An episodic Cretaceous cooling model for the Otago‐Marlborough Schist, New Zealand, based on<sup>40</sup>Ar/<sup>39</sup>Ar white mica ages

The Cretaceous was a time of widespread convergent and extensional thermotectonic activity in New Zealand. K-Ar, Ar-Ar, and fission track dates thus far obtained from the Haast Schist belt record cooling and exhumation of Jurassic-Cretaceous age in Otago and late Neogene age in the Southern Alps. In this paper we present results of a pilot U-Pb and Sm-Nd geochronological investigation that at last provide ages of local amphibolite facies mineral growth in the Haast Schist, rather than exhumation ages.We report a U-Pb age of 71 ± 2 Ma for four monazite fractions from aMataketake Range garnet biotite greyschist; this result is within error of the U-Pb age of nearby anatectic granite pegmatite dikes. We also report a four-point Sm-Nd isochron age of 100 ± 12 Ma for titanite, garnet, hornblende, and whole rock fractions from a Haast River amphibolite. The two dated rocks are c. 20 km apart, apparently alongstrike from each other and in the same mapped metamorphic zone. Our results support a model of protracted, episodic, spatially heterogeneous Cretaceous mineral growth in the Haast Schist, with the generation of anatectic pegmatites in the latest Cretaceous.In an appendix we describe our unsuccessful attempts to find and date other high closure temperature minerals by various methods, including U-Pb dating of titanite in an Otago greyschist and in an Alpine calcmylonite.

Section: Introductionmentioning

confidence: 90%

U‐Pb and Sm‐Nd ages from the Alpine Schist, New Zealand

Mortimer¹,

Cooper²

2004

“…Graham (1985) dated schistose Rakaia rocks (Haast Schist) from the central North Island and could not verify whether a Late Jurassic to Early Cretaceous uplift event was of regional or only local significance. In contrast, Little et al (1999) distribution from the MTZ arc to the west, but uplift declined to the north (Fig. 7).…”

Section: Possible Paleogeographic Reconstructionsmentioning

confidence: 85%

Terrane affiliation and terrane boundaries of Mesozoic accretionary complexes, northeastern North Island, New Zealand: Some implications from recycled elastics

Leverenz

Ballance

2001

In the late Mesozoic Waioeka petrofacies in northeastern North Island, New Zealand, sandstone pebbles differ significantly in petrography from their enclosing sandy conglomerate matrix, and yield contrasting provenance signatures. The compositional contrast demonstrates the extrabasinal origin of most of the analysed clasts. Differences in clast provenance have been used to review boundaries and the terrane affiliation to the neighbouring Torlesse and Waipapa composite terranes.A previously postulated Cretaceous large-scale dextral strike-slip displacement of eastern North Island along the Wellington-Mohaka-Whakatane Fault is supported by these data. The timing for this movement can be further bracketed between c. 98 and 85 Ma. The Waioeka and Omaio petrofacies, formerly attributed to the Torlesse terranes as the Waioeka Subterrane, are reinterpreted to constitute a separate terrane (Waioeka-Mata River Terrane). However, the westernmost portion of the former Waioeka Subterrane, west of the Wellington-Mohaka-Whakatane Fault, is considered to be part of the Waipapa composite terrane.

“…(1 (Little et al 1999). Uplift and exhumation of the schist was accompanied by regional extension and the development of low-angle ductile shear zones at 135Á105 Ma (Deckert et al 2002;Forster & Lister 2003).…”

Section: Geological Settingmentioning

confidence: 99%

“…Mortimer & Cooper (2004) suggest that the timing of highest grade metamorphic mineral growth in the Otago Schist was during the Jurassic. Little et al (1999) inferred that peak metamorphism in the Otago Schist occurred in the middle Jurassic (170Á180 Ma) and that the Otago Schist was held at mid-to-lower crustal depths until 135 Ma. Thereafter, exhumation occurred at 0.6Á1 mm yr…”

