The dating of shallow faults in the Earth's crust

Pluijm, Ben A. van der; Hall, Chris M.; Vrolijk, Peter; Pevear, David R.; Covey, Michael C.

doi:10.1038/35084053

Cited by 239 publications

(142 citation statements)

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“…The illite crystallinity is a measure of crystallite thickness, but is also influenced by structural distortion, e.g., dependent age spectra (e.g., Pluijm et al, 2001;Solum et al, 2005;Löbens et al, 2011;Bense et al, 2014;Torgersen et al, 2015) that have been explained by two main processes:…”

Section: Illite and Temperaturementioning

confidence: 99%

“…Therefore, the K-Ar ages are bulk ages for the dated fine fractions, meaning that any K-bearing mineral present in the fine fractions will contribute to the age. Two main sources of 'contami nati on' must be considered: (1) Finely crushed host-rock minerals: They can be inherited from both sedimentary and crystalline host rocks (e.g., Vrolijk & van der Pluijm, 1999;Pluijm et al, 2001;Zwingmann et al, 2010b;Torgersen et al, 2014). The finest fractions are generally less affected by, or even free from this type of contamination.…”

Section: Illite and Temperaturementioning

confidence: 99%

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Post-Caledonian brittle deformation in the Bergen area, West Norway: results from K–Ar illite fault gouge dating

Ksienzyk¹,

Wemmer²,

Jacobs³

et al. 2016

NJG

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Post-Caledonian extension during orogenic collapse and Mesozoic rifting in the West Norway-northern North Sea region was accommodated by the formation and repeated reactivation of ductile shear zones and brittle faults. Offshore, the Late Palaeozoic-Mesozoic rift history is relatively well known; extension occurred mainly during two rift phases in the Permo-Triassic (Phase 1) and Mid-Late Jurassic (Phase 2). Normal faults in the northern North Sea, e.g., on the Horda Platform, in the East Shetland Basin and in the Viking Graben, were initiated or reactivated during both rift phases. Onshore, on the other hand, information on periods of tectonic activity is sparse as faults in crystalline basement rocks are difficult to date. KAr dating of illite that grows synkinematically in fine-grained fault rocks (gouge) can greatly help to determine the time of fault activity, and we apply the method to nine faults from the Bergen area. The K-Ar ages are complemented with X-ray diffraction analyses to determine the mineralogy, illite crystallinity and polytype composition of the samples. Based on these new data, four periods of onshore fault activity could be defined: (1) the earliest growth of fault-related illite in the Late Devonian-Early Carboniferous (>340 Ma) marks the waning stages of orogenic collapse; (2) widespread latest Carboniferous-Mid Permian (305-270 Ma) fault activity is interpreted as the onset of Phase 1 rifting, contemporaneous with rift-related volcanism in the central North Sea and Oslo Rift; (3) a Late Triassic-Early Jurassic (215-180 Ma) period of onshore fault activity postdates Phase 1 rifting and predates Phase 2 rifting and is currently poorly documented in offshore areas; and (4) Early Cretaceous (120-110 Ma) fault reactivation can be linked either to late Phase 2 North Sea rifting or to North Atlantic rifting.

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Section: Illite and Temperaturementioning

confidence: 99%

Section: Illite and Temperaturementioning

confidence: 99%

Post-Caledonian brittle deformation in the Bergen area, West Norway: results from K–Ar illite fault gouge dating

Ksienzyk¹,

Wemmer²,

Jacobs³

et al. 2016

NJG

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“…Ages of both clay 'end-member' components can be determined due to differences in thermally activated Ar release between authigenic and detrital clay minerals, as revealed by laser-stepped heating (Onstott et al 1997). Dating combined with detailed X-ray diffi'action analysis of several grain size fractions of clays in fault gouges allows for the extrapolation of ages of clay mixtures to both pure authigenic and pure detrital 'end-member' ages (van der Pluijm et al 2001). While considerable complexities exist in the processes governing the authigenic growth of mica, such as Ostwald ripening (Eberl et al 1990;Kfibler & Jaboyedoff 2000) and the reaction kinetics of mineral homogenization (Livi et al 2002), these new techniques offer exciting prospects for the complicated dating of fault gouges and our understanding of brittle faults.…”

