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2019 | OriginalPaper | Chapter

5. Integration of Fission-Track Thermochronology with Other Geochronologic Methods on Single Crystals

Author : Martin Danišík

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

Publisher: Springer International Publishing

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Abstract

Fission-track (FT) thermochronology can be integrated with the U–Pb and (U–Th)/He dating methods. All three radiometric dating methods can be applied to single crystals (hereafter referred to as “triple-dating”), allowing more complete and more precise thermal histories to be constrained from single grains. Such an approach is useful across a myriad of geological applications. Triple-dating has been successfully applied to zircon and apatite. However, other U-bearing minerals such as titanite and monazite, which are routinely dated by single methods, are also candidates for this approach. Several analytical procedures can be used to generate U–Pb—FT—(U–Th)/He age triples on single grains. The procedure introduced here combines FT dating by LA-ICPMS and in situ (U–Th)/He dating approach, whereby the U–Pb age is obtained as a by-product of U–Th analysis by LA-ICPMS. In this case, U–Pb, trace element and REE data can be collected simultaneously and used as annealing kinetics parameter or as provenance and petrogenetic indicators. This novel procedure avoids time-consuming irradiation in a nuclear reactor, reduces multiple sample handling steps and allows high sample throughput (predictably on the order of 100 triple-dated crystals in 2 weeks). These attributes and the increasing number of facilities capable of conducting triple-dating indicate that this approach may become more routine in the near future.

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Barbarand J, Carter A, Wood I, Hurford T (2003) Compositional and structural control of fission-track annealing in apatite. Chem Geol 198(1):107–137CrossRef

Belton D, Brown R, Kohn B, Fink D, Farley K (2004) Quantitative resolution of the debate over antiquity of the central Australian landscape: implications for the tectonic and geomorphic stability of cratonic interiors. Earth Planet Sci Lett 219(1):21–34CrossRef

Bernet M (2018) Chapter 15: Exhumation studies of mountain belts based on detrital fission-track analysis on sand and sandstones. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer

Bernet M, Spiegel C (2004) Introduction: detrital thermochronology. Geol S Am S 378:1–6

Bernet M, Garver JI (2005) Fission-track analysis of detrital zircon. Rev Mineral Geochem 58(1):205–237CrossRef

Bernet M, van der Beek P, Pik R, Huyghe P, Mugnier JL, Labrin E, Szulc A (2006) Miocene to recent exhumation of the central Himalaya determined from combined detrital zircon fission-track and U/Pb analysis of Siwalik sediments, western Nepal. Basin Res 18(4):393–412CrossRef

Boyce J, Hodges K, Olszewski W, Jercinovic M (2005) He diffusion in monazite: Implications for (U‐Th)/He thermochronometry. Geochem Geophys Geosys 6(12)CrossRef

Boyce J, Hodges K, Olszewski W, Jercinovic M, Carpenter B, Reiners PW (2006) Laser microprobe (U–Th)/He geochronology. Geochim Cosmochim Ac 70(12):3031–3039CrossRef

Boyce J, Hodges K, King D, Crowley JL, Jercinovic M, Chatterjee N, Bowring S, Searle M (2009) Improved confidence in (U‐Th)/He thermochronology using the laser microprobe: an example from a Pleistocene leucogranite, Nanga Parbat, Pakistan. Geochem Geophys Geosys 10(9)CrossRef

Brandon MT, Roden-Tice MK, Garver JI (1998) Late Cenozoic exhumation of the Cascadia accretionary wedge in the Olympic Mountains, northwest Washington State. Geol Soc Am Bull 110(8):985–1009CrossRef

Burtner RL, Nigrini A, Donelick RA (1994) Thermochronology of Lower Cretaceous source rocks in the Idaho-Wyoming thrust belt. AAPG Bull 78(10):1613–1636

Campbell IH, Reiners PW, Allen CM, Nicolescu S, Upadhyay R (2005) He–Pb double dating of detrital zircons from the Ganges and Indus Rivers: implication for quantifying sediment recycling and provenance studies. Earth Planet Sci Lett 237(3):402–432CrossRef

Carrapa B (2010) Resolving tectonic problems by dating detrital minerals. Geology 38(2):191–192CrossRef

Carrapa B, DeCelles PG, Reiners PW, Gehrels GE, Sudo M (2009) Apatite triple dating and white mica ⁴⁰Ar/³⁹Ar thermochronology of syntectonic detritus in the Central Andes: a multiphase tectonothermal history. Geology 37(5):407–410CrossRef

Carter A (2018) Chapter 14: Thermochronology on sand and sandstones for stratigraphic and provenance studies. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer

Carter A, Moss SJ (1999) Combined detrital-zircon fission-track and U–Pb dating: a new approach to understanding hinterland evolution. Geology 27(3):235–238CrossRef

