Geobiology

For the scientific journal, see Geobiology (journal).

Broadly defined, geobiology is an interdisciplinary field of scientific research that explores interactions between the biosphere and the lithosphere and/or the atmosphere.[1]

Major geobiological events

Perhaps the most profound geobiological event is the introduction of oxygen into the atmosphere by photosynthetic bacteria. This oxygenation of Earth's primoidial atmosphere (the so-called oxygen catastrophe) resulted in the precipitation of banded-iron rock formations.

A subsequent major change was the establishment of terrestrial plant life, which affected continental erosion and changed the types of rivers observed, allowing channelization of what were previously predominantly braided rivers.

More subtle geobiological events include the role of termites in overturning sediments, coral reefs in depositing calcium carbonate and breaking waves, sponges in absorbing dissolved marine silica, the role of dinosaurs in breaching river levees and promoting flooding, and the role of large mammal dung in distributing nutrients.[2][3]

Subdisciplines

Astrobiology

Another related area of research is astrobiology, an interdisciplinary field that uses a combination of geobiological and planetary science data to establish a context for the search for life on other planets.

Geomicrobiology

One major subdiscipline of geobiology is geomicrobiology, an area of study that focuses on investigating the interactions between microbes and minerals.

Biogeomorphology

Main article: Biogeomorphology

Biogeophysics

Main article: Biogeophysics

Bioremediation

One example of geobiological research in a modern context is the study of bacteria that "breathe" metals such as manganese and uranium. These organisms use metals as terminal electron acceptors in the same way that animals use oxygen. These processes hold promise as tools for environmental bioremediation.

See also

References

  1. Dilek, Yildirim; Harald Furnes; Karlis Muehlenbachs (2008). Links Between Geological Processes, Microbial Activities & Evolution of Life. Springer. p. v. ISBN 1-4020-8305-X.
  2. Doughty, C. E.; Wolf, A.; Malhi, Y. (2013). "The legacy of the Pleistocene megafauna extinctions on nutrient availability in Amazonia". Nature Geoscience 6 (9): 761. doi:10.1038/ngeo1895.
  3. Butterfield, N. J. (2011). "Animals and the invention of the Phanerozoic Earth system". Trends in Ecology & Evolution 26 (2): 81–87. doi:10.1016/j.tree.2010.11.012.

External links

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