Compound-Specific Radiocarbon Analysis by Elemental Analyzer–Accelerator Mass Spectrometry: Precision and Limitations

Haghipour, Negar; Ausín, Blanca; Usman, Muhammed; Ishikawa, Naoto F.; Wacker, Lukas; Welte, Caroline; Ueda, K.; Eglinton, Timothy I.

doi:10.1021/acs.analchem.8b04491

Cited by 58 publications

(63 citation statements)

References 38 publications

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“…The contribution of extraneous carbon to the WCO was evaluated by a suite of standards (WCO standards) prepared for each run by adding varying amounts of standard solution to vials containing 5 ml of ultrapure water, then taking them through the WCO procedure. To evaluate the mass and F 14 C of extraneous carbon for each run, we used the model of constant contamination described in Hanke et al (2017) and Haghipour et al (2018). The procedural blank of the decarbonation (chemical pre-treatment standard) was quantified by spiking vials containing acid with variable amounts of sucrose and phthalic acid, before taking them through the entire procedure (Fig.…”

Section: Blank Assessmentmentioning

confidence: 99%

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Towards Organic Carbon Isotope Records from Stalagmites: Coupled δ13C and 14C Analysis Using Wet Chemical Oxidation

et al. 2019

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Speleothem organic matter can be a powerful tracer for past environmental conditions and karst processes. Carbon isotope measurements (δ13C and 14C) in particular can provide crucial information on the provenance and age of speleothem organic matter, but are challenging due to low concentrations of organic matter in stalagmites. Here, we present a method development study on extraction and isotopic characterization of speleothem organic matter using a rapid procedure with low laboratory contamination risk. An extensive blank assessment allowed us to quantify possible sources of contamination through the entire method. Although blank contamination is consistently low (1.7 ± 0.34 – 4.3 ± 0.86 μg C for the entire procedure), incomplete sample decarbonation poses a still unresolved problem of the method, but can be detected when considering both δ13C and 14C values. We test the method on five stalagmites, showing reproducible results on samples as small as 7 μg C for δ13C and 20 μg C for 14C. Furthermore, we find consistently lower non-purgeable organic carbon (NPOC) 14C values compared to the carbonate 14C over the bomb spike interval in two stalagmites from Yok Balum Cave, Belize, suggesting overprint of a pre-aged or even fossil source of carbon on the organic fraction incorporated by these stalagmites.

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Section: Blank Assessmentmentioning

confidence: 99%

“…Both methods assume constant contamination from each method step on all samples. Table 2), the average blank contamination over all runs was1.30 ± 0.52 μg C, F 14 C= 0.42 ± 0.17, when calculated with the method of constant contamination byHaghipour et al (2018; Suppl. Table 1).…”

mentioning

confidence: 98%

Towards Organic Carbon Isotope Records from Stalagmites: Coupled δ13C and 14C Analysis Using Wet Chemical Oxidation

et al. 2019

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“…For correcting the processed standards, a constant contamination of 2.2 ± 1.3 µgC with 0.25 ± 0.09 Fm (average of all five direct blank measurements) was applied which bins together the blanks isolated under elution time windows corresponding to those of the reported amino acids and purified with the PrimesepA column under isocratic 95-5-0.05 and 65-35-0.05 water-acetonitrile-TFA conditions. This simplified assignment of constant contamination has large uncertainty compared to more rigorously constrained contamination case studies (Haghipour et al, 2019), yet, using Equations 1 and 2 [following Wacker and Christl (2012); see Supplementary Material], corrects all standards (IIb) within error of their respective consensus radiocarbon isotopic compositions (Table 1). Nonetheless, this blank size is consistent with observations made by Ishikawa et al (2018) who quantify the total blank as approximately 2.4 µgC for samples without "post-purification" (filtration and rinsing with diethyl ether; see procedure 3b in Figure 1).…”

Section: Discussionmentioning

confidence: 99%

Liquid Chromatographic Isolation of Individual Amino Acids Extracted From Sediments for Radiocarbon Analysis

et al. 2020

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The "building blocks of life" are found nearly ubiquitously in the environment in the form of proteins, peptides, and single amino acids. To shed light on amino acid sources, cycling, and preservation in sedimentary environments, we present a method using high-pressure liquid chromatography to separate and isolate underivatized amino acids extracted from sediments to conduct compound-specific radiocarbon analysis. This method consists of three main steps including (1) amino acid extraction by hydrofluoric and hydrochloric acids followed by desalting, (2) liquid chromatographic isolation and purification using two complementary column chemistries, and (3) post-purification and measurement by accelerator mass spectrometry. The resulting blank of this procedure is estimated to contain 2.2 ± 1.3 µgC with 0.25 ± 0.09 Fm.

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“…Several recent developments suggest further improvements to natural abundance 14 C analysis. New CO 2 -accepting ion sources allow peripheral instruments, such as elemental analyzers, other oxidation or hydrolysis systems and potentially gas chromatography, to interface directly to AMS (Bronk Ramsey et al, 2004;Ruff et al, 2010;Haghipour et al, 2019). This eliminates the need for an offline graphitization step, which is labor-intensive and potentially introduces 14 C contamination.…”

Section: Natural-level Radiocarbon Analysismentioning

confidence: 99%

Analytical and Computational Advances, Opportunities, and Challenges in Marine Organic Biogeochemistry in an Era of “Omics”

et al. 2020

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Advances in sampling tools, analytical methods, and data handling capabilities have been fundamental to the growth of marine organic biogeochemistry over the past four decades. There has always been a strong feedback between analytical advances and scientific advances. However, whereas advances in analytical technology were often the driving force that made possible progress in elucidating the sources and fate of organic matter in the ocean in the first decades of marine organic biogeochemistry, today process-based scientific questions should drive analytical developments. Several paradigm shifts and challenges for the future are related to the intersection between analytical progress and scientific evolution. Untargeted "molecular headhunting" for its own sake is now being subsumed into process-driven targeted investigations that ask new questions and thus require new analytical capabilities. However, there are still major gaps in characterizing the chemical composition and biochemical behavior of macromolecules, as well as in generating reference standards for relevant types of organic matter. Field-based measurements are now routinely complemented by controlled laboratory experiments and in situ rate measurements of key biogeochemical processes. And finally, the multidisciplinary investigations that are becoming more common generate large and diverse datasets, requiring innovative computational tools

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Compound-Specific Radiocarbon Analysis by Elemental Analyzer–Accelerator Mass Spectrometry: Precision and Limitations

Cited by 58 publications

References 38 publications

Towards Organic Carbon Isotope Records from Stalagmites: Coupled δ13C and 14C Analysis Using Wet Chemical Oxidation

Towards Organic Carbon Isotope Records from Stalagmites: Coupled δ13C and 14C Analysis Using Wet Chemical Oxidation

Liquid Chromatographic Isolation of Individual Amino Acids Extracted From Sediments for Radiocarbon Analysis

Analytical and Computational Advances, Opportunities, and Challenges in Marine Organic Biogeochemistry in an Era of “Omics”

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