海洋生物矿物：多金属结核和结壳的前景与挑战

Marine biominerals: perspectives and challenges for polymetallic nodules and crusts.

作者信息

Wang Xiaohong, Müller Werner E G

机构信息

National Research Center for Geoanalysis, 26 Baiwanzhuang Dajie, CHN-100037 Beijing, China.

出版信息

Trends Biotechnol. 2009 Jun;27(6):375-83. doi: 10.1016/j.tibtech.2009.03.004. Epub 2009 May 4.

DOI:10.1016/j.tibtech.2009.03.004

PMID:19409632

Abstract

Deep sea minerals in polymetallic nodules, crusts and hydrothermal vents are not only formed by mineralization but also by biologically driven processes involving microorganisms (biomineralization). Within the nodules, free-living and biofilm-forming bacteria provide the matrix for manganese deposition, and in cobalt-rich crusts, coccolithophores represent the dominant organisms that act as bio-seeds for an initial manganese deposition. These (bio)minerals are economically important: manganese is an important alloying component and cobalt forms part of special steels in addition to being used, along with other rare metals, in plasma screens, hard-disk magnets and hybrid car motors. Recent progress in our understanding of the participation of the organic matrices in the enrichment of these metals might provide the basis for feasibility studies of biotechnological applications.

摘要

多金属结核、结壳和热液喷口中的深海矿物不仅通过矿化作用形成，还通过涉及微生物的生物驱动过程（生物矿化作用）形成。在结核内部，自由生活和形成生物膜的细菌为锰的沉积提供了基质，而在富钴结壳中，颗石藻是作为初始锰沉积生物种子的主要生物。这些（生物）矿物具有重要的经济价值：锰是一种重要的合金成分，钴除了与其他稀有金属一起用于等离子屏幕、硬盘磁体和混合动力汽车发动机外，还是特殊钢的组成部分。我们在理解有机基质参与这些金属富集方面的最新进展可能为生物技术应用的可行性研究提供基础。

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海洋生物矿物：多金属结核和结壳的前景与挑战

Marine biominerals: perspectives and challenges for polymetallic nodules and crusts.

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