A downcore increase in time averaging is the null expectation from the transit of death assemblages through a mixed layer

IF 2.6 2区地球科学 Q2 BIODIVERSITY CONSERVATION

Paleobiology Pub Date : 2023-01-19 DOI:10.1017/pab.2022.42

A. Tomašovỳch, S. Kidwell, Ran Dai

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引用次数: 2

Abstract

Abstract. Understanding how time averaging changes during burial is essential for using Holocene and Anthropocene cores to analyze ecosystem change, given the many ways in which time averaging affects biodiversity measures. Here, we use transition-rate matrices to explore how the extent of time averaging changes downcore as shells transit through a taphonomically complex mixed layer into permanently buried historical layers: this is a null model, without any temporal changes in rates of sedimentation or bioturbation, to contrast with downcore patterns that might be produced by human activity. Assuming stochastic burial and exhumation movements of shells between increments within the mixed layer and stochastic disintegration within increments, we find that almost all combinations of net sedimentation, mixing, and disintegration produce a downcore increase in time averaging (interquartile range [IQR] of shell ages), this trend is typically associated with a decrease in kurtosis and skewness and by a shift from right-skewed to symmetrical age distributions. A downcore increase in time averaging is thus the null expectation wherever bioturbation generates an internally structured mixed layer (i.e., a surface, well-mixed layer is underlain by an incompletely mixed layer): under these conditions, shells are mixed throughout the entire mixed layer at a slower rate than they are buried below it by sedimentation. This downcore trend created by mixing is further amplified by the downcore decline in disintegration rate. We find that transition-rate matrices accurately reproduce the downcore changes in IQR, skewness, and kurtosis observed in bivalve assemblages from the southern California shelf. The right-skewed shell age-frequency distributions typical of surface death assemblages—the focus of most actualistic research—might be fossilized under exceptional conditions of episodic anoxia or sudden burial. However, such right-skewed assemblages will typically not survive transit through the surface mixed layer into subsurface historical layers: they are geologically transient. The deep-time fossil record will be dominated instead by the more time-averaged assemblages with weakly skewed age distributions that form in the lower parts of the mixed layer.

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时间平均的下核增长是死亡组合通过混合层传递的零期望

摘要考虑到时间平均对生物多样性测量的多种影响，了解埋葬过程中时间平均的变化对于使用全新世和人类世岩心分析生态系统变化至关重要。在这里，我们使用转换速率矩阵来探索当贝壳穿过地震学复杂的混合层进入永久埋藏的历史层时，时间平均的程度是如何在地下发生变化的：这是一个零模型，沉积或生物扰动速率没有任何时间变化，与人类活动可能产生的地下模式形成对比。假设混合层内增量之间贝壳的随机埋藏和挖掘运动，以及增量内的随机崩解，我们发现几乎所有净沉降、混合和崩解的组合都会在时间平均值（贝壳年龄的四分位间距[IQR]）上产生下降，这种趋势通常与峰度和偏度的降低以及从右偏向对称年龄分布的转变有关。因此，当生物扰动产生内部结构的混合层（即表面、充分混合的层下面是不完全混合的层）时，时间平均值的下降是零预期：在这些条件下，贝壳在整个混合层中的混合速度比它们通过沉积埋在混合层下面的速度慢。混合产生的下降趋势被分解率的下降进一步放大。我们发现，转换速率矩阵准确地再现了在南加州陆架双壳类组合中观察到的IQR、偏度和峰度的下降变化。地表死亡组合的典型右偏壳年龄频率分布——大多数实际研究的焦点——可能是在偶发性缺氧或突然埋葬的特殊条件下石化的。然而，这种右斜组合通常无法通过表面混合层进入地下历史层：它们在地质上是瞬态的。深层化石记录将由混合层下部形成的具有弱偏斜年龄分布的时间平均组合主导。

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来源期刊

Paleobiology 地学-古生物学

CiteScore

5.30

自引率

3.70%

发文量

审稿时长

>12 weeks

期刊介绍： Paleobiology publishes original contributions of any length (but normally 10-50 manuscript pages) dealing with any aspect of biological paleontology. Emphasis is placed on biological or paleobiological processes and patterns, including macroevolution, extinction, diversification, speciation, functional morphology, bio-geography, phylogeny, paleoecology, molecular paleontology, taphonomy, natural selection and patterns of variation, abundance, and distribution in space and time, among others. Taxonomic papers are welcome if they have significant and broad applications. Papers concerning research on recent organisms and systems are appropriate if they are of particular interest to paleontologists. Papers should typically interest readers from more than one specialty. Proposals for symposium volumes should be discussed in advance with the editors.