Chronostratigraphy of the Hottah terrane and Great Bear magmatic zone of Wopmay orogen, Canada, and exploration of a terrane translation model

Abstract

The Paleoproterozoic Hottah terrane is the western-most exposed bedrock of the Canadian Shield, and a critical component for understanding the evolution of the Wopmay orogen. Thirteen new high-precision U-Pb zircon crystallization ages are presented and support field observations of a volcano-plutonic continuum from Hottah terrane through to the end of the Great Bear magmatism; from >1950 Ma to 1850 Ma. The new crystallization ages, new geochemical data, and newly published detrital zircon U-Pb data, are used to challenge hitherto accepted models for the evolution of the Hottah terrane as an exotic arc and micro-continent that arrived over a west-dipping subduction zone and collided with the Slave craton at ca. 1.88 Ga. While the Hottah terrane does have a tectonic history that is distinct from that of the neighbouring Slave craton, it shares a temporal history with a number of domains to the south and east, domains that were tied to the Slave craton by ca. 1.97 Ga. It is interpreted herein that Hottah terrane began to the south of its current position and evolved in an active margin over an always east-dipping subduction system that began prior to ca. 2.0 Ga and continued to ca. 1.85 Ga, and underwent tectonic switching and migration. The stratigraphy of the ca. 1913 to 1900 Ma Hottah plutonic complex and Bell Island Bay Group comprises a subaerial rifting arc sequence, followed by basinal opening that is represented by marginal marine quartz arenite and overlying ca. 1893 Ma pillowed basalt flows and lesser rhyodacites. We interpret this stratigraphy to record Hottah terrane rifting off its parental arc crust, in essence the birth to the new Hottah terrane. This model is similar to rapidly rifting arcs in active margins, for example modern Baja California. These rifts generally occur at the transition between subduction zones (e.g., Cocos-Rivera plates) and transtensional shear zones (e.g., San Andreas fault) and we suggest that extension driven transtensional shearing, or more simply terrane translation, was responsible for the evolution of Bell Island Bay Group stratigraphy and that it transported this newly born Hottah terrane laterally (northward in modern coordinates), arriving adjacent to the Slave craton at ca. 1.88 Ga. Renewed east-dipping subduction led to the Great Bear arc flare-up at ca. 1876 Ma, continuing to ca. 1869 Ma. This was followed by voluminous Great Bear plutonism until ca. 1855 Ma. The model implicates that it was the westerly Nahanni terrane and its subducting oceanic crust that collided with this active margin, shutting down the > 120 million year old, east-dipping subduction system.