Experimental calibration of clumped isotopes in siderite between 8.5 and 62 °C and its application as paleo-thermometer in paleosols

Dijk, Joep van; Fernández, Álvaro; Storck, Julian-Christopher; White, Timothy S.; Lever, Mark A.; Müller, Inigo A.; Bishop, Stewart; Seifert, Reto; Driese, Steven G.; Krylov, Alexey; Ludvigson, Greg A.; Turchyn, Alexandra V.; Lin, Chin Yik; Wittkop, Chad; Bernasconi, Stefano M.

doi:10.1016/j.gca.2019.03.018

Cited by 22 publications

(36 citation statements)

References 94 publications

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“…We must note, however, that none of the data that initially suggested large mineralogical differences in Δ* 25-X was included in this reprocessing effort. This data set is not able to interrogate Δ* mineralogyX values (difference between Δ 47 of CO 2 and Δ 63 of solid carbonate), which some have suggested shows mineralogical differences as well (van Dijk et al, 2019;Müller et al, 2017).…”

Section: Effects Of Updating From Sg To Iupac Parameters On the Tempementioning

confidence: 99%

“…Without applying any acid fractionation correction, Δ 47 values for samples reacted at the same temperature can be directly compared, but a choice of Δ* 25-X (or Δ* T1-T2 between any two reaction temperatures) is necessary to compare samples reacted at different acid temperatures. A variety of theoretical (Guo et al, 2009) and experimental (Bonifacie et al, 2017;Defliese et al, 2015;van Dijk et al, 2019;Guo et al, 2009;Henkes et al, 2013;Kelson et al, 2017;Müller et al, 2017;Murray et al, 2016;Passey et al, 2010;Tripati et al, 2015;Wacker et al, 2013;Winkelstern et al, 2016) values for Δ* 17ineralogy and Δ* 25-X have been put forward. Many of these experimental studies have found similar behavior across differing mineralogies (Bonifacie et al, 2017;Defliese et al, 2015;Kelson et al, 2017;Wacker et al, 2013;Winkelstern et al, 2016), with nondistinguishable values (Δ* dolomite90 values within error of theoretical Δ* calcite90 values, Bonifacie et al, 2017), overlapping calibration data (Bonifacie et al, 2017;Defliese et al, 2015;Kelson et al, 2017;Wacker et al, 2013;Winkelstern et al, 2016), or identical Δ* 25-X values across multiple mineralogies (Defliese et al, 2015).…”

Section: 1029/2018gc008127mentioning

confidence: 99%

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Effects of Improved ¹⁷O Correction on Interlaboratory Agreement in Clumped Isotope Calibrations, Estimates of Mineral‐Specific Offsets, and Temperature Dependence of Acid Digestion Fractionation

Petersen

Defliese

Saenger

et al. 2019

Geochem Geophys Geosyst

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169

281

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The clumped isotopic composition of carbonate‐derived CO2 (denoted Δ47) is a function of carbonate formation temperature and in natural samples can act as a recorder of paleoclimate, burial, or diagenetic conditions. The absolute abundance of heavy isotopes in the universal standards VPDB and VSMOW (defined by four parameters: R13VPDB, R17VSMOW, R18VSMOW, and λ) impact calculated Δ47 values. Here, we investigate whether use of updated and more accurate values for these parameters can remove observed interlaboratory differences in the measured T‐Δ47 relationship. Using the updated parameters, we reprocess 14 published calibration data sets measured in 11 different laboratories, representing many mineralogies, bulk compositions, sample types, reaction temperatures, and sample preparation and analysis methods. Exploiting this large composite data set (n = 1,253 sample replicates), we investigate the possibility for a “universal” clumped isotope calibration. We find that applying updated parameters improves the T‐Δ47 relationship (reduces residuals) within most labs and improves overall agreement but does not eliminate all interlaboratory differences. We reaffirm earlier findings that different mineralogies do not require different calibration equations and that cleaning procedures, method of pressure baseline correction, and mass spectrometer type do not affect interlaboratory agreement. We also present new estimates of the temperature dependence of the acid digestion fractionation for Δ47 (Δ*25‐X), based on combining reprocessed data from four studies, and new theoretical equilibrium values to be used in calculation of the empirical transfer function. Overall, we have ruled out a number of possible causes of interlaboratory disagreement in the T‐Δ47 relationship, but many more remain to be investigated.

