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相关概念视频

Threats to Biodiversity01:50

Threats to Biodiversity

There have been five major extinction events throughout geological history, resulting in the elimination of biodiversity, followed by a rebound of species that adapted to the new conditions. In the current geological epoch, the Holocene, there is a sixth extinction event in progress. This mass extinction has been attributed to human activities and is thus provisionally called the Anthropocene. In 2019 the human population reached 7.7 billion people and is projected to comprise 10 billion by...
Keystone Species01:39

Keystone Species

Measures of species biodiversity, such as richness (i.e., the number of species present) and evenness (i.e., their relative abundance), describe an ecological community’s structure. Many factors affect community structure, including abiotic factors (e.g., sunlight and nutrients), disturbances (e.g., fire or flood), species interactions (e.g., predation or competition), and chance events (e.g., foreign species invasion). Certain species—such as keystone species—also play a pivotal role in the...
Ecological Disturbance02:26

Ecological Disturbance

An ecological disturbance is a temporary disruption in the environment resulting from abiotic, biotic, or anthropogenic factors, causing a pronounced change in an ecosystem. The impact of an ecological disturbance, which can depend on its intensity, frequency, and spatial distribution, plays a significant role in shaping the species diversity within the ecosystem.Ecological disturbances can be caused by an event as small as the trampling of underbrush to an incident as wide-ranging as a forest...
Habitat Fragmentation02:31

Habitat Fragmentation

Habitat fragmentation describes the division of a more extensive, continuous habitat into smaller, discontinuous areas. Human activities such as land conversion, as well as slower geological processes leading to changes in the physical environment, are the two leading causes of habitat fragmentation. The fragmentation process typically follows the same steps: perforation, dissection, fragmentation, shrinkage, and attrition.
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The deep ocean and its underlying sediments represent vast, largely unexplored microbial habitats that extend far beyond the sunlit photic zone. The photic (euphotic) zone typically spans the upper ~100–200 meters of pelagic waters in the open ocean, but its depth varies geographically and seasonally, where sufficient light supports photosynthetic life. Below this lies the deep sea, spanning roughly 1000–6000 meters (bathypelagic to abyssal zones), with deeper hadal trenches extending beyond...

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Prospecting Microbial Strains for Bioremediation and Probiotics Development for Metaorganism Research and Preservation
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在海洋本托斯的灭绝和生态系统功能.

Martin Solan1, Bradley J Cardinale, Amy L Downing

  • 1Oceanlab, University of Aberdeen, Main Street, Newburgh, Aberdeenshire, Scotland AB41 6AA. m.solan@abdn.ac.uk

Science (New York, N.Y.)
|November 13, 2004
PubMed
概括
此摘要是机器生成的。

物种灭绝通常会减少海洋生态系统中重要的沉积物生物化. 影响的大小取决于物种特征和灭绝顺序,影响生态系统后果.

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科学领域:

  • 海洋生态海洋生态学
  • 生物多样性研究的研究.
  • 生态系统的运作 生态系统的运作

背景情况:

  • 全球生物多样性正在迅速变化,显著的生态影响尚未完全理解.
  • 沉积物生物化是保持水生社区健康和生态系统持久性的关键过程.

研究的目的:

  • 模拟物种灭绝对海洋沉积物生物化的影响.
  • 了解物种的功能特征和灭绝顺序如何影响生态系统层面的后果.

主要方法:

  • 利用了来自海洋无脊椎动物群落的数据.
  • 参数化预测模型模拟灭绝场景.
  • 分析了物种功能特征,灭绝风险和生物流水平之间的关系.

主要成果:

  • 预测物种灭绝通常是为了减少沉积物生物化.
  • 生物流减少的程度取决于物种的功能特征和它们的灭绝风险之间的共变性.
  • 灭绝的具体驱动因素和物种丧失的顺序显著改变了生态系统的结果.

结论:

  • 生物多样性丧失可能会损害重要的生态系统过程,如生物化.
  • 预测灭绝的生态后果需要考虑物种特有的特征和物种丧失的动态.
  • 保护战略必须考虑特征依赖的灭绝脆弱性,以减轻生态系统层面的影响.