Video taken from the seafloor at 2600m depth, as the multicore lands and takes a sediment sample amount deep sea fauna. Video courtesy of INSPIRE: Chile Margin 2010

Today we are mapping and sampling offshore along the Chile margin, a few hundred miles south of where the recentearthquake occurred. Both here and near the earthquake epicenter, the seafloor deepens steeply where the oceanic Pacific plate sinks (subducts) beneath the continental South American plate. Shifting of these huge tectonic plates caused the earthquake. Deformation and associated landslides at the edge of the continental slope generated the tsunami. 

The sonar system we use for mapping tells us the shape, depth, and something about the character of the seafloor. Each pulse of sound (a ‘ping’) goes from the ship to the seafloor and back. If the seafloor has new sediment on it, some of the energy from the ping is absorbed and only a quiet echo will be heard (and recorded) back at the ship. If the seafloor is hard or steep, a stronger echo will be recorded at the ship. To map deformation and landslides caused by the earthquake and aftershocks, we will look for sharp, curved landslide scarps (strong echos) and for jumbled piles of rock (a mix of strong and weak echos) at the base of the slope. 

This margin (and many around the world) have an additional factor- the presence of methane hydrate frozen within the crust of the slope. Usually the hydrate layer is a few hundred meters below the seafloor and associated fluids/gases percolate up slowly, seeping out in small areas at the seafloor. A large landslide on the slope can break through the hydrate layer and provide a direct ‘escape’ route for the methane. Addtionally, fracturing and vibration due to passing seismic waves from the earthquake could trigger new flow channels within the slope allowing gas to escape.
So, in addition to the sonar data, we will be looking carefully for signals in the water just above the seafloor that could indicate bubbles escaping from new methane emissions. If we do see an area of strong bubble emission and our chemical sensors detect methane we can design a detailed study that the underwater vehicle ABE will conduct. 


Related Links

INSPIRE: Chile Margin 2010

INSPIRE: Chile Margin 2010: February 28 Log

NOAA Ocean Explorer Gallery