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Section: Effects Of Updating From Sg To Iupac Parameters On the Tempementioning

confidence: 99%

Section: 1029/2018gc008127mentioning

confidence: 99%

Effects of Improved ¹⁷O Correction on Interlaboratory Agreement in Clumped Isotope Calibrations, Estimates of Mineral‐Specific Offsets, and Temperature Dependence of Acid Digestion Fractionation

Petersen

Defliese

Saenger

et al. 2019

Geochem Geophys Geosyst

Self Cite

169

281

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“…We choose to work solely on calcites to avoid potential biases due to specific acid fractionation factors (AFF) when using different carbonates (i.e. aragonite, dolomite, siderite) as theoretically predicted (Guo et al, 2009) and shown by recent experimental work (Müller et al, 2017a;van Dijk et al, 2019) at the temperature of acid digestion used in this study (70°C). We also took advantage of the growing number of laboratories that adopted a fully carbonate-based standardisation of Δ 47 measurementsidentical to the treatment used hereto evaluate further the improvement brought by this standardisation scheme to interlaboratory comparison.…”

Section: Introductionmentioning

confidence: 99%

Clumped isotope temperature calibration for calcite: Bridging theory and experimentation

Jautzy¹,

Savard²,

Dhillon³

et al. 2020

Geochem. Persp. Let.

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Clumped isotopes (Δ 47) analysis in carbonates is becoming widespread across the geochemical community as a geothermometer that also allows for the reconstruction of the precipitating fluid δ 18 O composition. While initial Δ 47-temperature relationship discrepancies between laboratories have been considerably reduced over the past 10 years, theoretical temperature calibration and laboratory experimental efforts have still not converged to common ground. Moreover, a lack of high temperature anchor points has weakened its application to high temperature calcite formation. Here we present a temperature calibration for carbonate clumped isotopes between 5 and 726°C, using synthetically precipitated and heated calcites, to extend the calcite Δ 47-temperature calibration to higher temperatures. By showing a strong agreement between the empirical calibration proposed here, theoretical and all recently published T-calibrations made using a full carbonate referencing scheme, this study: (1) provides a calibration allowing more precise application in high temperature geological systems, (2) further supports the improvement of inter-laboratory comparison by using carbonate standards, (3) reconciles empirical temperature calibrations with theory.

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“…Since the initial proposal of this proxy, a number of different Δ 47 -T calibrations have been published, leading to reconstructed temperature discrepancies of up to 10-15 C based on the same Δ 47 value. 1,17,[20][21][22][23][24][25][26][27][28][29][30][31][32][33] Several hypotheses exist as to the origin of calibration differences, including different gas preparation procedures, different mass spectrometric corrections, and potentially different acid fractionation factors [34][35][36] 20,25,30,34 or use of temperature calibrations for different carbonate minerals (e.g. dolomite in Bonifacie et al, 37 calcite in Kele et al 31 and Kelson et al, 32 and siderite in van Dijk et al 36 ).…”

Section: Introductionmentioning

confidence: 99%

Effects of different constants and standards on the reproducibility of carbonate clumped isotope (Δ₄₇) measurements: Insights from a long‐term dataset

