Evolution of the Mongol-Okhotsk Ocean as constrained by new palaeomagnetic data from the Mongol-Okhotsk suture zone, Siberia

Pan

Int J Earth Sci (Geol Rundsch)

et al. 2008

Sensitive high-resolution ion microprobe (SHRIMP) U-Pb dating, laser-ablation multi-collector IC-PMS Hf isotope and electron microprobe element analyses of inherited/antecrystal and magmatic zircons from five granitoid intrusions of Linxi area, in the southern segment of the Great Xing'an Range of China were integrated to solve continental crustal growth mechanisms. These intrusions were divided into two suites. Suites 1 and 2 are mainly granodiorite and syenogranite and correspond to magnesian and ferroan granites, respectively. SHRIMP dating establishes an Early Cretaceous (135-125 Ma) age for most Linxi granitoids and a time of *146 Ma when their source rocks were generated or re-melted. However, some granitoids were generated in Early Triassic (241 Ma) and Late Jurassic (146 Ma), after their source rock experienced precursory melting episodes at 263 Ma and 165 Ma, respectively. All zircon 206 Pb/ 238 U ages (\300 Ma, n = 100), and high positive zircon e Hf (t) values (n = 175) suggest juvenile source materials with an absence of Precambrian basement.Hf-Nd isotopic decoupling of Linxi granitoids suggests a source component of pelagic sediments, i.e. Paleozoic subduction accretion complexes. Zircon e Hf (t) values (t = 263-165 Ma) form a trend sub-parallel to the depleted mantle Hf isotope evolution curve, whilst those with t = 146-125 Ma fall markedly below the latter. The first trend indicates a provenance from essentially subducted oceanic slabs. However, the abrupt e Hf (t) decrease, together with extensive Early Cretaceous magmatism, is interpreted as reflecting mantle upwelling and resultant underplating, and exhumation of subducted oceanic slabs. Suite 1 granitoids derive mainly from subducted oceanic slabs or Paleozoic subduction accretion complex, whereas Suite 2 from underplated mafic rock and, subordinately, Paleozoic subduction accretion complex. Compositions of Suites 1 and 2 depend on the hydrous, oxidized or relatively anhydrous, reduced nature of source rocks. Among each of these five intrusions, magmatic zircons have systematically lower 176 Hf/ 177 Hf than inherited/antecrystal zircons. Hf isotopic and substituting element profiles through inherited/antecrystal zircons (t = 263 to *146 Ma) indicate repeated low melt-fraction melting in the source region. In contrast, profiles through inherited/antecrystal and magmatic zircons (t = 146-125 Ma) reveal melting region expansion with a widening range of source compositions and increasing melt fractions. These results lead to the conclusion that continental growth in this region involved a three-step process. This included subduction accretion and repeated underplating, intermediary differentiation of juvenile rocks, and granitoid production from these differentiated rocks.

Section: Osmentioning

confidence: 99%

Three-step continental-crust growth from subduction accretion and underplating, through intermediary differentiation, to granitoid production

Pan

Int J Earth Sci (Geol Rundsch)

et al. 2008

“…Certainly not. Şengör and his co-workes have clearly shown that the Mongol-Okhotsk Ocean did not close until the end of the Jurassic using not only age but also stratigraphic, structural and petrographic data, and their conclusion is corroborated by more recent palaeomagnetic observations (Kravchinsky et al, 2002).…”

Section: Comparative Anatomy Of Mountain Beltsmentioning

confidence: 83%

Outcrops, isotopic ages, terranes and the undesirable fate of tectonic interpretations

