A hidden Arctic world: Methane mounds and life found 3.6 km below the Greenland Sea | – The Times of India

Deep down, beneath the icy edges of the Greenland Sea, a remarkable and previously undiscovered geological and biological complex has been found by scientists. The existence of this topographic anomaly deep down in the sea, where light, high pressure, and low temperature are prevalent factors, extends our understanding of what is known about the oceanography of the Arctic. The findings are especially pertinent in light of recent increased scientific interest in the Earth’s poles in relation to increased understanding of global climate processes. The observation of a level of biological and geological interaction in one of the most remote ocean regions on Earth contributes important information on what is known about the physical characteristics of the Arctic.

Why methane hydrate mounds forming deep beneath the Arctic Ocean

The most notable aspect of the discovery is that it consists of a number of gas hydrate mounds along the Molloy Ridge, a tectonic boundary that lies deep beneath the Greenland Sea. A gas hydrate is a molecule that consists of a large amount of trapped methane, all held together with crystalline ice. The existence of these hydrates at a depth of some 3,640 meters is one of the deepest known hydrate formation sites that have been discovered so far. According to the research paper that was published in Nature Communications, high-resolution images that included the extent of these hydrate mounds along the ridge have been discovered with the help of a remotely operated robotic vehicle. Gas hydrates have until now been thought to be largely associated with continental slopes and the shallower margins of the Arctic.

How life survives without sunlight on the Arctic sea floor

The ecologists surrounding the hydrate mountains recorded the existence of a dense population of chemosynthetic organisms. Such organisms receive energy from chemicals instead of sunlight. Based on the fact that the area is lightless, the organisms receive energy from the methane seeping from beneath the seafloor. The organisms form the base of the food chain, in turn supporting other life forms. Scientists recorded tube worms, crustaceans, as well as a dense mat of microbes aggregated in areas surrounding the seeps. The organisms exhibit specific adaptations in order to withstand high pressures as well as near-freezing temperatures. The organisms’ metabolism is specifically attuned in order to take advantage of the methane as well as sulphide compounds seeping from the sediments. The finding shows the existence of life in the deepest parts of the Arctic Ocean utilizing available energy in the area.

What role does the Molloy Ridge play in deep Arctic sea floor processes?

The Molloy Ridge is recognised as one of the deepest mid-ocean ridges in the world and is characterised by tectonic plates that are gradually drifting apart. The tectonic activities in this process result in the creation of cracks and channels in the Earth’s crust that facilitate methane gas to flow from deeper to upper layers. When methane gas reaches lower temperatures close to the ocean floor, it either gets trapped in its hydrate form or seeps out gradually. The process that is observed in this tectonic interaction is directly related to biological activities occurring on the ocean floor. The mid-ocean ridge functions both as a channel and as a supporting structure that determines hydrate and biologically active zones. The process of interaction in this study is very helpful in gaining an understanding of deep-sea ecosystems’ maintenance at a deeper level for extended periods.

What this discovery means for Arctic methane stability

Methane has a crucial role within the carbon cycle, and what happens to methane under the ocean floor is closely tracked because methane can affect the climate. The methane hydrate mounds under the Greenland Sea support a long-term trap that holds methane under stable conditions. At present, the conditions on the Molloy Ridge support a stable environment to retain methane, hindering massive amounts of methane from entering the water body. Still, recognising such systems is critical to predict their reaction to potential warming within the ocean currents or temperatures. The findings provide scientists a chance to observe and measure methane within a system that has been underrepresented within climate models to predict climatic changes. The findings confirm the essence of the deep basins within the Arctic to control carbon beneath the Earth and within the ocean.

Why the deep Arctic Ocean is becoming a focus of scientific research

The discovery of hydrate mounds and their ecosystems in the Greenland Sea is one such finding that showcases the effect that advances in technology are having on deep oceanography. The use of remotely operated vehicles with sophisticated sensors and imaging systems is enabling scientists to explore regions that were hitherto unexplored. With every new expedition, new layers of complexity are being found under the Arctic Ocean, from unexpected topographical features to new ecosystems. The Molloy Ridge finding indicates that perhaps such regions are to be found elsewhere on deep tectonic margins, waiting to be located and studied.Also Read | A step toward time travel? Physicists reverse waves in time