Friday, April 30, 2010

Massive South Atlantic Current Discovered






Again we are learning just how badly that the three dimensional ocean current structure needs to be both mapped in decent detail and also continuously monitored.  Variation must occur and we have no idea.

 

I have already argued that a minor adjustment in the flow of warm surface water into the Arctic over the past fifty years is sufficient to account for everything we know about the past couple of decades of hemispheric warming, presently confused with global warming.

 

We presently are unable to identify the mechanism behind this change.  It appears likely to be a simple yet subtle alteration in the subsea current geometry.  I am encouraged in this line by the reality of the Gulf Stream having been two degrees warmer during the Bronze Age.

 

I notice that folks are now making the same linkage and recognizing that we possibly have it all backwards.  It is Arctic warming rather than global warming.

 

Massive Southern Ocean current discovered

Apr 27, 2010
In a paper published today in Nature Geoscience, the researchers described the current – more than three kilometres below the Ocean's surface – as an important pathway in a global network of ocean currents that influence climate patterns.
"The current carries dense, oxygen-rich water that sinks near Antarctica to the deep ocean basins further north," says co-author Dr Steve Rintoul from the Antarctic Climate and Ecosystems CRC and CSIRO's Wealth from Oceans Flagship.
"Without this supply of Antarctic water, the deepest levels of the ocean would have little oxygen.
"The ocean influences climate by storing and transporting heat and carbon dioxide – the more the ocean stores, the slower the rate of climate change. The deep current along the Kerguelen Plateau is part of a global system of ocean currents called the overturning circulation, which determines how much heat and carbon the ocean can soak up."
While earlier expeditions had detected evidence of the current system, they were not able to determine how much water the current carried. The joint Japanese–Australian experiment deployed current-meter moorings anchored to the sea floor at depths of up to 4500 m. Each mooring reached from the sea floor to a depth of 1000 m and measured current speed, temperature and salinity for a two-year period.
"The continuous measurements provided by the moorings allow us, for the first time, to determine how much water the deep current carries to the north," Dr Rintoul said. The current was found to carry more than 12 million cubic metres per second of Antarctic water colder than 0 °C (because of the salt dissolved in sea water, the ocean does not freeze until the temperature gets close to –2 °C).
"It was a real surprise to see how strong the flow was at this location. With two-year average speeds of more than 20 cm per second, these are the strongest mean currents ever measured at depths three kilometres below the sea surface.
"Mapping the deep current systems is an important step in understanding the global network of ocean currents that influence climate, now and in the future. Our results show that the deep currents near the Kerguelen Plateau make a large contribution to this global ocean circulation," Dr Rintoul said.
Antarctic waters carried northward by the deep currents eventually fill the deep layers of eastern Indian and Pacific Oceans.

A deep ocean current with a volume equivalent to 40 Amazon Rivers has been discovered by Japanese and Australian scientists near the Kerguelen plateau, in the Indian Ocean sector of the Southern Ocean, 4,200 kilometres south-west of Perth. 
In a paper published today in Nature Geoscience, the researchers described the current –more than three kilometres below the Ocean’s surface – as an important pathway in a global network of ocean currents that influence climate patterns.

'The current carries dense, oxygen-rich water that sinks near Antarctica to the deep ocean basins further north,' says co-author Dr Steve Rintoul from the Antarctic Climate and Ecosystems CRC and CSIRO’s Wealth from Oceans Flagship.

'Without this supply of Antarctic water, the deepest levels of the ocean would have little oxygen.'

'The ocean influences climate by storing and transporting heat and carbon dioxide – the more the ocean stores, the slower the rate of climate change. The deep current along the Kerguelen Plateau is part of a global system of ocean currents called the overturning circulation, which determines how much heat and carbon the ocean can soak up.'

While earlier expeditions had detected evidence of the current system, they were not able to determine how much water the current carried. The joint Japanese-Australian experiment deployed current-meter moorings anchored to the sea floor at depths of up to 4500m. Each mooring reached from the sea floor to a depth of 1000m and measured current speed, temperature and salinity for a two-year period.

'The continuous measurements provided by the moorings allow us, for the first time, to determine how much water the deep current carries to the north,' Dr Rintoul said. The current was found to carry more than 12 million cubic metres per second of Antarctic water colder than 0 °C (because of the salt dissolved in sea water, the ocean does not freeze until the temperature gets close to -2 °C).

'It was a real surprise to see how strong the flow was at this location. With two-year average speeds of more than 20cm per second, these are the strongest mean currents ever measured at depths three kilometres below the sea surface.'

'Mapping the deep current systems is an important step in understanding the global network of ocean currents that influence climate, now and in the future. Our results show that the deep currents near the Kerguelen Plateau make a large contribution to this global ocean circulation,' Dr Rintoul said.

Antarctic waters carried northward by the deep currents eventually fill the deep layers of eastern Indian and Pacific Oceans.

The research team included scientists from the Institute of Low Temperature Science (ILTS) at Hokkaido University in Japan, the Centre for Australian Weather and Climate Research, the Antarctic Climate and Ecosystems Cooperative Research Centre and the Wealth from Oceans National Research Flagship. Funding support was provided by the Australian Climate Change Science Program, the Cooperative Research Centre Program and logistics support from the Australian Antarctic Division. The lead author of the paper is Dr Yasushi Fukamachi, from the ILTS.