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2019 | OriginalPaper | Chapter

12. Application of Fission-Track Thermochronology to Understand Fault Zones

Author : Takahiro Tagami

Published in: Fission-Track Thermochronology and its Application to Geology

Publisher: Springer International Publishing

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Abstract

The timing and thermal effects of fault motions can be constrained by fission-track (FT) thermochronology and other thermochronological analyses of fault zone rocks. Materials suitable for such analyses are produced by fault zone processes, such as: (1) mechanical fragmentation of host rocks, grain-size reduction of fragments and recrystallisation of grains to form mica and clay minerals, (2) secondary heating/melting of host rocks as the result of friction and (3) mineral vein formation as a consequence of fluid flow associated with fault motion. The geothermal structure of fault zones is primarily controlled by three factors: (a) the regional geothermal structure around the fault zone that reflects the background thermotectonic history of the study area, (b) frictional heating of wall rocks by fault motion and consequent heat transfer into surrounding rocks and (c) thermal effects of hot fluid flow in and around the fault zone. The thermal sensitivity of FTs is briefly reviewed, with a particular focus on the fault zone thermal processes, i.e., flash and hydrothermal heating. Based on these factors, representative examples as well as key issues, including sampling strategy, are highlighted for using thermochronology to analyse fault zone materials, such as fault gouges, pseudotachylytes and mylonites. The thermochronologic analyses of the Nojima fault in Japan are summarised, as an example of multidisciplinary investigations of an active seismogenic fault system. Geological, geomorphological and seismological implications of these studies are also discussed.

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previous chapter Fission-Track Thermochronology in Structural Geology and Tectonic Studies

next chapter Crustal Exhumation of Plutonic and Metamorphic Rocks: Constraints from Fission-Track Thermochronology

“Fault zone” is a term to describe the spatial extent along a fault where rocks are significantly deformed by the faulting.

Ault AK, Reiners PW, Evans JP, Thomson SN (2015) Linking hematite (U–Th)/He dating with the microtextural record of seismicity in the Wasatch fault damage zone, Utah, USA. Geology 43:771–774CrossRef

Baldwin SL, Fitzgerald PG, Malusà MG (2018) Chapter 13. Crustal exhumation of plutonic and metamorphic rocks: constraints from fission-track thermochronology. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer, Berlin

Boles JR, Eichhubl P, Garven G, Chen J (2004) Evolution of a hydrocarbon migration pathway along basin-bounding fault: evidence from fault cement. AAPG Bull 88:947–970CrossRef

Boullier AM, Ohotani T, Fujimoto K, Ito H, Dubois M (2001) Fluid inclusions in pseudotachylytes from the Nojima fault, Japan. J Geophys Res 106:21965–21977CrossRef

Brix MR, Stockhert B, Seidel E, Theye T, Thomson SN, Kuster M (2002) Thermobarometric data from a fossil zircon partial annealing zone in high pressure-low temperature rocks of eastern and central Crete, Greece. Tectonophysics 349:309–326CrossRef

Brodsky EE, Mori J, Fulton PM (2010) Drilling into faults quickly after earthquakes. EOS Am Geophys Un 91:237–238CrossRef

Carslaw HS, Jaeger JC (1959) Conduction of heat in solids. Oxford University Press, Oxford, 510 p

Cox SF (2005) Coupling between deformation, fluid pressures and fluid flow in ore-producing hydrothermal environments. In: Economic geology 100th anniversary volume, pp 39–75

Cox SF (2010) The application of failure mode diagrams for exploring the roles of fluid pressure and stress states in controlling styles of fracture-controlled permeability enhancement in faults and shear zones. Geofluids 10:217–233

d’Alessio MA, Blythe AE, Burgmann R (2003) No frictional heat along the San Gabriel Fault, California; evidence from fission-track thermochronology. Geology 31:541–544CrossRef

Donelick RA, O’Sullivan PB, Ketcham RA (2005) Apatite fission-track analysis. Rev Mineral Geochem 58:49–94CrossRef

Evans JP, Forster CB, Goddard JV (1997) Permeability of fault-related rocks, and implications for hydraulic structure of fault zone. J Struct Geol 19:1393–1404CrossRef

Flotte N, Plagnes V, Sorel D, Benedicto A (2001) Attempt to date Pliestocene normal faults of the Corinth-Patras Rift (Greece) by U/Th method, and tectonic implications. Geophys Res Lett 28:3769–3772CrossRef

Foster DA (2018) Chapter 11. Fission-track thermochronology in structural geology and tectonic studies. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer, Berlin

