A practical method for assigning uncertainty and improving the accuracy of alpha-ejection corrections and eU concentrations in apatite (U–Th) ∕ He chronology
{"title":"A practical method for assigning uncertainty and improving the accuracy of alpha-ejection corrections and eU concentrations in apatite (U–Th) ∕ He chronology","authors":"Spencer D. Zeigler, J. Metcalf, R. Flowers","doi":"10.5194/gchron-5-197-2023","DOIUrl":null,"url":null,"abstract":"Abstract. Apatite (U–Th) / He (AHe) dating generally assumes that grains can\nbe accurately and precisely modeled as geometrically perfect hexagonal\nprisms or ellipsoids in order to compute the apatite volume (V),\nalpha-ejection corrections (FT), equivalent spherical radius\n(RFT), effective uranium concentration (eU), and corrected (U–Th) / He\ndate. It is well-known that this assumption is not true. In this work, we\npresent a set of corrections and uncertainties for V, FT, and RFT\naimed (1) at “undoing” the systematic deviation from the idealized\ngeometry and (2) at quantifying the contribution of geometric uncertainty to\nthe total uncertainty budget for eU and AHe dates. These corrections and\nuncertainties can be easily integrated into existing laboratory workflows at\nno added cost, can be routinely applied to all dated apatite, and can even\nbe retroactively applied to published data. To quantify the degree to which\nreal apatite deviates from geometric models, we selected 264 grains that span\nthe full spectrum of commonly analyzed morphologies, measured their\ndimensions using standard 2D microscopy methods, and then acquired 3D scans\nof the same grains using high-resolution computed tomography (CT). We then\ncompared our apatite 2D length, maximum width, and minimum width\nmeasurements with those determined by CT, as well as the V, FT, and\nRFT values calculated from 2D microscopy measurements with those from\nthe “real” 3D measurements. While our 2D length and maximum width\nmeasurements match the 3D values well, the 2D minimum width values\nsystematically underestimate the 3D values and have high scatter. We\ntherefore use only the 2D length and maximum width measurements to compute\nV, FT, and RFT. With this approach, apatite V, FT, and\nRFT values are all consistently overestimated by the 2D microscopy\nmethod, requiring correction factors of 0.74–0.83 (or 17 %–26 %), 0.91–0.99\n(or 1 %–9 %), and 0.85–0.93 (or 7 %–15 %), respectively. The 1σ\nuncertainties in V, FT, and RFT are 20 %–23 %, 1 %–6 %, and\n6 %–10 %, respectively. The primary control on the magnitude of the\ncorrections and uncertainties is grain geometry, with grain size exerting\nadditional control on FT uncertainty. Application of these corrections\nand uncertainties to a real dataset (N=24 AHe analyses) yields 1σ\nanalytical and geometric uncertainties of 15 %–16 % in eU and 3 %–7 % in the\ncorrected date. These geometric corrections and uncertainties are\nsubstantial and should not be ignored when reporting, plotting, and\ninterpreting AHe datasets. The Geometric Correction Method (GCM) presented\nhere provides a simple and practical tool for deriving more accurate FT\nand eU values and for incorporating this oft neglected geometric\nuncertainty into AHe dates.\n","PeriodicalId":12723,"journal":{"name":"Geochronology","volume":"436 1","pages":""},"PeriodicalIF":2.7000,"publicationDate":"2023-05-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Geochronology","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.5194/gchron-5-197-2023","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"GEOCHEMISTRY & GEOPHYSICS","Score":null,"Total":0}
引用次数: 1
Abstract
Abstract. Apatite (U–Th) / He (AHe) dating generally assumes that grains can
be accurately and precisely modeled as geometrically perfect hexagonal
prisms or ellipsoids in order to compute the apatite volume (V),
alpha-ejection corrections (FT), equivalent spherical radius
(RFT), effective uranium concentration (eU), and corrected (U–Th) / He
date. It is well-known that this assumption is not true. In this work, we
present a set of corrections and uncertainties for V, FT, and RFT
aimed (1) at “undoing” the systematic deviation from the idealized
geometry and (2) at quantifying the contribution of geometric uncertainty to
the total uncertainty budget for eU and AHe dates. These corrections and
uncertainties can be easily integrated into existing laboratory workflows at
no added cost, can be routinely applied to all dated apatite, and can even
be retroactively applied to published data. To quantify the degree to which
real apatite deviates from geometric models, we selected 264 grains that span
the full spectrum of commonly analyzed morphologies, measured their
dimensions using standard 2D microscopy methods, and then acquired 3D scans
of the same grains using high-resolution computed tomography (CT). We then
compared our apatite 2D length, maximum width, and minimum width
measurements with those determined by CT, as well as the V, FT, and
RFT values calculated from 2D microscopy measurements with those from
the “real” 3D measurements. While our 2D length and maximum width
measurements match the 3D values well, the 2D minimum width values
systematically underestimate the 3D values and have high scatter. We
therefore use only the 2D length and maximum width measurements to compute
V, FT, and RFT. With this approach, apatite V, FT, and
RFT values are all consistently overestimated by the 2D microscopy
method, requiring correction factors of 0.74–0.83 (or 17 %–26 %), 0.91–0.99
(or 1 %–9 %), and 0.85–0.93 (or 7 %–15 %), respectively. The 1σ
uncertainties in V, FT, and RFT are 20 %–23 %, 1 %–6 %, and
6 %–10 %, respectively. The primary control on the magnitude of the
corrections and uncertainties is grain geometry, with grain size exerting
additional control on FT uncertainty. Application of these corrections
and uncertainties to a real dataset (N=24 AHe analyses) yields 1σ
analytical and geometric uncertainties of 15 %–16 % in eU and 3 %–7 % in the
corrected date. These geometric corrections and uncertainties are
substantial and should not be ignored when reporting, plotting, and
interpreting AHe datasets. The Geometric Correction Method (GCM) presented
here provides a simple and practical tool for deriving more accurate FT
and eU values and for incorporating this oft neglected geometric
uncertainty into AHe dates.