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Microbes and Other Elemental Cycles01:24

Microbes and Other Elemental Cycles

Microbial activity plays a pivotal role in the biogeochemical cycling of iron and manganese, especially at the redox gradients characteristic of stratified aquatic environments. These cycles are driven by microbial transformations between oxidized and reduced forms of the metals, allowing organisms to exploit them for metabolic energy and structural purposes.Iron Cycling Across Redox GradientsIn neutral, oxygen-rich surface waters, iron is predominantly found in its oxidized, insoluble ferric...
Metabolism of Chemolithotrophs01:15

Metabolism of Chemolithotrophs

Chemolithotrophs are microorganisms that obtain energy by oxidizing inorganic molecules such as hydrogen gas (H₂), ammonia (NH₃), reduced sulfur compounds (H₂S, S²⁻), and ferrous iron (Fe²⁺). Unlike heterotrophic organisms that rely on organic carbon, chemolithotrophs transfer electrons from these inorganic donors to the electron transport chain (ETC), generating a proton motive force (PMF) that drives ATP synthesis through oxidative phosphorylation. However, because inorganic electron donors...
Microbes and the Sulfur Cycle01:29

Microbes and the Sulfur Cycle

Sulfur is a vital element in Earth's biogeochemical systems. It transitions through various inorganic states, including sulfate (SO₄²⁻), elemental sulfur (S⁰), and sulfide (S²⁻). Abiotic and biological mechanisms across oxic and anoxic environments intricately mediate these transformations. Sulfate, the most oxidized form of sulfur, is predominantly stored in rocks, marine sediments, and oceanic waters, acting as a long-term reservoir in the global sulfur cycle.In oxic environments,...
Carbon-dioxide Fixation01:28

Carbon-dioxide Fixation

Carbon dioxide fixation in prokaryotes enables the assimilation of inorganic carbon into organic molecules, supporting biosynthetic pathways, sustaining ecosystems, and contributing to the global carbon cycle. It also has industrial applications in carbon capture and bioproduct synthesis. Autotrophic organisms rely on this process to utilize CO₂ as a carbon source in diverse environments.The Calvin CycleThe Calvin cycle is the most widespread carbon fixation mechanism, primarily used by...
Origin of Photosynthesis01:26

Origin of Photosynthesis

Photosynthesis represents a fundamental biological process that transformed Earth's atmosphere and paved the way for complex life. Emerging roughly 3.4–3.8 billion years ago, the earliest photosynthetic organisms harnessed light energy to produce organic compounds. These anoxygenic phototrophs used electron donors like hydrogen sulfide (H₂S) or ferrous iron (Fe²⁺), rather than water, and did not release molecular oxygen (O₂) as a byproduct. Various groups, including green sulfur and purple...
Microbial Nutrition01:28

Microbial Nutrition

Organisms exhibit remarkable metabolic diversity, categorized based on how they acquire energy and carbon. These strategies enable survival in various ecological niches and are essential for maintaining energy flow and nutrient cycling within ecosystems.Energy and Carbon SourcesOrganisms are classified as phototrophs or chemotrophs based on energy acquisition. Phototrophs use light as their energy source, while chemotrophs rely on oxidizing chemical compounds. Further differentiation arises...

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Updated: May 15, 2026

Laboratory Simulation of an Iron(II)-rich Precambrian Marine Upwelling System to Explore the Growth of Photosynthetic Bacteria
09:45

Laboratory Simulation of an Iron(II)-rich Precambrian Marine Upwelling System to Explore the Growth of Photosynthetic Bacteria

Published on: July 24, 2016

酸化条件下での地上の増殖.

Julien Siebert1, James Badro, Daniele Antonangeli

  • 1Institut de Minéralogie et de Physique des Milieux Condensés, Université Pierre et Marie Curie, UMR CNRS 7590, Institut de Physique du Globe de Paris, 75005 Paris, France. julien.siebert@impmc.upmc.fr

Science (New York, N.Y.)
|January 12, 2013
PubMed
まとめ
この要約は機械生成です。

地球の核形成は,これまで考えられていたよりも酸化が強い条件下で起こったのかもしれない. この研究は,高圧実験を用いてシデロファイルの元素を分析し,初期の地球の組成と惑星の酸化還元過程の新たなモデルを示唆した.

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関連する実験動画

Last Updated: May 15, 2026

Laboratory Simulation of an Iron(II)-rich Precambrian Marine Upwelling System to Explore the Growth of Photosynthetic Bacteria
09:45

Laboratory Simulation of an Iron(II)-rich Precambrian Marine Upwelling System to Explore the Growth of Photosynthetic Bacteria

Published on: July 24, 2016

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A Set of In Situ Informed Simulated Medium Formats for Culturing Environmentally Acquired Anaerobic Microorganisms

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科学分野:

  • 地質化学 地質化学
  • 惑星科学は惑星科学である.
  • 高圧鉱物物理 高圧鉱物物理

背景:

  • 地球のマントルの構成,特にシデロファイルの元素の豊富さは,惑星の核形成の歴史に関する重要な洞察を提供します.
  • 以前のモデルでは,原子核の形成は比較的減少条件下で発生し,原子核とマントルの間の元素の分割に影響を与えると示唆されていた.

研究 の 目的:

  • より広い範囲の条件下で,核形成中にシデロフィール元素 (バナジアム,クロミウム,ニッケル,コバルト) の分割行動を調査する.
  • 新しい実験データに基づいて,地球の初期のマグマ海洋と蓄積物質の酸化還元状態を再評価する.

主な方法:

  • 核形成条件をシミュレートする高圧,高温分割実験 (35-74 GPa, 3100-4400 K).
  • 主要な siderophile 要素の金属シリケート分割係数の分析.

主要な成果:

  • マントルのバナジウムとクロームの枯渇は,これまで考えられていたよりもより酸化的な条件下で核の形成によって説明できる.
  • 金属コアにおける酸素の溶解性の向上は,バナジウムとクロムの分割に大きく影響する.
  • これらの発見は,地球の蓄積材料の酸化還元状態に関する以前の仮定に異議を唱える.

結論:

  • 地球は,普通または炭酸塩状のコンドライトのように酸化した物質から蓄積した可能性があります.
  • マントルからコアへの酸素転送は,観測されたマントルのバナジウムとクロムの濃度を,コア組成に関する地球物理学的制約と調和させるための実行可能なメカニズムを提供します.
  • この研究は,初期の地球の化学的進化とコア-マントルの分化に関する私たちの理解を洗練します.