Fujimoto K, Ueda A, Ohtani T, Takahashi M, Ito H, Tanaka H, Boullier AM (2007) Borehole water and hydrologic model around the Nojima fault, SW Japan. Tectonophysics 443:174–182CrossRef

Fukuchi T, Imai N (2001) ESR and ICP analyses of the DPRI 500 m drill core samples penetrating through the Nojima Fault, Japan. Isl Arc 10:465–478CrossRef

Gallagher K (1995) Evolving temperature histories from apatite fission-track data. Earth Planet Sci Lett 136:421–435CrossRef

Haines SH, van der Pluijm BA (2008) Clay quantification and Ar–Ar dating of synthetic and natural gouge: application to the Miocene Sierra Mazatan detachment fault, Sonora, Mexico. J Struct Geol 30:525–538CrossRef

Holdsworth RE, Butler CA, Roberts AM (1997) The recognition of reactivation during continental deformation. J Geol Soc London 154:73–78CrossRef

Kamp PJJ, Green PF, White SH (1989) Fission track analysis reveals character of collisional tectonics in New Zealand. Tectonics 8:169–195CrossRef

Ketcham R (2018) Chapter 3. Fission track annealing: from geologic observations to thermal modeling. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer, Berlin

Lachenbruch H (1986) Simple models for the estimation and measurement of frictional heating by an earthquake. USGS Open File Rep 86-508

Little TA, Cox S, Vry JK, Batt G (2005) Variations in exhumation level and uplift rate along the oblique-slip Alpine fault, central Southern Alps, New Zealand. GSA Bull 117:707–723CrossRef

Magloughlin JF, Hall CM, van der Pluijm BA (2001) ⁴⁰Ar–³⁹Ar geochronometry of pseudotachylytes by vacuum encapsulation: North Cascade Mountains, Washington, USA. Geology 29:51–54CrossRef

Maino M, Casini L, Ceriani A, Decarlis A, Di Giulio A, Seno S, Setti M, Stuart FM (2015) Dating shallow thrusts with zircon (U–Th)/He thermochronometry—the shear heating connection. Geology 43:495–498CrossRef

Malusà MG, Fitzgerald PG (2018) Chapter 8. From cooling to exhumation: setting the reference frame for the interpretation of thermocronologic data. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer, Berlin

Malusà MG, Fitzgerald PG (2018) Chapter 10. Application of thermochronology to geologic problems: bedrock and detrital approaches. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer, Berlin

Matsumoto H, Yamanaka C, Ikeya M (2001) ESR analysis of the Nojima fault gouge, Japan, from the DPRI 500 m borehole. Isl Arc 10:479–485CrossRef

Metcalf JR, Fitzgerald PG, Baldwin SL, Munoz JA (2009) Thermochronology of a convergent orogeny: constraints on the timing of thrust faulting and subsequent exhumation of the Maladeta Pluton in the central Pyrenean axial zone. Earth Planet Sci Lett 287:488–503CrossRef

Mulch A, Cosca MA, Handy MR (2002) In-situ UV-laser ⁴⁰Ar/³⁹Ar geochronology of a micaceous mylonite: an example of defect-enhanced argon loss. Contrib Mineral Petrol 142:738–752CrossRef

Murakami M (2010) Average shear work estimation of Nojima fault from fission-track analytical data. Earth Monthly (in Japanese) 32:24–29

Murakami M, Tagami T (2004) Dating pseudotachylyte of the Nojima fault using the zircon fission-track method. Geophys Res Lett 31

Murakami M, Tagami T, Hasebe N (2002) Ancient thermal anomaly of an active fault system: zircon fission-track evidence from Nojima GSJ 750 m borehole samples. Geophys Res Lett 29

Murakami M, Kosler J, Takagi H, Tagami T (2006a) Dating pseudotachylyte of the Asuke Shear Zone using zircon fission-track and U–Pb methods. Tectonophysics 424:99–107CrossRef

Murakami M, Yamada R, Tagami T (2006b) Short-term annealing characteristics of spontaneous fission tracks in zircon: a qualitative description. Chem Geol 227:214–222CrossRef

Nuriel P, Rosenbaum G, Zhao JX, Feng Y, Golding SD, Villement B, Weinberger R (2012) U–Th dating of striated fault planes. Geology 40:647–650CrossRef

O’Hara K (2004) Paleostress estimated on ancient seismogenic faults based on frictional heating of coal. Geophys Res Lett 31

Oshiman N, Ando M, Ito H, Ikeda R (eds) (2001) Geophysical probing of the Nojima fault zone. Isl Arc 10:197–198CrossRef

Otsuki K, Monzawa N, Nagase T (2003) Fluidization and melting of fault gouge during seismic slip: identification in the Nojima fault zone and implications for focal earthquake mechanisms. J Geophys Res 108