Carter A, Bristow C (2000) Detrital zircon geochronology: enhancing the quality of sedimentary source information through improved methodology and combined U–Pb and fission-track techniques. Basin Res 12(1):47–57CrossRef

Carter A, Bristow C (2003) Linking hinterland evolution and continental basin sedimentation by using detrital zircon thermochronology: a study of the Khorat Plateau Basin, eastern Thailand. Basin Res 15(2):271–285CrossRef

Chamberlain KR, Bowring SA (2001) Apatite–feldspar U–Pb thermochronometer: a reliable, mid-range (∼450 °C), diffusion-controlled system. Chem Geol 172(1):173–200CrossRef

Cherniak D (1993) Lead diffusion in titanite and preliminary results on the effects of radiation damage on Pb transport. Chem Geol 110(1–3):177–194CrossRef

Cherniak DJ (2010) Diffusion in accessory minerals: zircon, titanite, apatite, monazite and xenotime. Rev Mineral Geochem 72(1):827–869CrossRef

Cherniak D, Watson E (2001) Pb diffusion in zircon. Chem Geol 172(1):5–24CrossRef

Cherniak DJ, Watson EB (2003) Diffusion in zircon. Rev Mineral Geochem 53(1):113–143CrossRef

Cherniak D, Lanford W, Ryerson F (1991) Lead diffusion in apatite and zircon using ion implantation and Rutherford backscattering techniques. Geochim Cosmochim Ac 55(6):1663–1673CrossRef

Cherniak D, Watson EB, Grove M, Harrison TM (2004) Pb diffusion in monazite: a combined RBS/SIMS study. Geochim Cosmochim Ac 68(4):829–840CrossRef

Chew DM, Donelick RA (2012) Combined apatite fission track and U–Pb dating by LA-ICP-MS and its application in apatite provenance analysis. Quant Miner Microanal Sediments Sed Rocks: Minerall Ass Can Short Course 42:219–247

Chew DM, Sylvester PJ, Tubrett MN (2011) U–Pb and Th-Pb dating of apatite by LA-ICPMS. Chem Geol 280(1):200–216CrossRef

Cochrane R, Spikings RA, Chew D, Wotzlaw J-F, Chiaradia M, Tyrrell S, Schaltegger U, Van der Lelij R (2014) High temperature (>350 °C) thermochronology and mechanisms of Pb loss in apatite. Geochim Cosmochim Ac 127:39–56CrossRef

Cox R, Košler J, Sylvester P, Hodych J Apatite fission-track (FT) dating by LAM-ICP-MS analysis. J Conf Abstr, 2000. p 322

Coyle D, Wagner G (1998) Positioning the titanite fission-track partial annealing zone. Chem Geol 149(1):117–125CrossRef

Danišík M, Kuhlemann J, Dunkl I, Székely B, Frisch W (2007) Burial and exhumation of Corsica (France) in the light of fission track data. Tectonics 26(1)CrossRef

Danišík M, Sachsenhofer RF, Privalov VA, Panova EA, Frisch W, Spiegel C (2008) Low-temperature thermal evolution of the Azov Massif (Ukrainian Shield—Ukraine)—Implications for interpreting (U–Th)/He and fission track ages from cratons. Tectonophysics 456(3):171–179CrossRef

Danišík M, Pfaff K, Evans NJ, Manoloukos C, Staude S, McDonald BJ, Markl G (2010a) Tectonothermal history of the Schwarzwald ore district (Germany): an apatite triple dating approach. Chem Geol 278(1):58–69CrossRef

Danišík M, Sachsenhofer R, Frisch W, Privalov V, Panova E, Spiegel C (2010b) Thermotectonic evolution of the Ukrainian Donbas Foldbelt revisited: new constraints from zircon and apatite fission track data. Basin Res 22(5):681–698CrossRef

Danišík M, Kuhlemann J, Dunkl I, Evans NJ, Székely B, Frisch W (2012) Survival of ancient landforms in a collisional setting as revealed by combined fission track and (U–Th)/He thermochronometry: a case study from Corsica (France). J Geol 120(2):155–173CrossRef

Danišík M, Fodor L, Dunkl I, Gerdes A, Csizmeg J, Hámor-Vidó M, Evans NJ (2015) A multi-system geochronology in the Ad-3 borehole, Pannonian Basin (Hungary) with implications for dating volcanic rocks by low-temperature thermochronology and for interpretation of (U–Th)/He data. Terra Nova 27(4):258–269CrossRef

Danišík M, McInnes BI, Kirkland CL, McDonald BJ, Evans NJ, Becker T (2017) Seeing is believing: visualization of He distribution in zircon and implications for thermal history reconstruction on single crystals. Science Advances 3(2):e1601121CrossRef

Djimbi DM, Gautheron C, Roques J, Tassan-Got L, Gerin C, Simoni E (2015) Impact of apatite chemical composition on (U–Th)/He thermochronometry: An atomistic point of view. Geochim Cosmochim Ac 167:162–176CrossRef

