 (2) 141-160 doi:10.1017/s0016756804008908
Plain Text	O'LEARY, N., WHITE, N., TULL, S., BASHILOV, V., KUPRIN, V., NATAPOV, L., MACDONALD, D. (2004) Evolution of the Timan–Pechora and South Barents Sea basins. Geological Magazine, 141 (2) 141-160 doi:10.1017/s0016756804008908
In	(2004, March) Geological Magazine Vol. 141 (2) Cambridge University Press (CUP)
Abstract/Notes	We have analysed 129 stratigraphic sections from the Timan–Pechora basin, from its adjacent continental shelf and from the South Barents Sea basin, in order to determine whether existing models of extensional sedimentary basin formation can be applied to these intracratonic basins or whether new mechanisms of formation need to be invoked. The subsidence history of each section has been calculated using standard backstripping techniques. An inverse model, based on finite-duration lithospheric stretching, has then been used to calculate the distribution of strain rate as a function of time required to fit each subsidence profile. Results demonstrate an excellent fit between theory and observation. By combining our analysis with independent field-based and geophysical observations, we show that the Timan–Pechora basin underwent at least four phases of mild lithospheric stretching during the Phanerozoic (β<1.2). These phases occurred in Ordovician, Late Ordovician–Silurian, Middle–Late Devonian and Permian–Early Triassic times. Growth on normal faults, episodes of volcanic activity and regional considerations provide corroborative support for the existence of all four phases. Although less well constrained, subsidence data from the South Barents Sea basin are consistent with a similar Early–Middle Palaeozoic history. The main difference is that Permian–Early Triassic extension is substantially greater than that seen onshore. This similarity implies structural connectivity throughout their respective evolutions. Finally, subsidence modelling demonstrates that rapid foreland basin formation, associated with the Uralian Orogeny, was initiated in Permo-Triassic times and is confined to the eastern margin of the Timan–Pechora basin. Coeval foreland subsidence does not occur on the eastern margin of the South Barents Sea basin, supporting the allochthonous nature of Novaya Zemlya. The most puzzling result is the existence of simultaneous lithospheric extension and foreland loading in Permian–Early Triassic times. This juxtaposition is most clearly seen within the Timan–Pechora basin itself and suggests that convective drawdown may play a role in foreland basin formation.

	*Wilson, C. D. V. (1953) Magnetometric Mapping for Haematite in South Wales. Geological Magazine, 90 (2) 140-141 doi:10.1017/s0016756800064062*
	Jeans, C. V. (2004) WHITE, J. D. L. & RIGGS, N. R. (eds) 2001. Volcaniclastic Sedimentation in Lacustrine Settings. International Association of Sedimentologists Special Publication no. 30. vii + 309 pp. Oxford: Blackwell Science. Price £52.50 (paperback) ISBN 0 632 05847 1. Geological Magazine, 141 (1) 106 doi:10.1017/s001675680332878x
	WILLNER, A. P., WARTHO, J.-A., KRAMM, U., PUCHKOV, V. N. (2004) Laser 40Ar/39Ar ages of single detrital white mica grains related to the exhumation of Neoproterozoic and Late Devonian high pressure rocks in the Southern Urals (Russia) Geological Magazine, 141 (2) 161-172 doi:10.1017/s0016756803008628
	Kotik, I. S.; Maydl, T. V.; Nechaev, M. S.; Kotik, O. S.; Pronina, N. V.; Sokolova, L. V. (2025) Depositional Environments and Petroleum Generation Potential of Lower Devonian Rocks in the Chernyshev Ridge, Timan–Pechora Petroleum Province. Lithology and Mineral Resources, 60 (2). doi:10.1134/s0024490224700883
	*(2004) W. B. HARLAND 1917–2003. Geological Magazine, 141 (2) 113 doi:10.1017/s001675680400915x*
	Vladimir V. Shimansky1, Michail D., (2000) Abstract: Models of Stratigraphically Trapped Reservoir Formation (Western Siberia and Timan Pechora Basins, Russia) AAPG Bulletin, 84. doi:10.1306/a9672e74-1738-11d7-8645000102c1865d
	*MOYNE, S., NEIGE, P. (2004) Cladistic analysis of the Middle Jurassic ammonite radiation. Geological Magazine, 141 (2) 115-123 doi:10.1017/s0016756804009082*
	Sergeev, V. N., Semikhatov, M. A., Fedonkin, M. A., Veis, A. F., Vorob’eva, N. G. (2007) Principal stages in evolution of Precambrian organic world: Communication 1. Archean and Early Proterozoic. Stratigraphy and Geological Correlation, 15 (2). 141-160 doi:10.1134/s0869593807020025
	Antipov, S. V., Bilashenko, V. P., Vysotskii, V. L., Kalantarov, V. E., Kobrinskii, M. N., Sarkisov, A. A., Sotnikov, V. A., Shvedov, P. A., Ibraev, R. A., Sarkisyan, A. S. (2015) Prediction and Evaluation of the Radioecological Consequences of a Hypothetical Accident on the Sunken Nuclear Submarine B-159 in the Barents Sea. Atomic Energy, 119 (2) 132-141 doi:10.1007/s10512-015-0039-x
	*(1875) Miscellaneous. Geological Magazine, S. 2 Vol. 2 (3) 141 doi:10.1017/s0016756800157851*
	*BARTOV, YUVAL, SAGY, AMIR (2004) Late Pleistocene extension and strike-slip in the Dead Sea Basin. Geological Magazine, 141 (5) 565-572 doi:10.1017/s001675680400963x*

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O'LEARY, N., WHITE, N., TULL, S., BASHILOV, V., KUPRIN, V., NATAPOV, L., MACDONALD, D. (2004) Evolution of the Timan–Pechora and South Barents Sea basins. Geological Magazine, 141 (2) 141-160 doi:10.1017/s0016756804008908

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