Chang

Defliese

et al. 2020

Rapid Comm Mass Spectrometry

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Rationale Carbonate clumped isotope (Δ47) thermometry examines the temperature‐dependent excess abundance of the 13C–18O bond in the carbonate lattice. Inconsistent temperature calibrations and standard values have been reported among laboratories, which has led to the use of equilibrated gases and carbonate standards for standardization. Furthermore, different acid fractionation factors and isotopic parameter sets have been proposed for improving inter‐laboratory data comparability. However, few long‐term datasets have been generated to explore the effects of these factors on the long‐term reproducibility of Δ47 data within a laboratory. Methods Four standards (ISTB‐1, NBS‐19, GBWO4416, and GB04417) were analyzed as unknowns by isotope ratio mass spectrometry from 2015 to 2019. The values of Δ47 were calibrated using the ETH standards. We investigated the Assonov, Brand, and Gonfiantini isotope parameter sets for carbon and oxygen isotopes, as well as two correction schemes of equilibrated gas and carbonate standardization, using the same sample measurements to determine which procedures enhanced reproducibility. ISTB‐1 (calcite) and ZK312‐346W (dolomite) were measured to determine the 90°C acid fractionation factor. Results The corrected 90°C acid fractionation factors are 0.076 ± 0.008‰ for ISTB‐1 and 0.077 ± 0.009‰ for ZK312‐346W. The choice of isotope parameter set had no significant influence on final Δ47 values in this study. However, using the Assonov parameters to calculate Δ47 values improved the reproducibility of the results. The use of carbonate standards improved reproducibility through time compared with the use of equilibrated gases for standardization. Conclusions At 90°C, the acid fractionation factors of calcite and dolomite are statistically indistinguishable. We find an insignificant effect from changing the isotope parameter set, suggesting that the choice of isotope parameter set among laboratories is not a major factor affecting inter‐laboratory reproducibility. We find that using carbonate standards improved the reproducibility of results, suggesting that the use of carbonate standards may help to achieve inter‐laboratory comparability of results in future studies.

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Experimental calibration of clumped isotopes in siderite between 8.5 and 62 °C and its application as paleo-thermometer in paleosols

Cited by 22 publications

References 94 publications

Effects of Improved ¹⁷O Correction on Interlaboratory Agreement in Clumped Isotope Calibrations, Estimates of Mineral‐Specific Offsets, and Temperature Dependence of Acid Digestion Fractionation

Effects of Improved ¹⁷O Correction on Interlaboratory Agreement in Clumped Isotope Calibrations, Estimates of Mineral‐Specific Offsets, and Temperature Dependence of Acid Digestion Fractionation

Clumped isotope temperature calibration for calcite: Bridging theory and experimentation

Effects of different constants and standards on the reproducibility of carbonate clumped isotope (Δ₄₇) measurements: Insights from a long‐term dataset

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Experimental calibration of clumped isotopes in siderite between 8.5 and 62 °C and its application as paleo-thermometer in paleosols

Cited by 22 publications

References 94 publications

Effects of Improved 17O Correction on Interlaboratory Agreement in Clumped Isotope Calibrations, Estimates of Mineral‐Specific Offsets, and Temperature Dependence of Acid Digestion Fractionation

Effects of Improved 17O Correction on Interlaboratory Agreement in Clumped Isotope Calibrations, Estimates of Mineral‐Specific Offsets, and Temperature Dependence of Acid Digestion Fractionation

Clumped isotope temperature calibration for calcite: Bridging theory and experimentation

Effects of different constants and standards on the reproducibility of carbonate clumped isotope (Δ47) measurements: Insights from a long‐term dataset

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Product

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Experimental calibration of clumped isotopes in siderite between 8.5 and 62 °C and its application as paleo-thermometer in paleosols

Effects of Improved ¹⁷O Correction on Interlaboratory Agreement in Clumped Isotope Calibrations, Estimates of Mineral‐Specific Offsets, and Temperature Dependence of Acid Digestion Fractionation

Effects of Improved ¹⁷O Correction on Interlaboratory Agreement in Clumped Isotope Calibrations, Estimates of Mineral‐Specific Offsets, and Temperature Dependence of Acid Digestion Fractionation

Effects of different constants and standards on the reproducibility of carbonate clumped isotope (Δ₄₇) measurements: Insights from a long‐term dataset