Dodson MH (1973) Closure temperature in cooling geochronological and petrological systems. Contrib Mineral Petr 40(3):259–274CrossRef

Donelick RA, Miller DS (1991) Enhanced TINT fission track densities in low spontaneous track density apatites using ²⁵²Cf-derived fission fragment tracks: a model and experimental observations. Int J Rad Appl Instr Part D Nuclear Tracks Rad Meas 18(3):301–307CrossRef

Donelick RA, Ketcham RA, Carlson WD (1999) Variability of apatite fission-track annealing kinetics: II. Crystallographic orientation effects. Am Mineral 84(9):1224–1234CrossRef

Donelick RA, O’Sullivan PB, Ketcham RA (2005) Apatite fission-track analysis. Rev Mineral Geochem 58(1):49–94CrossRef

Donelick R, O’Sullivan P, Ketcham R, Hendriks B, Redfield T (2006) Relative U and Th concentrations from LA-ICP-MS for apatite fission-track grain-age dating. Geochim Cosmochim Ac 70(18):A143CrossRef

Ehlers TA, Farley KA (2003) Apatite (U–Th)/He thermochronometry: methods and applications to problems in tectonic and surface processes. Earth Planet Sci Lett 206(1):1–14CrossRef

Emmel B, Jacobs J, Crowhurst P, Daszinnies M (2007) Combined apatite fission-track and single grain apatite (U–Th)/He ages from basement rocks of central Dronning Maud Land (East Antarctica)—Possible identification of thermally overprinted crustal segments? Earth Planet Sci Lett 264(1):72–88CrossRef

Enkelmann E, Jonckheere R, Wauschkuhn B (2005) Independent fission-track ages (ϕ-ages) of proposed and accepted apatite age standards and a comparison of ϕ-, Z-, ζ-and ζ 0-ages: implications for method calibration. Chem Geol 222(3):232–248CrossRef

Evans NJ, McInnes BI, McDonald B, Danišík M, Jourdan F, Mayers C, Thern E, Corbett D (2013) Emplacement age and thermal footprint of the diamondiferous Ellendale E9 lamproite pipe, Western Australia. Mineralium Deposita 48(3):413–421CrossRef

Evans N, McInnes B, McDonald B, Danišík M, Becker T, Vermeesch P, Shelley M, Marillo-Sialer E, Patterson D (2015) An in situ technique for (U–Th–Sm)/He and U–Pb double dating. J Analyt Atom Spect 30(7):1636–1645CrossRef

Farley K (2000) Helium diffusion from apatite: general behavior as illustrated by Durango fluorapatite. J Geophys Res B 105(B2):2903–2914CrossRef

Farley KA (2002) (U–Th)/He dating: Techniques, calibrations, and applications. Rev Mineral Geochem 47(1):819–844CrossRef

Farley K, Wolf R, Silver L (1996) The effects of long alpha-stopping distances on (U–Th)/He ages. Geochim Cosmochim Ac 60(21):4223–4229CrossRef

Fayon A (2011) Fission track dating of monazite: etching efficiencies as a function of U content. Paper presented at GSA Annual Meeting in Minneapolis, 9–12 October 2011

Fitzgerald P, Baldwin SL, Webb L, O’Sullivan PB (2006) Interpretation of (U–Th)/He single grain ages from slowly cooled crustal terranes: a case study from the Transantarctic Mountains of southern Victoria Land. Chem Geol 225(1):91–120CrossRef

Fleischer RL, Price PB, Walker RM (1975) Nuclear tracks in solids: principles and applications. University of California Press

Flowerdew M, Millar IL, Curtis ML, Vaughan A, Horstwood M, Whitehouse MJ, Fanning CM (2007) Combined U–Pb geochronology and Hf isotope geochemistry of detrital zircons from early Paleozoic sedimentary rocks, Ellsworth-Whitmore Mountains block, Antarctica. Geol Soc Am Bull 119(3–4):275–288CrossRef

Flowers RM (2009) Exploiting radiation damage control on apatite (U–Th)/He dates in cratonic regions. Earth Planet Sci Lett 277(1):148–155CrossRef

Flowers R, Farley K (2012) Apatite ⁴He/³He and (U–Th)/He evidence for an ancient Grand Canyon. Science 338(6114):1616–1619CrossRef

Flowers R, Farley K (2013) Response to Comments on “Apatite ⁴He/³He and (U–Th)/He evidence for an ancient Grand Canyon”. Science 340(6129):143CrossRef

Flowers RM, Kelley SA (2011) Interpreting data dispersion and “inverted” dates in apatite (U–Th)/He and fission-track datasets: an example from the US midcontinent. Geochim Cosmochim Ac 75(18):5169–5186CrossRef

Flowers R, Shuster D, Wernicke B, Farley K (2007) Radiation damage control on apatite (U–Th)/He dates from the Grand Canyon region, Colorado Plateau. Geology 35(5):447–450CrossRef