Peterman ZE, Day W (1989) Early Proterozoic activity on Archean faults in the western Superior province—evidence from pseudotachylite. Geology 17:1089–1092CrossRef

Reimold WU, Jessberger EK, Stephan T (1990) ⁴⁰Ar–³⁹Ar dating of pseudotachylite from the Vredefort dome, South Africa: a progress report. Tectonophysics 171:139–152CrossRef

Ring U, Bernet M (2010) Fission-track analysis unravels the denudation history of the Bonar Range in the footwall of the Alpine fault, South Island, New Zealand. Geol Mag 147:801–813CrossRef

Rolland Y, Corsini M, Rossi M, Cox SF, Pennacchioni G, Mancktelow N, Boullier AM (2007) Comment on “Alpine thermal and structural evolution of the highest external crystalline massif: The Mont Blanc” by P. H. Leloup, N. Arnaud, E. R. Sobel, and R. Lacassin. Tectonics 26

Scholz CH (1980) Shear heating and the state of stress on faults. J Geophys Res 85:6174–6184CrossRef

Scholz CH (1988) The brittle-plastic transition and the depth of seismic faulting. Geol Runds 77:319–328CrossRef

Scholz CH (2002) The mechanics of earthquakes and faulting, 2nd edn. Cambridge University Press, Cambridge, UK, 471 p

Scholz CH, Beavan J, Hanks TC (1979) Frictional metamorphism, argon depletion, and tectonic stress on the Alpine fault, New Zealand. J Geophys Res 84:6770–6782CrossRef

Seront S, Wong TF, Caine JS, Forster CB, Bruhn RL, Fredrich JT (1998) Laboratory characterization of hydromechanical properties of a seismogenic normal fault system. J Struct Geol 20:865–881CrossRef

Seward D, Sibson RH (1985) Fission-track age for a pseudotachylite from the Alpine fault zone, New Zealand. New Z J Geol Geophys 28:553–557CrossRef

Sherlock SC, Watts LM, Holdsworth R, Roberts D (2004) Dating fault reactivation by Ar/Ar laserprobe: an alternative view of apparently cogenetic mylonite-pseudotachylite assemblages. J Geol Soc London 161:335–338CrossRef

Shimamoto T, Takemura K, Fujimoto K, Tanaka H, Wibberley CAJ (2001) Nojima fault zone probing by core analyses. Isl Arc 10:357–359CrossRef

Sibson RH (1975) Generation of pseudotachylite by ancient seismic faulting. Geophys J Royal Astron Soc 43:775–794CrossRef

Sibson RH (1977) Fault rocks and fault mechanisms. J Geol Soc London 133:191–213CrossRef

Sibson RH (1992) Implications of fault-valve behavior for rupture nucleation recurrence. Tectonophysics 211:283–293CrossRef

Simpson C (1985) Deformation of granitic rocks across the brittle-ductile transition. J Struct Geol 5:503–512CrossRef

Solum JG, van der Pluijm BA, Peacor DR (2005) Neocrystallization, fabrics, and age of clay minerals from an exposure of the Moab fault, Utah. J Struct Geol 27

Sueoka S, Kohn BP, Tagami T, Tsutsumi H, Hasebe N, Tamura A, Arai S (2012) Denudational history of the Kiso Range, central Japan, and its tectonic implications: constraints from low-temperature thermochronology. Isl Arc 21:32–52CrossRef

Sueoka S, Tsutsumi H, Tagami T (2016) New approach to resolve the amount of Quaternary uplift and associated denudation of the mountain ranges in the Japanese Islands. Geosci Front 7:197–210CrossRef

Tagami T (2005) Zircon fission-track thermochronology and applications to fault studies. Rev Mineral Geochem 58:95–122CrossRef

Tagami T (2012) Thermochronological investigation of fault zones. Tectonophysics 538–540:67–85CrossRef

Tagami T, Galbraith RF, Yamada R, Laslett GM (1998) Revised annealing kinetics of fission tracks in zircon and geological implications. In: van den Haute P, De Corte F (eds) Advances in fission-track geochronology. Kluwer, Dordrecht, The Netherlands, pp 99–112CrossRef

Tagami T, Hasebe N, Kamohara H, Takemura K (2001) Thermal anomaly around Nojima fault as detected by the fission-track analysis of Ogura 500 m borehole samples. Isl Arc 10:457–464CrossRef

Tagami T, Lal N, Sorkhabi RB, Nishimura S (1988) Fission track thermochronologic analysis of the Ryoke Belt and the Median Tectonic Line Southwest Japan. J Geophys Res 93:13705–13715CrossRef

