一种通过氢热解快速分离发热碳以进行稳定同位素和放射性碳分析的方法。

A rapid throughput technique to isolate pyrogenic carbon by hydrogen pyrolysis for stable isotope and radiocarbon analysis.

机构信息

ARC Centre of Excellence for Australian Biodiversity and Heritage and Centre for Tropical Environmental and Sustainability Science, College of Science and Engineering, James Cook University, Cairns, QLD, Australia.

NERC Radiocarbon Facility, SUERC, Scottish Enterprise Technology Park, East Kilbride, UK.

出版信息

Rapid Commun Mass Spectrom. 2020 May 30;34(10):e8737. doi: 10.1002/rcm.8737.

DOI:10.1002/rcm.8737

PMID:31981268

Abstract

RATIONALE

Rapid, reliable isolation of pyrogenic carbon (PyC; also known as char, soot, black carbon, or biochar) for the determination of stable carbon isotope (δ C) composition and radiocarbon ( C) dating is needed across multiple fields of research in geoscience, environmental science and archaeology. Many current techniques do not provide reliable isolation from contaminating organics and/or are relatively time-consuming. Hydrogen pyrolysis (HyPy) does provide reliable isolation of PyC, but the current methodology is time consuming.

METHODS

We explored the potential for subjecting multiple samples to HyPy analysis by placing up to nine individual samples in custom-designed borosilicate sample vessels in a single reactor run. We tested for cross-contamination between samples in the same run using materials with highly divergent radiocarbon activities (~0.04-116.3 pMC), δ C values (-11.9 to -26.5‰) and labile carbon content. We determined C/ C using accelerator mass spectrometry and δ C values using an elemental analyser coupled to a continuous flow isotope ratio mass spectrometer.

RESULTS

Very small but measurable transfer between samples of highly divergent isotope composition was detectable. For samples having a similar composition, this cross-contamination is considered negligible with respect to measurement uncertainty. For samples having divergent composition, we found that placing a sample vessel loaded with silica mesh adsorbent between samples eliminated measurable cross-contamination in all cases for both C/ C and δ C values.

CONCLUSIONS

It is possible to subject up to seven samples to HyPy in the same reactor run for the determination of radiocarbon content and δ C value without diminishing the precision or accuracy of the results. This approach enables an increase in sample throughput of 300-600%. HyPy process background values are consistently lower than the nominal laboratory process background for quartz tube combustion in the NERC Radiocarbon Laboratory, indicating that HyPy may also be advantageous as a relatively 'clean' radiocarbon pre-treatment method.

摘要

原理

在地球科学、环境科学和考古学等多个研究领域，都需要快速、可靠地分离发热碳（PyC；也称为炭、煤烟、黑碳或生物炭），以确定稳定碳同位素（δ¹³C）组成和放射性碳（¹⁴C）测年。许多当前的技术无法可靠地分离出污染有机物，或者相对耗时。氢热解（HyPy）确实可以可靠地分离 PyC，但当前的方法耗时。

方法

我们探索了通过在单个反应堆运行中，将多达九个单个样品放入定制设计的硼硅酸盐样品容器中，对多个样品进行 HyPy 分析的潜力。我们使用具有高度不同放射性碳活度（~0.04-116.3 pMC）、δ¹³C 值（-11.9 至-26.5‰）和不稳定碳含量的材料，测试了同一运行中样品之间的交叉污染情况。我们使用加速器质谱法测定 ¹⁴C/¹²C 值，并使用与连续流动同位素比质谱仪耦合的元素分析仪测定 δ¹³C 值。

结果

对于具有高度不同同位素组成的样品，虽然可检测到非常小但可测量的转移，但对于具有相似组成的样品，这种交叉污染在测量不确定度方面被认为可以忽略不计。对于具有不同组成的样品，我们发现，在所有情况下，在样品之间放置一个装满硅胶网吸附剂的样品容器，可以消除 ¹⁴C/¹²C 和 δ¹³C 值的可测量交叉污染。

结论

对于同一反应堆运行，可以对多达七个样品进行 HyPy 处理，以确定放射性碳含量和 δ¹³C 值，而不会降低结果的精密度或准确性。这种方法可以将样品通量提高 300-600%。HyPy 过程背景值始终低于 NERC 放射性碳实验室石英管燃烧的标称实验室过程背景值，这表明 HyPy 也可能是一种相对“清洁”的放射性碳预处理方法。