Flowers RM, Ketcham RA, Shuster DL, Farley KA (2009) Apatite (U–Th)/He thermochronometry using a radiation damage accumulation and annealing model. Geochim Cosmochim Ac 73(8):2347–2365CrossRef

Flowers RM, Farley KA, Ketcham RA (2015) A reporting protocol for thermochronologic modeling illustrated with data from the Grand Canyon. Earth Planet Sci Lett 432:425–435CrossRef

Flowers RM, Farley KA, Ketcham RA (2016) Response to comment on “A reporting protocol for thermochronologic modeling illustrated with data from the Grand Canyon”. Earth Planet Sci Lett 441:213CrossRef

Fox M, Shuster DL (2014) The influence of burial heating on the (U–Th)/He system in apatite: Grand Canyon case study. Earth Planet Sci Lett 397:174–183CrossRef

Galbraith R, Laslett G (1993) Statistical models for mixed fission track ages. Nuclear Tracks Rad Meas 21(4):459–470CrossRef

Gallagher K (2012) Transdimensional inverse thermal history modeling for quantitative thermochronology. J Geophys Res: Sol Ea 117 (B2)CrossRef

Gallagher K (2016) Comment on “A reporting protocol for thermochronologic modeling illustrated with data from the Grand Canyon” by Flowers, Farley and Ketcham. Earth Planet Sci Lett 441:211–212CrossRef

Gallagher K, Brown R, Johnson C (1998) Fission track analysis and its applications to geological problems. Ann Rev Earth Planet Sci 26(1):519–572CrossRef

Gardés E, Jaoul O, Montel J-M, Seydoux-Guillaume A-M, Wirth R (2006) Pb diffusion in monazite: an experimental study of Pb²⁺ + Th⁴⁺ ⇔ 2Nd³⁺ interdiffusion. Geochim Cosmochim Ac 70(9):2325–2336CrossRef

Garver JI (2003) Etching zircon age standards for fission-track analysis. Rad Meas 37(1):47–53CrossRef

Garver JI, Kamp PJ (2002) Integration of zircon color and zircon fission-track zonation patterns in orogenic belts: application to the Southern Alps. New Zealand. Tectonophysics 349(1):203–219CrossRef

Gautheron C, Tassan-Got L (2010) A Monte Carlo approach to diffusion applied to noble gas/helium thermochronology. Chem Geol 273(3):212–224CrossRef

Gleadow A (1981) Fission-track dating methods: what are the real alternatives? Nuclear Tracks 5(1–2):3–14CrossRef

Gleadow A, Fitzgerald P (1987) Uplift history and structure of the Transantarctic Mountains: new evidence from fission track dating of basement apatites in the Dry Valleys area, southern Victoria Land. Earth Planet Sci Lett 82(1–2):1–14CrossRef

Gleadow A, Lovering J (1974) The effect of weathering on fission track dating. Earth Planet Sci Lett 22(2):163–168CrossRef

Gleadow A, Duddy I, Lovering J (1983) Fission track analysis: a new tool for the evaluation of thermal histories and hydrocarbon potential. Austr Petrol Expl Ass J 23:93–102

Gleadow A, Duddy I, Green PF, Lovering J (1986a) Confined fission track lengths in apatite: a diagnostic tool for thermal history analysis. Contrib Mineral Petr 94(4):405–415CrossRef

Gleadow AJ, Duddy IR, Green PF, Hegarty KA (1986b) Fission track lengths in the apatite annealing zone and the interpretation of mixed ages. Earth Planet Sci Lett 78(2–3):245–254CrossRef

Gleadow AJ, Gleadow SJ, Belton DX, Kohn BP, Krochmal MS, Brown RW (2009) Coincidence mapping-a key strategy for the automatic counting of fission tracks in natural minerals. Geol Soc Spec Publ 324(1):25–36CrossRef

Gleadow AJ, Kohn BP, Lugo-Zazueta R, Alimanovic A (2012) The use of coupled image analysis and laser-ablation ICP-MS in fission track thermochronology. In: Goldschmidt Conference Abstracts 1765, Montreal, 24–29 June, 2012

Gleadow AJ, Kohn B, Seiler C (2018) Chapter 4: the future of fission-track thermochronology. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer

Green P, Duddy I (2006) Interpretation of apatite (U–Th)/He ages and fission track ages from cratons. Earth Planet Sci Lett 244(3):541–547CrossRef

Green P, Duddy I, Laslett G, Hegarty K, Gleadow AW, Lovering J (1989a) Thermal annealing of fission tracks in apatite 4. Quantitative modelling techniques and extension to geological timescales. Chem Geol: Isotope Geosc Sect 79(2):155–182

Green PF, Duddy IR, Gleadow AJ, Lovering JF (1989b) Apatite fission-track analysis as a paleotemperature indicator for hydrocarbon exploration. In: Thermal history of sedimentary basins. Springer, pp 181–195CrossRef

