Data Reduction of Laser Ablation Split‐Stream (LASS) Analyses Using Newly Developed Features Within Iolite: With Applications to Lu‐Hf + U‐Pb in Detrital Zircon and Sm‐Nd +U‐Pb in Igneous Monazite
暂无分享,去创建一个
C. Fisher | D. Pearson | Yan Luo | T. Chacko | C. Sarkar | C. Paton | Daniel B. Tersmette
[1] J. Vervoort,et al. Combining Nd isotopes in monazite and Hf isotopes in zircon to understand complex open-system processes in granitic magmas , 2017 .
[2] Shan Gao,et al. Tracing crustal evolution by U-Th-Pb, Sm-Nd, and Lu-Hf isotopes in detrital monazite and zircon from modern rivers , 2017 .
[3] A. Kylander‐Clark. Petrochronology by Laser-Ablation Inductively Coupled Plasma Mass Spectrometry , 2017 .
[4] J. Vervoort,et al. Clarifying the zircon Hf isotope record of crust–mantle evolution , 2016 .
[5] Y. Hu,et al. MKED1: A new titanite standard for in situ analysis of Sm–Nd isotopes and U–Pb geochronology , 2016 .
[6] G. Gehrels,et al. Unraveling crustal growth and reworking processes in complex zircons from orogenic lower-crust: The Proterozoic Putumayo Orogen of Amazonia , 2015 .
[7] Chao Huang,et al. Sr and Nd isotopic compositions of apatite reference materials used in U-Th-Pb geochronology , 2014 .
[8] J. Blichert‐Toft,et al. Implications of discordant U–Pb ages on Hf isotope studies of detrital zircons , 2014 .
[9] J. Crowley,et al. Simultaneous in situ determination of U‐Pb and Sm‐Nd isotopes in monazite by laser ablation ICP‐MS , 2014 .
[10] J. Vervoort,et al. Guidelines for reporting zircon Hf isotopic data by LA-MC-ICPMS and potential pitfalls in the interpretation of these data , 2014 .
[11] C. Fisher,et al. Accurate Hf isotope determinations of complex zircons using the “laser ablation split stream” method , 2014 .
[12] J. Cottle,et al. Laser-ablation split-stream ICP petrochronology , 2013 .
[13] R. Ickert. Algorithms for estimating uncertainties in initial radiogenic isotope ratios and model ages , 2013 .
[14] M. Mihalynuk,et al. Baltican crustal provenance for Cambrian–Ordovician sandstones of the Alexander terrane, North American Cordillera: evidence from detrital zircon U–Pb geochronology and Hf isotope geochemistry , 2013, Journal of the Geological Society.
[15] Yue-heng Yang,et al. Neodymium isotopic compositions of the standard monazites used in U\Th\Pb geochronology , 2012 .
[16] Daniel B. Tersmette. Geology, geochronology, thermobarometry, and tectonic evolution of the Queen Maud block, Churchill craton, Nunavut, Canada , 2012 .
[17] J. Hellstrom,et al. CellSpace: A module for creating spatially registered laser ablation images within the Iolite freeware environment , 2012 .
[18] Cin-Ty A. Lee,et al. A trio of laser ablation in concert with two ICP‐MSs: Simultaneous, pulse‐by‐pulse determination of U‐Pb discordant ages and a single spot Hf isotope ratio analysis in complex zircons from petrographic thin sections , 2012 .
[19] J. Hellstrom,et al. Iolite: Freeware for the visualisation and processing of mass spectrometric data , 2011 .
[20] S. Samson,et al. A direct comparison of the ages of detrital monazite versus detrital zircon in Appalachian foreland basin sandstones: Searching for the record of Phanerozoic orogenic events , 2011 .
[21] M. McCulloch,et al. Tracing the provenance and recrystallization processes of the Earth's oldest detritus at Mt. Narryer and Jack Hills, Western Australia: An in situ Sm–Nd isotopic study of monazite , 2011 .
[22] J. Blichert‐Toft,et al. Synthetic zircon doped with hafnium and rare earth elements: A reference material for in situ hafnium isotope analysis , 2011 .
[23] H. Longerich,et al. Sm-Nd isotope systematics by laser ablation-multicollector-inductively coupled plasma mass spectrometry: Methods and potential natural and synthetic reference materials , 2011 .
