深海沉积物档案中14C测年精度的再评价

IF 2.7 Q2 GEOCHEMISTRY & GEOPHYSICS
B. Lougheed, P. Ascough, A. Dolman, L. Löwemark, B. Metcalfe
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引用次数: 8

摘要

摘要目前在深海沉积物档案中应用放射性碳(14C)方法的地质年代学水平缺乏沉积物生物扰动的关键信息。在这里,我们应用了一个沉积物堆积模型,模拟了数百万有孔虫的沉积和生物扰动,根据其模拟时间步长,将现实的14C活动(即来自14C校准曲线)分配给每个单个有孔虫。我们发现,通常用于表示离散深度沉积物间隔的14C年龄的正态分布(基于报告的实验室14C年龄和测量误差)不太可能忠实地反映特定深度间隔的实际14C年龄分布。我们还发现,在校准过程中,这种与实际14C年龄分布的偏差被大大放大。具体来说,我们发现在许多情况下,系统地低估了总地质年代学误差(高达数千年),以及在下核校准的中位年龄中产生的年龄深度伪影。即使在“完美”模拟沉积物档案情景的情况下,沉积累积率(SAR)、生物扰动深度、水库年龄和物种丰度都保持不变,14C测量和校准过程也会产生数百年的时间动态中位年龄深度人工制品,因此即使是高SAR情景(40和60 cm kyr−1)也容易受到影响。在与地球Δ14C历史的动态变化相对应的时期,这种年龄深度的人工制品尤其明显,当时不同的14c活动的单个有孔虫可以合并到单个离散深度的沉积区间中。对于某些低sar情景,我们发现下离散深度的真实年龄中位数可能系统性地落在14C测量和校准过程预测的校准年龄范围之外,从而导致系统地不准确的年龄估计。简而言之,我们的研究结果表明,文献中可能存在14c衍生的年龄深度人工制品。此外,由于这种年龄深度人工制品很可能与全球Δ14C的大尺度变化相吻合,而全球Δ14C的大尺度变化本身也可能与全球气候的大尺度变化相吻合(如最后一次消冰期),因此,14c衍生的年龄深度人工制品以前可能被错误地归因于与全球气候相吻合的SAR变化。我们的研究强调了开发改进的深海沉积物14C校准技术的必要性,其中包括对多样品样品的生物扰动的优先表示。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Re-evaluating 14C dating accuracy in deep-sea sediment archives
Abstract. The current geochronological state of the art for applying the radiocarbon (14C) method to deep-sea sediment archives lacks key information on sediment bioturbation. Here, we apply a sediment accumulation model that simulates the sedimentation and bioturbation of millions of foraminifera, whereby realistic 14C activities (i.e. from a 14C calibration curve) are assigned to each single foraminifera based on its simulation time step. We find that the normal distribution of 14C age typically used to represent discrete-depth sediment intervals (based on the reported laboratory 14C age and measurement error) is unlikely to be a faithful reflection of the actual 14C age distribution for a specific depth interval. We also find that this deviation from the actual 14C age distribution is greatly amplified during the calibration process. Specifically, we find a systematic underestimation of total geochronological error in many cases (by up to thousands of years), as well as the generation of age–depth artefacts in downcore calibrated median age. Even in the case of “perfect” simulated sediment archive scenarios, whereby sediment accumulation rate (SAR), bioturbation depth, reservoir age and species abundance are all kept constant, the 14C measurement and calibration processes generate temporally dynamic median age–depth artefacts on the order of hundreds of years – whereby even high SAR scenarios (40 and 60 cm kyr−1) are susceptible. Such age–depth artefacts can be especially pronounced during periods corresponding to dynamic changes in the Earth's Δ14C history, when single foraminifera of varying 14C activity can be incorporated into single discrete-depth sediment intervals. For certain lower-SAR scenarios, we find that downcore discrete-depth true median age can systematically fall outside the calibrated age range predicted by the 14C measurement and calibration processes, thus leading to systematically inaccurate age estimations. In short, our findings suggest the possibility of 14C-derived age–depth artefacts in the literature. Furthermore, since such age–depth artefacts are likely to coincide with large-scale changes in global Δ14C, which themselves can coincide with large-scale changes in global climate (such as the last deglaciation), 14C-derived age–depth artefacts may have been previously incorrectly attributed to changes in SAR coinciding with global climate. Our study highlights the need for the development of improved deep-sea sediment 14C calibration techniques that include an a priori representation of bioturbation for multi-specimen samples.
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来源期刊
Geochronology
Geochronology Earth and Planetary Sciences-Paleontology
CiteScore
6.60
自引率
0.00%
发文量
35
审稿时长
19 weeks
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