Section: Vance Etalmentioning

confidence: 99%

“…In order to improve our understanding of the evolution of (semi-)brittle fault rocks like fault gouges or pseudotachylytes, both in-situ and stepwise-heating (or even better their combined use) 4~ dating have recently been applied (Mfiller et al 2002;van der Pluijm et al 2001). Fault gouges, which predominantly consist of fine-grained4clay 3 minerals, pose enormous difficulties for Ar/-9Ar dating.…”

Section: Vance Etalmentioning

confidence: 99%

Geochronology: linking the isotopic record with petrology and textures — an introduction

Vance

Müller

Villa³

2003

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Abstract:One of the key aims of geochronology, and the subject of the papers in this Special Publication, is the linkage of isotopic ages to petrological and textural information. A close link between the two types of information greatly improves the constraints available from geochronology on the nature and rates of lithospheric processes such as metamorphism and deformation. There have been several key advances in this area over the past 10-20 years, relating to increased precision and accuracy of isotopic ages but also, and crucially, to the spatial resolution available to geochronologists. This resolution now approaches that on which petrological, chemical and textural information is obtained. We also, in this introduction, identify the barriers that have impeded further progress, which relate both to technical issues as well as to problems of understanding. Finally we set the papers in this volume in the context of the preceding discussion and outline the key ways in which these papers point towards further progress in the future.Time has always been recognized as a key variable in the Earth sciences, both in its own right and through the constraints that chronological information provides on the rates of, and hence the physical mechanisms for, Earth processes. In the study of the dynamics of the Earth's lithosphere during orogenesis and metamorphism, one of the key requirements of any time datum is that it is relatable in a straightforward manner to other geological information, such as data on temperature, pressure and deformation. It is only through this linkage that chronometric information can achieve its full potential in contributing to progress in understanding the dynamics of mountain belts and other metamorphic settings. This linkage is the focus of the set of papers in this volume, which emanate from a special symposium at the 2002 Goldschmidt Conference, held at Davos, Switzerland. The topic under discussion has been the subject of a review by one of us recently (Mtiller 2003). Inevitably, there is some overlap between this paper and Miiller (2003). However, the emphasis of the two papers is slightly different, with Mtiller (2003) concentrating largely on new in-situ techniques and their resulting prospects, whereas here we give a broader overview of the whole subject, with more emphasis on the dating of high temperature processes and the interrelated achievements of both modelling and experimental work in petrology. We also aim to highlight some general issues that are dealt with in specifics in the subsequent contributions. First, we give a brief account of the progress that has been made over the past two decades in our ability to extract the timing and conditions of deformation and metamorphism from minerals and in the interpretive framework in which these new data are analysed. Next we identify three key barriers that initially impeded further progress and which have been and continue to be the subjects of intensive research eflbrt. Finally, we discuss ways that are being developed to surm...

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“…Dating of fine grained minerals (< 2 µm) such as illite can provide constraints on timing of active retrograde fault movement in the shallow crust (van der Pluijm et al, 2001;Zwingmann and Mancktelow, 2004;Zwingmann et al, 2010, Pleuger et al, 2012. K-Ar dating is a reliable tool to constrain authigenic formation of fined-grain illite clay minerals in brittle faults to circumvent 39 Ar recoil by 40 Ar/ 39 Ar dating (Clauer et al, 2012, Torgersen et al, 2015.…”

Section: K-armentioning

confidence: 99%

Influence of deformation and fluids on Ar retention in white mica: Dating the Dover Fault, Newfoundland Appalachians

Kellett

Warren

Larson

et al. 2016

Lithos

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The dating of shallow faults in the Earth's crust

Cited by 239 publications

References 18 publications

Post-Caledonian brittle deformation in the Bergen area, West Norway: results from K–Ar illite fault gouge dating

Post-Caledonian brittle deformation in the Bergen area, West Norway: results from K–Ar illite fault gouge dating

Geochronology: linking the isotopic record with petrology and textures — an introduction

Influence of deformation and fluids on Ar retention in white mica: Dating the Dover Fault, Newfoundland Appalachians

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