[24] A. Gerdes,et al. The behavior of the Hf isotope system in radiation-damaged zircon during experimental hydrothermal alteration , 2010 .
[25] J. Hellstrom,et al. Improved laser ablation U‐Pb zircon geochronology through robust downhole fractionation correction , 2010 .
[26] A. Gerdes,et al. Zircon formation versus zircon alteration — New insights from combined U–Pb and Lu–Hf in-situ LA-ICP-MS analyses, and consequences for the interpretation of Archean zircon from the Central Zone of the Limpopo Belt , 2009 .
[27] J. Darling,et al. Concurrent Pb–Hf isotope analysis of zircon by laser ablation multi-collector ICP-MS, with implications for the crustal evolution of Greenland and the Himalayas , 2009 .
[28] T. Hirata,et al. Reworking of Hadean crust in the Acasta gneisses, northwestern Canada: Evidence from in-situ Lu–Hf isotope analysis of zircon , 2009 .
[29] A. Bouvier,et al. The Lu–Hf and Sm–Nd isotopic composition of CHUR: Constraints from unequilibrated chondrites and implications for the bulk composition of terrestrial planets , 2008 .
[30] D. Zhuang,et al. In situ simultaneous determination of trace elements, U-Pb and Lu-Hf isotopes in zircon and baddeleyite , 2008 .
[31] M. Whitehouse,et al. Plesovice zircon : A new natural reference material for U-Pb and Hf isotopic microanalysis , 2008 .
[32] D. Günther,et al. Simultaneous determinations of U–Pb age, Hf isotopes and trace element compositions of zircon by excimer laser-ablation quadrupole and multiple-collector ICP-MS , 2008 .
[33] J. Hellstrom,et al. Isotopic and Elemental Imaging of Geological Materials by Laser Ablation Inductively Coupled Plasma‐Mass Spectrometry , 2007 .
[34] J. Woodhead,et al. Strontium Isotope Analysis of Kimberlitic Groundmass Perovskite via LA‐MC‐ICP‐MS , 2007 .
[35] R. Creaser,et al. Queen Maud block: A newly recognized Paleoproterozoic (2.4-2.5 Ga) terrane in northwest Laurentia , 2007 .
[36] H. Isnard,et al. Investigations for determination of Gd and Sm isotopic compositions in spent nuclear fuels samples by MC ICPMS , 2005 .
[37] I. Katayama,et al. U-Pb and Lu-Hf isotope systematics of zircons from the Mississippi River sand: Implications for reworking and growth of continental crust , 2005 .
[38] R. Berman,et al. TECTONOMETAMORPHISM AT ca. 2.35 AND 1.85 Ga IN THE RAE DOMAIN, WESTERN CHURCHILL PROVINCE, NUNAVUT, CANADA: INSIGHTS FROM STRUCTURAL, METAMORPHIC AND IN SITU GEOCHRONOLOGICAL ANALYSIS OF THE SOUTHWESTERN COMMITTEE BAY BELT , 2005 .
[39] S. Eggins,et al. Zircon Hf-isotope analysis with an excimer laser, depth profiling, ablation of complex geometries, and concomitant age estimation , 2004 .
[40] L. Halicz,et al. Accurate isotope ratio measurements of ytterbium by multiple collection inductively coupled plasma mass spectrometry applying erbium and hafnium in an improved double external normalization procedure , 2003 .
[41] C. Isachsen,et al. The decay constant of 176Lu determined from Lu-Hf and U-Pb isotope systematics of terrestrial Precambrian high-temperature mafic intrusions , 2003 .
[42] P. Sylvester,et al. Present Trends and the Future of Zircon in Geochronology: Laser Ablation ICPMS , 2003 .
[43] P. Renne,et al. Call for an improved set of decay constants for geochronological use , 2001 .
[44] L. Heaman,et al. Age and origin of the Jan Lake Complex: a glimpse at the buried Archean craton of the Trans-Hudson Orogen , 1999 .
[45] D. Günther,et al. Inter-laboratory note. Laser ablation inductively coupled plasma mass spectrometric transient signal data acquisition and analyte concentration calculation , 1996 .
[46] P. Španěl,et al. Dissociative recombination of H3+ and some other interstellar ions: a controversy resolved , 1993 .
[47] J. Cesario,et al. Isotopic analysis of rare earth elements by total vaporization of samples in thermal ionization mass spectrometry , 1992 .