Green PF, Crowhurst PV, Duddy IR, Japsen P, Holford SP (2006) Conflicting (U–Th)/He and fission track ages in apatite: enhanced He retention, not anomalous annealing behaviour. Earth Planet Sci Lett 250(3):407–427CrossRef

Guenthner WR, Reiners PW, Ketcham RA, Nasdala L, Giester G (2013) Helium diffusion in natural zircon: Radiation damage, anisotropy, and the interpretation of zircon (U–Th)/He thermochronology. Am J Sci 313(3):145–198CrossRef

Hanchar JM, Hoskin PW (2003) Zircon–reviews in mineralogy and geochemistry, vol 53. Mineralogical society of America/geochemical society, p 500

Hansen K, Reiners PW (2006) Low temperature thermochronology of the southern East Greenland continental margin: evidence from apatite (U–Th)/He and fission track analysis and implications for intermethod calibration. Lithos 92(1):117–136CrossRef

Hasebe N, Barbarand J, Jarvis K, Carter A, Hurford AJ (2004) Apatite fission-track chronometry using laser ablation ICP-MS. Chem Geol 207(3):135–145CrossRef

Hawkins DP, Bowring SA (1999) U–Pb monazite, xenotime and titanite geochronological constraints on the prograde to post-peak metamorphic thermal history of Paleoproterozoic migmatites from the Grand Canyon, Arizona. Contrib Mineral Petr 134(2):150–169CrossRef

Hendriks BWH (2003) Cooling and Denudation of the Norwegian and Barents Sea Margins, Northern Scandinavia: Constrained by Apatite Fission Track and (U–Th) He Thermochronology. Vrije universiteit

Hendriks B, Redfield T (2005) Apatite fission track and (U–Th)/He data from Fennoscandia: an example of underestimation of fission track annealing in apatite. Earth Planet Sci Lett 236(1):443–458CrossRef

Hendriks BWH, Redfield TF (2006) Reply to: comment on “Apatite fission track and (U–Th)/He data from Fennoscandia: an example of underestimation of fission track annealing in apatite” by BWH hendriks and TF redfield. Earth Planet Sci Lett 248(1–2):569–577

Horne AM, van Soest MC, Hodges KV, Tripathy-Lang A, Hourigan JK (2016) Integrated single crystal laser ablation U/Pb and (U–Th)/He dating of detrital accessory minerals–Proof-of-concept studies of titanites and zircons from the Fish Canyon tuff. Geochim Cosmochim Ac 178:106–123CrossRef

Hourigan JK, Reiners PW, Brandon MT (2005) U–Th zonation-dependent alpha-ejection in (U–Th)/He chronometry. Geochim Cosmochim Ac 69(13):3349–3365CrossRef

House M, Kohn B, Farley K, Raza A (2002) Evaluating thermal history models for the Otway Basin, southeastern Australia, using (U–Th)/He and fission-track data from borehole apatites. Tectonophysics 349(1):277–295CrossRef

Hurford AJ (1986) Cooling and uplift patterns in the Lepontine Alps South Central Switzerland and an age of vertical movement on the Insubric fault line. Contrib Mineral Petr 92(4):413–427CrossRef

Hurford AJ (2018) Chapter 1: an historical perspective on fission-track thermochronology. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer

Hurley PM (1952) Alpha ionization damage as a cause of low helium ratios. Eos, Trans Am Geophys Union 33(2):174–183CrossRef

Jennings E, Marschall H, Hawkesworth C, Storey C (2011) Characterization of magma from inclusions in zircon: apatite and biotite work well, feldspar less so. Geology 39(9):863–866CrossRef

Jolivet M, Dempster T, Cox R (2003) Distribution of U and Th in apatites: implications for U–Th/He thermo chronology. CR Geosci, 899–906

Jonckheere R, Ratschbacher L (2015) Standardless fission-track dating of the Durango apatite age standard. Chem Geol 417:44–57CrossRef

Karlstrom KE, Lee J, Kelley S, Crow R, Young RA, Lucchitta I, Beard LS, Dorsey R, Ricketts JW, Dickinson WR, Crossey L (2013) Comment on “Apatite ⁴He/³He and (U-Th)/He evidence for an ancient grand canyon”. Science 340(6129):143. http://dx.doi.org/10.1126/science.1233982CrossRef

Ketcham RA (2005) Forward and inverse modeling of low-temperature thermochronometry data. Rev Mineral Geochem 58(1):275–314CrossRef

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

Ketcham RA, Donelick RA, Carlson WD (1999) Variability of apatite fission-track annealing kinetics: III. Extrapolation to geological time scales. Am Mineral 84(9):1235–1255CrossRef

