A surprising finding: stromatolites in the deep sea

environmentdeep seastromatoliteschemosynthesismarine microorganisms
The investigated dome-shaped limestone deposit at 734 meters water depth; photo taken by the diving robot "MARUM-QUEST"
(c) MARUM – Zentrum für Marine Umweltwissenschaften, Universität Bremen

Research team discovers fossils at 730 meters depth With an age of 3.5 million years, stromatolites are among the oldest fossils. However, lime deposits have so far occurred only in shallow seas with water depths of up to ten meters. Because the limescale deposits can only grow if light-dependent and photosynthetic microorganisms are involved. A new study by geoscientists shows that using light-independent, chemosynthetic microbes, stromatolites can also grow on the ocean floor in 731 meters of water. Bremen geoscientists discovered in an expedition in the Arabian Sea off the coast of Pakistan dome-shaped microbial mats at methane outcrops in 730 meters of water. With the help of the gripper arm of diving robot "MARUM-QUEST 4000" they were able to recover a calcareous dome approximately 40 centimeters high. Inside, the team found finely laminated and arched limestone structures originally covered by microbial mats. These microbes were examined more accurately at MARUM geochemically. The result: methane-degrading marine microorganisms, the archaea, are involved in the construction of the so-called stromatolites. The Greek origin of the name already hides the form of limestone hills: the ancient Greek stroma stands for ceiling, lithos for stone. "Unlike the microsynthetic microbes that live in the shallow sea, which extract energy for their metabolism from the sun's rays, these microbes use energy generated in the extraction of methane in the deep ocean. In the dark, they operate chemosynthesis," says MARUM's Gerhard Bohrmann. Bacteria living on the seabed transform the hydrogen sulfide that is produced during methane decomposition. "We were able to identify the fiber bundles of these sulfide-oxidizing bacteria in thin sections under the microscope," reports Dr. med. Tobias Himmler from MARUM, first author of the study. "How these bundles are received is extraordinary. Since the bacteria in the Arabian Sea have hardly any free oxygen at this depth, they probably use nitrate instead of oxygen, which promotes calcification," adds Prof. Dr. med. Jörn Peckmann from the University of Hamburg. Their assumption corroborates a geochemical model that confirms calcification through the chemosynthesis-based metabolism of microbes. From this, the researchers conclude that unlike the previously known photosynthetic microbes also light-independent chemosynthesis based microbes can build up stromatolites - even in the deep sea. Stromatolites are the most common fossils in rock formations older than 541 million years. Similar to today's Arabian Sea, in the oceans before that time, in the so-called Precambrian, there was little oxygen in the water. The discovery of chemosynthesis-based stromatolites in the Arabian Sea provides new insights into how these ancient fossils might have originated. "Until now, only photosynthesis-based stromatolites were known, for example from the Bahamas or Shark Bay on the west coast of Australia. In contrast to the chemosynthesis-based stromatolites, these differ in structure and their internal structure from many Precambrian stromatolites," explains Tobias Himmler. The researchers therefore speculate that chemosynthesis has contributed more than previously thought to the growth of stromatolites in the Precambrian region more than 541 million years ago. More information: www.marum.de Link to the study: pubs.geoscienceworld.org//stromatolites-below-the-photic-zone

The microbial mats bulge at the gas outlets. They are involved in the construction of the dome-like stromatolites
(c) MARUM – Zentrum für Marine Umweltwissenschaften, Universität Bremen

Tento článek byl automaticky přeložen a může obsahovat drobné nepřesnosti; v případě pochybností se podívejte na originální anglickou verzi.

další

mares
Medical Clearance for Scuba Diving: What Divers Need to Know
AI KB

Lékařské osvědčení pro potápění s přístrojem: Co potápěči potřebují vědět

Lékařské potvrzení o způsobilosti k potápění pomáhá Scuba Diverům s astmatem, cukrovkou, vysokým krevním tlakem nebo jinými již existujícími zdravotními problémy plánovat bezpečnější ponory.

Před 1 dnem
mares
How To Plan Stress-Free International Dive Trips
AI KB

Jak naplánovat bezstresové mezinárodní potápěčské výlety

Plánujete mezinárodní potápěčské výlety? Zjistěte, jak se připravit, sbalit si věci, vybrat destinace, zajistit logistiku a vyhnout se běžným chybám, abyste si potápěčskou dovolenou užili bez stresu.

Před 3 dny
predrag_vuckovic
Is Scuba Diving Dangerous? Safe Scuba Diving During Your First SSI Course
AI KB

Je potápění s přístrojem nebezpečné? Bezpečné potápění během vašeho prvního kurzu SSI

Je potápění nebezpečné? Zjistěte, jak SSI výcvik, bezpečné potápěčské návyky, kontroly s parťákem a pojištění DiveAssure pomáhají novým Scuba Diverům cítit se připraveni.

Před 5 dny
mares
Technical Diving Training: Is It Right for You? A Full Guide
AI KB

Výcvik technického potápění: Je to pro vás to pravé? Kompletní průvodce

Uvažujete o výcviku technického potápění? Seznamte se s dovednostmi, vybavením a základními bezpečnostními pravidly, které potřebujete, a zjistěte, jak vám SSI Extended Range výcvik pomůže začít.

Před 7 dny
Adam-Moore
Save Our Oceans: 5 Inspiring Divers Making a Difference
AI KB

Zachraňme naše oceány: 5 inspirativních potápěčů, kteří mění svět k lepšímu

Seznamte se s pěti inspirativními potápěči, kteří se snaží zachránit naše oceány prostřednictvím vyprávění příběhů, ochrany oceánů, freedivingu, ochrany oceánů a iniciativy SSI Blue Oceans.

Před 9 dny