Section: Geological Settingmentioning

confidence: 99%

“…Little et al (1999) inferred that peak metamorphism in the Otago Schist occurred in the middle Jurassic (170Á180 Ma) and that the Otago Schist was held at mid-to-lower crustal depths until 135 Ma. Thereafter, exhumation occurred at 0.6Á1 mm yr(1 (Little et al 1999). Uplift and exhumation of the schist was accompanied by regional extension and the development of low-angle ductile shear zones at 135Á105 Ma (Deckert et al 2002;Forster & Lister 2003).…”

mentioning

confidence: 99%

See 1 more Smart Citation

Cretaceous age, composition, and microstructure of pseudotachylyte in the Otago Schist, New Zealand

Barker

Sibson

Palin

et al. 2010

At Tucker Hill, in Central Otago, New Zealand, a series of pseudotachylyte veins are hosted in quartzofeldspathic schist. Chilled margins, microlites, flow banding, and the crystallisation of mineral phases absent from the host rock provide unequivocal evidence for melting during pseudotachylyte formation. Whole rock analyses of pseudotachylyte reveal c. 3 ) enrichment of K 2 O, Ba, and Rb, and similar depletion of Na 2 O, CaO, Sr, and Eu, as compared to host schist. Formation age of pseudotachylyte is 95.991.8 Ma as measured by total fusion 40 Ar/ 39 Ar analyses. Stepwise heating of pseudotachylyte matrix yields an excellently defined 40 Ar/ 39 Ar plateau age of 96.090.3 Ma. These well-defined ages are attributed to the presence of potassium feldspar, low abundance of inherited lithic material from the host rock, and few fluid inclusions containing extraneous Ar. We propose that formation of these pseudotachylyte veins was related to Cretaceous extensional uplift and exhumation of the Otago Schist.Keywords: pseudotachylyte; schist; Otago; Ar-Ar; geochronology; friction melting IntroductionThe presence of pseudotachylyte (former friction melt) in a fault zone is commonly attributed to frictional melting of rock during seismic slip (Sibson 1975). As such, pseudotachylytes are valuable indicators that an exhumed fault zone was seismically active. Pseudotachylytes have been described from inactive, ancient fault zones (e.g., Outer Hebrides Fault Zone: Sibson 1975;Maddock 1983;Kelley et al. 1994) and present day seismically active fault zones (e.g., the Alpine Fault: Sibson et al. 1981;Bossiere 1991;Warr et al. 2003). Determining the formation age of pseudotachylyte can reveal when a fault was seismically active, and provide information on the significance of a pseudotachylytebearing fault zone relative to the timing of other regional deformation events (Kelley et al. 1994;Magloughlin et al. 2001;Sherlock & Hetzel 2001;Mueller et al. 2002;Warr et al. 2003).In Central Otago, New Zealand, a series of pseudotachylyte veins are found in schist outcropping on Tucker Hill (1698 24?23??E; 458 15?16?S), near the township of Alexandra (Fig. 1). The pseudotachylyte veins are hosted in the garnet-biotite-albite zone of the greenschist facies of the Otago Schist, which forms the basement rocks of much of the Otago region (Mortimer 1993a, b). Tucker Hill is approximately 15 km to the east of the Cromwell Gorge Shear Zone and approximately 20 km to the south of the Rise and Shine Shear Zone, which are two Cretaceous age extensional shear zones (Deckert et al. 2002).Previous studies that have attempted to determine the age of pseudotachylyte utilising 40 Ar/ 39 Ar geochronology in various localities have met with varying degrees of success. In particular, accurate and geologically meaningful 40 Ar/ 39 Ar age determinations are negatively influenced by the presence of variable amounts of inherited crystals (i.e., incompletely melted) from host rocks (Magloughlin et al. 2001;Warr et al. 2007), argon loss by diffusion or alteration ...