Ketcham RA, Carter A, Donelick RA, Barbarand J, Hurford AJ (2007a) Improved measurement of fission-track annealing in apatite using c-axis projection. Am Mineral 92(5–6):789–798CrossRef

Ketcham RA, Carter A, Donelick RA, Barbarand J, Hurford AJ (2007b) Improved modeling of fission-track annealing in apatite. Am Mineral 92(5–6):799–810CrossRef

Ketcham RA, Donelick RA, Balestrieri ML, Zattin M (2009) Reproducibility of apatite fission-track length data and thermal history reconstruction. Earth Planet Sci Lett 284(3):504–515CrossRef

Ketcham RA, Guenthner WR, Reiners PW (2013) Geometric analysis of radiation damage connectivity in zircon, and its implications for helium diffusion. Am Mineral 98(2–3):350–360CrossRef

Kinny PD, Maas R (2003) Lu–Hf and Sm–Nd isotope systems in zircon. Rev Mineral Geochem 53(1):327–341CrossRef

Kirkland C, Erickson T, Johnson T, Danišík M, Evans N, Bourdet J, McDonald B (2016a) Discriminating prolonged, episodic or disturbed monazite age spectra: An example from the Kalak Nappe Complex, Arctic Norway. Chem Geol 424:96–110CrossRef

Kirkland C, Spaggiari C, Johnson T, Smithies R, Danišík M, Evans N, Wingate M, Clark C, Spencer C, Mikucki E (2016b) Grain size matters: implications for element and isotopic mobility in titanite. Precambrian Res 278:283–302CrossRef

Kohn BP, Gleadow A (2018) Chapter 21: application of low-temperature thermochronology to craton evolution. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer

Kohn BP, Green PF (2002) Low temperature thermochronology: from tectonics to landscape evolution. ElsevierCrossRef

Kohn BP, Lorencak M, Gleadow AJ, Kohlmann F, Raza A, Osadetz KG, Sorjonen-Ward P (2009) A reappraisal of low-temperature thermochronology of the eastern Fennoscandia Shield and radiation-enhanced apatite fission-track annealing. Geol Soc Spec Publ 324(1):193–216CrossRef

Kohn BP, Chung L, Gleadow A (2018) Chapter 2: fission-track analysis: field collection, sample preparation and data acquisition. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer

Košler J, Sylvester PJ (2003) Present trends and the future of zircon in geochronology: laser ablation ICPMS. Rev Mineral Geochem 53(1):243–275CrossRef

Krogh T (1982) Improved accuracy of U–Pb zircon ages by the creation of more concordant systems using an air abrasion technique. Geochim Cosmochim Ac 46(4):637–649CrossRef

Ksienzyk AK, Dunkl I, Jacobs J, Fossen H, Kohlmann F (2014) From orogen to passive margin: constraints from fission track and (U–Th)/He analyses on Mesozoic uplift and fault reactivation in SW Norway. Geol Soc Spec Publ 390(SP390):327

Lee J, Stockli D, Kelley S, Pederson J, Karlstrom K, Ehlers T (2013) New thermochronometric constraints on the Tertiary landscape evolution of the central and eastern Grand Canyon, Arizona. Geosphere 9(2):216–228CrossRef

Lisker F, Ventura B, Glasmacher U (2009) Apatite thermochronology in modern geology. Geol Soc Spec Publ 324(1):1–23CrossRef

Liu W, Zhang J, Sun T, Wang J (2014) Application of apatite U–Pb and fission-track double dating to determine the preservation potential of magnetite–apatite deposits in the Luzong and Ningwu volcanic basins, eastern China. J Geochem Expl 138:22–32CrossRef

Lorencak M (2003) Low temperature thermochronology of the Canadian and Fennoscandian Shields: Integration of apatite fission track and (U–Th)/He methods. University of Melbourne, School of Earth Sciences

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

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

Malusà MG, Garzanti E (2018) Chapter 7: the sedimentology of detrital thermochronology. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer

Malusà MG, Danišík M, Kuhlemann J (2016) Tracking the Adriatic-slab travel beneath the Tethyan margin of Corsica-Sardinia by low-temperature thermochronometry. Gondwana Res 31:135–149CrossRef

Malusà MG, Wang J, Garzanti E, Liu ZC, Villa IM, Wittmann H (2017) Trace-element and Nd-isotope systematics in detrital apatite of the Po river catchment: implications for prove-nance discrimination and the lag-time approach to detrital thermochronology. Lithos 290–291:48–59CrossRef

McDowell FW, McIntosh WC, Farley KA (2005) A precise ⁴⁰Ar–³⁹Ar reference age for the Durango apatite (U–Th)/He and fission-track dating standard. Chem Geol 214(3):249–263CrossRef

McInnes BI, Evans NJ, Fu FQ, Garwin S (2005) Application of thermochronology to hydrothermal ore deposits. Rev Mineral Geochem 58(1):467–498CrossRef

