Abstract
U–Pb age spectra of detrital zircons related to the East European Platform could be traced in paragneiss through the whole Mid-German-Crystalline Zone (Variscides, Central Europe) from the Odenwald via the Spessart to the Ruhla crystalline forming an exotic unit between Armorica and Laurussia. The depositional ages of the paragneiss are defined by the youngest age of the detrital zircons and the oldest intrusion ages as Ordovician to Silurian. The Ediacaran dominated age spectrum of detrital zircons from the paragneiss of the East Odenwald suggests the latter to be derived from the shelf of the East European Platform (Baltica), which was influenced by the 1.5 Ga old detritus delivered from a giant intrusion (Mazury granitoid, Poland). The detrital zircon age spectrum of the lower Palaeozoic paragneiss of the East Odenwald and sandstone of the northern Holy Cross Mountains are identical. The pure Sveconorwegian spectrum of the lower Palaeozoic quartzite from the Spessart, (Kirchner and Albert Int J Earth Sci 2020) and the Ruhla (Zeh and Gerdes Gondwana Res 17:254–263, 2010) could be sourced from Bornholm and southern Sweden. A U–Pb age spectrum with 88% Palaeozoic detrital zircons from a volcano-sedimentary rock of the East Odenwald is interpreted to be derived from a Silurian magmatic arc (46%), which was probably generated during the drift of the Mid-German-Crystalline Zone micro-continent to the south. A tentative plate tectonic model of Mid-German-Crystalline Zone is presented taking into account (a) the East European Platform related age spectra of the detrital zircons (b) the Ordovician to Silurian depositional age of the metasediments (c) the Silurian and Early Devonian intrusion age of the plutonic and volcanic rocks and (d) the U–Pb ages of the Middle Devonian high-grade metamorphism. The East European Platform-related part of the Mid-German-Crystalline Zone is interpreted as a micro-continent, which drifted through the Rheic Ocean to the south and collided with the Saxothuringian (Armorican Terrane Assemblage) during the Early Devonian. Such large-scale tectonic transport from the northern continent to the southern continent is also known from the SW Iberia, where Laurussia-related metasediments of the Rheic suture zone are explained by a large scale tectonic escape (Braid et al. J Geol Soc Lond 168:383–392, 2011).
Highlights
There is a consensus in the paleogeographic models of the configuration of the continents during the Palaeozoic in Central Europe (Cocks and Torsvik 2006; Torsvik and Cocks 2017 and references there in)
The Avalonian terrane was a part of West Gondwana, which split off during the early Palaeozoic and collided after the closure of the TornquistOceanwith Baltica in the Late Ordovician (East Avalon) and with Laurentia (West Avalon) after the closure of the Iapetus Oceanin the Silurian
A part of the Mid-German-Crystalline Zone belongs during the lower Palaeozoic to the shelf of the East European Platform (Baltica)
Summary
There is a consensus in the paleogeographic models of the configuration of the continents during the Palaeozoic in Central Europe (Cocks and Torsvik 2006; Torsvik and Cocks 2017 and references there in). The Avalonian terrane was a part of West Gondwana, which split off during the early Palaeozoic and collided after the closure of the TornquistOceanwith Baltica in the Late Ordovician (East Avalon) and with Laurentia (West Avalon) after the closure of the Iapetus Oceanin the Silurian. This subduction/collision, referred to as the Caledonian Orogeny, resulted in the formation of a large northern continent, Laurussia (Torsvik and Rehnström 2003; Winchester et al 2002, 2006; Torsvik and Cocks 2013; Cocks and Torsvik 2006; Cocks and Fortey 2009; von Raumer et al 2002, 2003; Murphy et al 2004b; Nance et al 2008; Domeier 2016)
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