The following is a re-post from the Antarctic folder at, which I like because is provides both paleo-evidence of high Arctic Amplification (which is currently being cut roughly in half by aerosols from Asia) from Lake Elgygytgn in Russia; and also the Inter-hemispheric climate couple showing that SLR form Antarctica can increase the water deep in the Bering Strait sufficiently to allow warm water from the Pacific Ocean to flow into the Arctic Ocean (thus decreasing Arctic Sea Ice):
http://forum.arctic-sea-ice.net/index.php/topic,130.msg27687/topicseen.html#msg27687"The following link leads to the University of Alaska Fairbank's website focused on Lake Elgygytgn research, and the extract following the link is from an article Posted on February 4th, 2014 by Laura Nielsen on "Inter-hemispheric climate coupling". The extract emphasizes that in the paleo-past the Antarctic generally responded more quickly to orbital induced solar insolation variations, and that repeatedly paleo-collapses of the WAIS resulted in subsequent Arctic amplification, due both to changes in ocean currents, and to increases in sea level pushing more warm Pacific water through the Bering St. into the Arctic Ocean. If the WAIS collapses this century, we may soon see a marked increase in Arctic amplification:
http://frontierscientists.com/tag/lake-elgygytgyn/Extract: "Antarctica and the Arctic
Climate at the North and South pole are connected. Sediment records from Antarctica show that the West Antarctic ice sheet melted at various times in history. Following many of those events, the Arctic warmed. These recurring intervals of paired warming show that climate in the two hemispheres is linked – it’s called inter-hemispheric climate coupling.
“When the West Antarctic ice sheet pulls back we see a corresponding warmth in the high lattitudes again, probably affecting the size of the Greenland ice sheet with major implications for changes in sea level,” says Julie Brigham-Grette. “Our results mesh with what glaciologists are seeing today. Seven of the 12 major ice shelves around the Antarctic are melting or are gone. We suspect the tipping point for the gradual de-glaciation of Greenland and the Arctic may be lower than glaciologists once thought.”
Complex systems
Earth is a complicated place. We can’t explain past warming using only orbital dynamics or levels of Carbon Dioxide. Scientists affiliated with the project outlined some past events that might explain the rapid warming the sediment records show occurred in both Antarctica and the Arctic around similar times.
When you imagine Antarctica, the picture includes large ice shelves that hang off the rocky edge of the ice-covered continent. Normally that ice keeps nearby ocean water very cold. The cold water travels along currents toward the north Pacific where it wells up to the surface. Ocean circulation can be affected, though. If Antarctic ice sheets disintegrate or melt away, they no longer enforce cold water currents that journey to the Arctic. Instead, surface ocean waters in the Arctic become warmer.
When Antarctica’s ice sheets disintegrate the ocean gains more water and sea levels rise globally. The Bering Strait usually restricts how much warm surface water approaches the Arctic from the south, but higher sea levels would mean warm surface water didn’t have to squeeze through such a narrow space, letting more warm water past the Bering Strait into the Arctic Ocean.
Either way, a warmer ocean means higher temperatures and more rainfall for the Arctic, which impacts paleoclimatology and sea ice history. Grasping the climate connections between the hemispheres gives us insight into our near future.""
Furthermore, I decided to add the four attached paleo plots for your general information. The first image by Hansen & Sato compares modern global mean surface temperature with those for over the past 0.8 million years.
The second compare the rate of modern global mean surface temperature raise to that during the PETM (showing that we are way faster now by about a factor of 100 times).
The third image compares the CMIP5 Arctic Sea Ice projections vs observed through 2012 (note that I believe that the 2013 CMIP5 projections err on the side of least drama).
The fourth shows the results of a GCM projection of the estimated timing of acceleration of ocean heat content from the flow of warm Atlantic current into the Arctic Ocean following a BAU pathway.