McInnes BI, Evans NJ, McDonald BJ, Kinny PD, Jakimowicz J (2009) Zircon U–Th-Pb-He double dating of the Merlin kimberlite field, Northern Territory, Australia. Lithos 112:592–599CrossRef

Meesters A, Dunai T (2002a) Solving the production-diffusion equation for finite diffusion domains of the various shapes, part 1; implications for low temperature (U–Th)/He thermochronology

Meesters A, Dunai T (2002b) Solving the production-diffusion equation for finite diffusion domains of various shapes: Part II. Application to cases with α-ejection and nonhomogeneous distribution of the source. Chem Geol 186(3):347–363CrossRef

Moore TE, O’Sullivan PB, Potter CJ, Donelick RA (2015) Provenance and detrital zircon geochronologic evolution of lower Brookian foreland basin deposits of the western Brooks Range, Alaska, and implications for early Brookian tectonism. Geosphere 11(1):93–122CrossRef

Morton A, Yaxley G (2007) Detrital apatite geochemistry and its application in provenance studies. Geol S Am S 420:319–344

Parrish RR, Noble SR (2003) Zircon U–Th-Pb geochronology by isotope dilution—thermal ionization mass spectrometry (ID-TIMS). Rev Mineral Geochem 53(1):183–213CrossRef

Price P, Walker R (1963) Fossil tracks of charged particles in mica and the age of minerals. J Geophys Res 68(16):4847–4862CrossRef

Rahl JM, Reiners PW, Campbell IH, Nicolescu S, Allen CM (2003) Combined single-grain (U–Th)/He and U/Pb dating of detrital zircons from the Navajo Sandstone. Utah Geol 31(9):761–764CrossRef

Rahn MK, Brandon MT, Batt GE, Garver JI (2004) A zero-damage model for fission-track annealing in zircon. Am Mineral 89(4):473–484CrossRef

Reiners PW (2004) Thermochronology of wildfire and fault heating through single-grain (U–Th)/He and fission-track double-dating. In: Conference Abstracts of the GSA Annual Meeting, Denver, 7–10, 2004

Reiners PW (2005) Zircon (U–Th)/He thermochronometry. Rev Mineral Geochem 58(1):151–179CrossRef

Reiners PW, Ehlers TA (2005) Low-temperature thermochronology: techniques, interpretations, and applications; Ed.: PW Reiners, TA Ehlers. Miner Soc Am. Washington

Reiners PW, Farley KA (1999) Helium diffusion and (U–Th)/He thermochronometry of titanite. Geochim Cosmochim Ac 63(22):3845–3859CrossRef

Reiners PW, Farley KA (2001) Influence of crystal size on apatite (U–Th)/He thermochronology: an example from the Bighorn Mountains, Wyoming. Earth Planet Sci Lett 188(3):413–420CrossRef

Reiners P, Campbell I, Nicolescu S, Allen C, Garver J, Hourigan J, Cowan D (2004) Double-and triple-dating of single detrital zircons with (U–Th)/He, fission-track, and U/Pb systems, and examples from modern and ancient sediments of the western US. In: AGU Fall Meeting Abstracts, 2004

Reiners PW, Spell TL, Nicolescu S, Zanetti KA (2004b) Zircon (U–Th)/He thermochronometry: He diffusion and comparisons with ⁴⁰Ar/³⁹Ar dating. Geochim Cosmochim Ac 68(8):1857–1887CrossRef

Reiners PW, Campbell I, Nicolescu S, Allen CM, Hourigan J, Garver J, Mattinson J, Cowan D (2005) (U–Th)/(He-Pb) double dating of detrital zircons. Am J Sci 305(4):259–311CrossRef

Schaltegger U, Schmitt A, Horstwood M (2015) U–Th–Pb zircon geochronology by ID-TIMS, SIMS, and laser ablation ICP-MS: recipes, interpretations, and opportunities. Chem Geol 402:89–110CrossRef

Schoene B, Latkoczy C, Schaltegger U, Günther D (2010) A new method integrating high-precision U–Pb geochronology with zircon trace element analysis (U–Pb TIMS-TEA). Geochim Cosmochim Ac 74(24):7144–7159CrossRef

Shen C-B, Donelick RA, O’Sullivan PB, Jonckheere R, Yang Z, She Z-B, Miu X-L, Ge X (2012) Provenance and hinterland exhumation from LA-ICP-MS zircon U–Pb and fission-track double dating of Cretaceous sediments in the Jianghan Basin, Yangtze block, central China. Sed Geol 281:194–207CrossRef

Shuster DL, Farley KA (2009) The influence of artificial radiation damage and thermal annealing on helium diffusion kinetics in apatite. Geochim Cosmochim Ac 73(1):183–196CrossRef

Shuster D, Flowers R, Farley K (2006) Radiation damage and helium diffusion kinetics in apatite. Geochim Cosmochim Ac 70(18):A590CrossRef

