始新世/渐新世全球破坏和加勒比红树林的革命

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Valentí Rull
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引用次数: 4

摘要

在最近的一篇论文中,作者证明,与特提斯海周围白垩纪泛热带红树林带最终逐渐区域分化的主流观点相反,加勒比红树林起源于始新世,该地区已知的第一种形成红树林的树种进化出现后,现存Pelliciera的祖先。本文代表了分析加勒比红树林进化的第二步,处理了这些群落经历的最重要的变化,这些变化发生在始新世-始新世过渡期(EOT),在这里被称为加勒比红树林革命。这种转变包括原始的Pelliciera红树林的消失,以及由Rhizophora(一种新出现的红树林,仍然主导着现存的加勒比红树林)主导的红树林群落所取代。本文首先回顾了研究区EOT全球破坏(构造和古地理重组、海洋环流、冷却、南极冰川作用、海平面下降)及其区域表现的现有文献,以及相应的生物反应。这提供了使用>;该地区有80个花粉记录。在环加勒比地区,33.8至33.5 Ma之间记录到3-6°C的降温和67米的海平面下降,这导致了扩散途径和屏障以及海洋古水流的显著变化。始新世晚期的红树林以本地Pelliciera(高达60%的花粉组合)为主,而Rhizophora(可能是通过长距离传播从印度-太平洋地区抵达的)则不存在或非常稀少。EOT之后,情况发生了根本性的变化,因为红树林广泛地由Rhizophora主导,而Pelliciera(当存在时)是次要的红树林元素(<;10%)。与此同时,Pelliciera在始新世期间被限制在一小块土地上(中美洲和南美洲西北部或CA/NWSA),它的范围扩大到加勒比海及其他地区,一直是Rhizophora红树林的一个次要组成部分。优势的转移可能是由于EOT的冷却,有利于广环化和迷走神经根的扩张,而不是扩散能力有限的狭窄气候Pelliciera。这被认为是竞争对手通过利基隔离共存的情况。此外,Rhizophora可以通过提供躲避环境和生物压力的避难所,特别是光照强度和盐度,促进Pelliciera的扩张。始新世Pelliciera红树林从未回归,但该物种作为一个次要元素存活到现在,并经历了三个主要阶段的显著范围变化,即EOT–中新世向整个新热带地区扩张,中上新世向加勒比海南部边缘收缩,以及上新世至最近重组到原始始新世CA/NWSA位置。讨论了新第三纪和更新世气候变化和人类活动在这些生物地理循环(分类单元周期)中的潜在作用,重点是降水。文章最后对未来的研究提出了一些展望。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Eocene/Oligocene global disruption and the revolution of Caribbean mangroves

In a recent paper, the author demonstrated that, in contrast with the prevailing view of eventual gradual regional differentiation from a hypothetical Cretaceous pantropical mangrove belt around the Tethys Sea, the Caribbean mangroves originated de novo in the Eocene after the evolutionary appearance of the first mangrove-forming tree species known for the region, the ancestor of the extant Pelliciera. This paper represents a second step in the analysis of the evolution of Caribbean mangroves dealing with the most important change experienced by these communities, occurring across the EoceneOligocene transition (EOT), which is termed here the Caribbean mangrove revolution. This shift consisted of the disappearance of the primeval Pelliciera mangroves and their replacement by mangrove communities dominated by Rhizophora, a newly emerged mangrove tree that still dominates extant Caribbean mangroves. This paper first reviews the available literature on the EOT global disruption (tectonic and paleogeographic reorganizations, ocean circulation, cooling, Antarctic glaciation, sea-level fall) and its regional manifestations in the study area, along with the corresponding biotic responses. This provides the paleoenvironmental framework with which to analyze the EOT mangrove revolution using the >80 pollen records available for the region. In the circum-Caribbean region, cooling of 3–6 °C and a sea-level fall of 67 m were recorded between 33.8 and 33.5 Ma, which led to significant shifts in dispersal pathways and barriers, as well as in marine paleocurrents. Late Eocene mangroves were dominated by the autochthonous Pelliciera (up to 60% of pollen assemblages), while Rhizophora, which likely arrived from the Indo-Pacific region by long-distance dispersal, was absent or very scarce. After the EOT, the situation was radically different, as the mangroves were widely dominated by Rhizophora, and Pelliciera, when present, was a subordinate mangrove element (<10%). At the same time, Pelliciera, which had been restricted to a small patch (Central America and NW South America or CA/NWSA) during the Eocene, expanded its range across the Caribbean and beyond, always as a minor component of Rhizophora mangroves. The dominance shift could have been due to the EOT cooling, by favoring the expansion of the euryclimatic and vagile Rhizophora over the stenoclimatic Pelliciera, of limited dispersal ability. This is considered a case of competitor coexistence by niche segregation. In addition, Rhizophora could have facilitated the expansion of Pelliciera by providing refuge against environmental and biotic stressors, notably light intensity and salinity. The Eocene Pelliciera mangroves never returned, but this species survived to the present as a minor element and experienced significant range shifts along three main phases, namely, EOT–Miocene expansion to the whole Neotropics, Mio-Pliocene contraction to the southern Caribbean margin and Pliocene to recent reorganization to the original Eocene CA/NWSA location. The potential role of Neogene and Pleistocene climatic shifts and human activities in these biogeographical loops (taxon cycles) is discussed, with an emphasis on precipitation. The paper ends by suggesting some prospects for future research.

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