Şengör

2013

Geodinamica Acta

This paper embodies a criticism of the recent proliferation of papers reporting high-quality isotopic ages combined with extremely poor tectonic interpretations resulting from an absence or non-consideration of high-quality geological mapping and ignorance of the basic tenets of tectonics, particularly of the comparative anatomy of mountain ranges. It appears that some geologists began to think that chronology (not even chronostratigraphy) alone is sufficient for understanding the geological history of a region. This seems a result of the mistaken belief that one kind of data can yield the clues to the entire geological history of an area. The kind of data chosen has become a matter of the most recent fashion, a sort of 'methodomania,' not what is required by the geological nature of the region under investigation. The appreciation that geological data are woefully incomplete and inadequate in most cases (even where superb geological maps exist) to generate perfect reconstructions is being lost. This brings with it the grave danger of impoverishing our conceptual repertoire of geological structures and evolutionary paths of tectonic entities such as orogens, taphrogens and keirogens leading to poor interpretations bereft of any sound geological basis.Erde, wie wir sie jetzt vor uns gewahr werden. Auch hier ist eine genetische Betrachtung wünschenswert. Alles, was wir entstanden sehen, und eine Succesion dabei gewahr werden, davon verlangen wir dieses successive Werden einzusehen. So wie die wahre Geschichte über-haupt nicht das Geschehene aufzählt, sondern wie sich das Geschehene auseinander entwickelt und darstellt. (Johann Wolfgang von Goethe) Wenn in der Zeichnung der Welt-und Länderkarten die Landesnatur dargestellt wird, so sollte dieß immer nur mit Bewußtsein der bestimmten Hypothese geschehen, wie dieß Absichtlich von einem Buache, Gatterer, v. Zimmermann, Fr. Schulz, Reichard, und nicht ohne Nutzen für die Wissenschaft, durchgeführt und von Zeune nach allen Seiten beleuchtet ist. Aber durch das in seiner Thätigkeit ohne Bewußtsein, nur blind folgende Heer der Nachahmer geht auch dieser Nutzen wieder verloren, und es tritt statt des Bildes der Natur ein Zerrbild hervor, welches die physikalische Erdkunde eben so als Quelle verwerfen sollte, wie die Physiognomik schon unrichtig gezeichnete Schattenrisse keiner Aufmerksamkeit würdig hält. (Carl Ritter) La rupture entre l'homme et la terre, c'est aussi la rupture entre l'homme et lui-même. (Gustave Thibon) 1

“…Стабильный структурный ансамбль до-кембрийских каледонских террейнов Северного мегаблока, включающий Тувино-Монгольский ми-кроконтинент, сформировался к концу ордовика. Этот мегаблок осложнен структурой Монголо-Охотского залива Палеопацифика, последователь-но закрывавшегося с запада на восток в позднем палеозое и мезозое с быстрым смыканием берегов в конце юры -начале мела [Şengör, Natal'in, 1996;Zorin, 1999;Kravchinsky et al, 2002]. Герцинские (силлурийско-каменноугольные) островные дуги Южного мегаблока (как части Южномонгольско-Хинганской или Тяньшань-Южнохингалинской зо-ны) отделялись от Северо-Китайского кратона и аккретированных к нему террейнов Солонкерским швом [Yanshin, 1974;Belichenko, Boos, 1990;Tseden et al, 1992;Kozakov et al, 2007;Windley et al, 2007;Parfenov et al, 2003;Wan, 2010].…”

Section: соотношения низкоскоростных аномалий переходного слоя с фрагunclassified

The latest geodynamics in Central Asia: primary and secondary mantle melting anomalies in the context of orogenesis, rifting, and lithospheric plate motions and interactions

Chuvashova¹,

Рассказов²,

Сунь³

2017

Geodin. tektonofiz.

A comprehensive model for deep dynamics in Asia has been developed from the data on the evolution of melting anomalies in the context of lithospheric plate motions, interactions, orogeny, and rifting. The key components of our model are the primary (transition layer) and secondary (upper mantle) melting anomalies (Gobi, Baikal, and North Transbaikalia; and Hangay, Sayan, and Vitim, respectively). It is inferred that the primary melting anomalies originated at the beginning of the latest geodynamic stage (ca. 90 Ma) as a result of the transition layer distortion by lower mantle flows. Such primary anomalies were caused by avalanche collapses of the slab material that had been stagnated under the closed fragments of the Solonker, Ural-Mongolian paleooceans and the Mongol-Okhotsk Bay of Paleopacific. The secondary melting anomalies occurred due to the Early-Middle Miocene structural reorganization in the Pacific-Asian and Indo-Asian interaction zones. The primary melting anomalies governed the spatial distribution of forces and processes of the latest geodynamic stage. The secondary melting anomalies resulted from the lithospheric motions relative to the primary anomalies and provided for the development of orogeny and rifting. The BaikalMongolian corridor of asthenospheric flows was limited by the lateral zones of convergent interactions between India and Asia in the southwest, and North America and Asia in the northeast. In these lateral zones, Late Phanerozoic paleoslabs and ascending mantle fluxes were revealed in the transition layer, as well as in the upper mantle, without any destruction by the asthenospheric flows.