Siebel W, Danišík M, Chen F (2009) From emplacement to unroofing: thermal history of the Jiazishan gabbro, Sulu UHP terrane, China. Mineral Petrol 96(3–4):163–175CrossRef

Söderlund P, Juez-Larré J, Page LM, Dunai TJ (2005) Extending the time range of apatite (U–Th)/He thermochronometry in slowly cooled terranes: Palaeozoic to Cenozoic exhumation history of southeast Sweden. Earth Planet Sci Lett 239(3):266–275CrossRef

Jt Stacey, Kramers J (1975) Approximation of terrestrial lead isotope evolution by a two-stage model. Earth Planet Sci Lett 26(2):207–221CrossRef

Stockli DF (2005) Application of low-temperature thermochronometry to extensional tectonic settings. Rev Mineral Geochem 58(1):411–448CrossRef

Stockli DF, Farley KA (2004) Empirical constraints on the titanite (U–Th)/He partial retention zone from the KTB drill hole. Chem Geol 207(3):223–236CrossRef

Stockli DF, Farley KA, Dumitru TA (2000) Calibration of the apatite (U–Th)/He thermochronometer on an exhumed fault block, White Mountains. Calif Geol 28(11):983–986CrossRef

Svojtka M, Košler J (2002) Fission-track dating of zircon by laser ablation ICPMS. In: Conference Abstracts of the Goldchmidt Conference, Geochim Cosmochim Ac, 2002. vol 15 A, pp A756–A756, Davos, 18–23 August, 2002

Tagami T (2005) Zircon fission-track thermochronology and applications to fault studies. Rev Mineral Geochem 58(1):95–122CrossRef

Thomson SN, Gehrels GE, Ruiz J, Buchwaldt R (2012) Routine low‐damage apatite U‐Pb dating using laser ablation–multicollector–ICPMS. Geochem Geophys Geosys 13(2)CrossRef

Tripathy-Lang A, Hodges KV, Monteleone BD, Soest MC (2013) Laser (U–Th)/He thermochronology of detrital zircons as a tool for studying surface processes in modern catchments. J Geophys Res: Earth 118(3):1333–1341CrossRef

van Soest MC, Hodges KV, Wartho JA, Biren MB, Monteleone BD, Ramezani J, Spray JG, Thompson LM (2011) (U‐Th)/He dating of terrestrial impact structures: the Manicouagan example. Geochem Geophys Geosys 12(5)

Vermeesch P (2004) How many grains are needed for a provenance study? Earth Planet Sci Lett 224(3):441–451CrossRef

Vermeesch P (2018) Chapter 6: statistics for fission-track thermochronology. In: Malusà MG, Fitzgerald PG (eds) Fission-track thermochronology and its application to geology. Springer

Vermeesch P, Miller DD, Graham SA, De Grave J, McWilliams MO (2006) Multimethod detrital thermochronology of the Great Valley Group near New Idria, California. Geol Soc Am Bull 118(1–2):210–218CrossRef

Vermeesch P, Sherlock SC, Roberts NM, Carter A (2012) A simple method for in-situ U–Th–He dating. Geochim Cosmochim Ac 79:140–147CrossRef

Wagner G, Reimer G (1972) Fission track tectonics: the tectonic interpretation of fission track apatite ages. Earth Planet Sci Lett 14(2):263–268CrossRef

Wagner G, van den Haute P (1992) Fission-track dating. Enke, Stuttgart, p 285CrossRef

Weise C, van den Boogaart KG, Jonckheere R, Ratschbacher L (2009) Annealing kinetics of Kr-tracks in monazite: implications for fission-track modelling. Chem Geol 260(1):129–137CrossRef

Weisheit A, Bons P, Danišík M, Elburg M (2014) Crustal-scale folding: Palaeozoic deformation of the Mt Painter Inlier, South Australia. Geol Soc Spec Publ 394(1):53–77CrossRef

Zattin M, Balestrieri ML, Hasebe N, Ketcham R, Seward D, Sobel E, Spiegel C (2008) Notes from the first workshop of the IGCP 543-low temperature thermochronology: applications and interlaboratory calibration. Episodes 31(3):356–357

Zattin M, Andreucci B, Thomson SN, Reiners PW, Talarico FM (2012) New constraints on the provenance of the ANDRILL AND‐2A succession (western Ross Sea, Antarctica) from apatite triple dating. Geochem Geophys Geosys 13(10)CrossRef

Zaun P, Wagner G (1985) Fission-track stability in zircons under geological conditions. Nucl Tracks Rad Meas 10(3):303–307

Zeitler P, Herczeg A, McDougall I, Honda M (1987) U–Th-He dating of apatite: a potential thermochronometer. Geochim Cosmochim Ac 51(10):2865–2868CrossRef

Title: Integration of Fission-Track Thermochronology with Other Geochronologic Methods on Single Crystals
Author: Martin Danišík
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_5