Tagami T, Murakami M (2007) Probing fault zone heterogeneity on the Nojima fault: constraints from zircon fission-track analysis of borehole samples. Tectonophysics 443:139–152CrossRef

Tagami T, O’Sullivan PB (2005) Fundamentals of fission-track thermochronology. Rev Mineral Geochem 58:19–47CrossRef

Takagi H, Arita K, Danhara T, Iwano H (2007) Timing of the Tsergo Ri Landslide, Langtang Himal, determined by fission track age for pseudotachylite. J Asian Earth Sci 29:466–472CrossRef

Takagi H, Shimada K, Iwano H, Danhara T (2010) Oldest record of brittle deformation along the Median Tectonic Line: fission-track age for pseudotachylite in the Taki area, Mie Prefecture. J Geol Soc Japan 116:45–50CrossRef

Tanaka H, Chester FM, Mori JJ, Wang CY (2007) Drilling into fault zones. Tectonophysics 443:123–125CrossRef

van der Pluijm BA, Hall CM, Vrolijk PJ, Pevear DR, Covey MC (2001) The dating of shallow faults in the Earth’s crust. Nature 412:172–175CrossRef

van der Pluijm BA, Vrolijk PJ, Pevear DR, Hall CM, Solum J (2006) Fault dating in the Canadian Rocky Mountains: evidence for late Cretaceous and early Eocene orogenic pulses. Geology 34:837–840CrossRef

Verhaert G, Muchez P, Sintubin M, Similox-Tohon D, Vandycke S, Keppens E, Hodge EJ, Richards DA (2004) Origin of paleofluids in a normal fault setting in the Aegean region. Geofluids 4:300–314CrossRef

Viola G, Mancktelow NS, Seward D, Meier A, Martin S (2003) The Pejo fault system; an example of multiple tectonic activity in the Italian Eastern Alps. GSA Bull 115:515–532CrossRef

Warr LN, van der Pluijm BA, Peacor DR, Hall CM (2003) Frictional melt pulses during a ~1.1 Ma earthquake along the Alpine fault, New Zealand. Earth Planet Sci Lett 209:39–52CrossRef

Warren-Smith E, Lamb S, Seward D, Smith E, Herman F, Stern T (2016) Thermochronological evidence of a low-angle, mid-crustal detachment plane beneath the central South Island, New Zealand. Geochem Geophys Geosyst 17:4212–4235CrossRef

Watanabe Y, Nakai S, Lin A (2008) Attempt to determine U–Th ages of calcite veins in the Nojima fault zone, Japan. Geochem J 42:507–513CrossRef

Wolfler A, Kurz W, Danisik M, Rabitsch R (2010) Dating of fault zone activity by apatite fission track and apatite (U–Th)/He thermochronometry: a case study from the Lavanttal fault system (Eastern Alps). Terra Nova 22:274–282

Yamada K, Hanamuro T, Tagami T, Shimada K, Takagi H, Yamada R, Umeda K (2012) The first (U–Th)/He dating of a pseudotachlylyte collected from the Median Tectonic Line, southwest Japan. J Asian Earth Sci 45:17–23CrossRef

Yamada K, Tagami T, Shimobayashi N (2003) Experimental study on hydrothermal annealing of fission tracks in zircon. Chem Geol 201:351–357CrossRef

Yamada R, Murakami M, Tagami T (2007) Statistical modelling of annealing kinetics of fission tracks in zircon; reassessment of laboratory experiments. Chem Geol 236:75–91CrossRef

Yamada R, Tagami T, Nishimura S, Ito H (1995) Annealing kinetics of fission tracks in zircon: an experimental study. Chem Geol 122:249–258CrossRef

Zwingmann H, Mancktelow N (2004) Timing of Alpine fault gouges. Earth Planet Sci Lett 223:415–425CrossRef

Zwingmann H, Yamada K, Tagami T (2010a) Timing of brittle deformation within the Nojima fault zone, Japan. Chem Geol 275:176–185CrossRef

Zwingmann H, Mancktelow N, Antognini M, Lucchini R (2010b) Dating of shallow faults: new constraints from the AlpTransit tunnel site (Switzerland). Geology 38:487–490CrossRef

Title: Application of Fission-Track Thermochronology to Understand Fault Zones
Author: Takahiro Tagami
Publisher: Springer International Publishing
Book: Fission-Track Thermochronology and its Application to Geology
Print ISBN: 978-3-319-89419-5

Electronic ISBN: 978-3-319-89421-8

Copyright Year: 2019
DOI: https://doi.org/10.1007/978-3-319-89421-8_12