Millennial Scale Change From Lake El’gygytgyn, NE Russia: Did We Step Or Leap Out Of The Warm Pliocene Into The Pleistocene?

43rd International Arctic Workshop, Amherst, Mass., March 11-13, 2014

Julie Brigham-Grette¹, Martin Melles², Pavel Minyuk³, and the El'gygytgyn Science Team⁴

¹University of Massachusetts, Amherst
²University of Cologne
³NEISRI-RAS Magadan
⁴USA, Germany, Russia

The Pliocene-Pleistocene climate evolution of the Arctic must have modulated the glacial history of Greenland and the onset of Northern Hemisphere glaciation. What is known from the terrestrial stratigraphy of Arctic climate change comes from sites that are spatially and temporally fragmented. In 2009, International Continental Deep Drilling at Lake El’gygytgyn (67^o 30' N, 172^o 05' E) recovered lacustrine sediments dating back to 3.58 Ma that provide the first time-continuous Pliocene-Pleistocene Arctic paleoclimate record of alternating glacial-interglacial change. The warmest/wettest Pliocene interval of the lake record occurs from ~3.58-3.34 Ma and is dominated by exceptional tree pollen implying July temperatures nearly 7-8 ^oC warmer than today, with nearly ~3 times the annual precipitation. Atmospheric CO2 levels are estimated to have been 360-400 ppm implying exceptionally high climate sensitivity and polar amplification. In fact, pollen spectra and modern analog analysis show an unbroken persistence of summers much warmer and wetter than the last interglacial, MIS 5e until nearly 2.2 Ma. Extreme warmth in the Mid Pliocene Arctic occurs at the same time ANDRILL results suggest the West Antarctic Ice Sheet was non-existent.

Using physical, chemical, and biological proxies we find pronounced glacial episodes commenced ~2.6 Ma ago, but the full range of typical Pleistocene glacial/interglacial change was not established until ~1.8 Ma ago. Greenland must have also responded to numerous “super interglacials” during the Quaternary record, with maximum summer temperatures and annual precipitation, especially during MIS 9, 11 and 31, at Lake El’gygytgyn exceeding that documented for MIS 5e. The correspondence of many of these super-interglacials with retreat of the West Antarctic Ice Sheet (Naish et al. 2009) could coincide with intervals when the Greenland Ice was reduced in size. The climate record from Lake El’gygytgyn, especially the history of past interglacials, provides a fresh means of testing the evolving magnitude of polar amplification over time, and the sensitivity of the Greenland Ice Sheet to extreme warmth in the rest of the Arctic.

Brigham-Grette, J., Melles, M., Minyuk, P., Andreev, A., Tarasov, P., DeConto, R., Koenig, S., Nowaczyk, N., Wennrich, V., Rosén, P., Haltia-Hovi, E., Cook, T., Gebhardt, T., Meyer-Jacob, C., Snyder, J., Herzschuh, U.  Pliocene warmth, extreme polar amplification, and stepped Pleistocene cooling recorded in NE Russia. Submitted to Science, 21 November 2012; in revision March 2013.

Melles, M., Brigham-Grette, J., Minyuk, P., and others. 2012. 2.8 Million Years of Arctic Climate Change from Lake El’gygytgyn, NE Russia. Science, 337, 315-320.

Naish, T. et al., 2009. Obliquity-paced Pliocene West Antarctic ice sheet oscillations. Nature, 458, 322-328.

See also Climate of the Past, special issue on Lake El’gygytgyn, 20+ manuscripts.

http://instaar.colorado.edu/meetings/AW2013/abstract_details.php?abstract_id=78

David Pollard & Robert M. DeConto, Nature, 458, Modelling West Antarctic ice sheet growth and collapse through the past five million years

Nature 458, 329-332 (19 March 2009) | doi:10.1038/nature07809

Modelling West Antarctic ice sheet growth and collapse through the past five million years

David Pollard* (Earth and Environmental Systems Institute, Pennsylvania State University, University Park, PA 16802, U.S.A.) and Robert M. DeConto (Department of Geosciences, University of Massachusetts, Amherst, MA 01003, U.S.A.)

Received 12 August 2008, accepted 8 January 2009.

Abstract

The West Antarctic ice sheet (WAIS), with ice volume equivalent to 5 m of sea level¹, has long been considered capable of past and future catastrophic collapse^{2, 3, 4}. Today, the ice sheet is fringed by vulnerable floating ice shelves that buttress the fast flow of inland ice streams. Grounding lines are several hundred metres below sea level and the bed deepens upstream, raising the prospect of runaway retreat^{3, 5}. Projections of future WAIS behaviour have been hampered by limited understanding of past variations and their underlying forcing mechanisms^{6, 7}. Its variation since the Last Glacial Maximum is best known, with grounding lines advancing to the continental-shelf edges around 15 kyr ago before retreating to near-modern locations by 3 kyr ago⁸. Prior collapses during the warmth of the early Pliocene epoch⁹ and some Pleistocene interglacials have been suggested indirectly from records of sea level and deep-sea-core isotopes, and by the discovery of open-ocean diatoms in subglacial sediments¹⁰. Until now¹¹, however, little direct evidence of such behaviour has been available. Here we use a combined ice sheet/ice shelf model¹² capable of high-resolution nesting with a new treatment of grounding-line dynamics and ice-shelf buttressing⁵ to simulate Antarctic ice sheet variations over the past 5 million years. Modelled WAIS variations range from full glacial extents with grounding lines near the continental shelf break, intermediate states similar to modern, and brief but dramatic retreats, leaving only small, isolated ice caps on West Antarctic islands. Transitions between glacial, intermediate and collapsed states are relatively rapid, taking one to several thousand years. Our simulation is in good agreement with a new sediment record (ANDRILL AND-1B) recovered from the western Ross Sea¹¹, indicating a long-term trend from more frequently collapsed to more glaciated states, dominant 40-kyr cyclicity in the Pliocene, and major retreats at marine isotope stage 31 ( 1.07 Myr ago) and other super-interglacials.

*Correspondence and requests for materials, e-mail: pollard@essc.psu.edu.

Link to abstract: http://www.nature.com/nature/journal/v458/n7236/abs/nature07809.html

R. DeConto, D. Pollard, D. Harwood, D. MacAyeal, C. Fielding, S. Sandroni, T. Naish, R. Alley: ANDRILL shows WAIS could collapse within 100 years

Driller thriller: Antarctica's tumultuous past revealed

by Douglas Fox, NewScientist, Issue 2703, April 13, 2009

THE midnight sun hangs low in the sky on this November evening. A plain of flat ice sweeps in all directions and mountains rise in the distance. Perched on the sea ice is a massive, teepee-shaped tent. A mechanised rumble emanates from within.

Inside the tent, men in hard hats tend a rotating shaft of steel. This drill turns day and night through 8 m of sea ice covering the surface of McMurdo Sound, off the coast of Antarctica, and through 400 m of water beneath it and into the seabed.

It's not oil these men are drilling for, but another precious resource -- historical perspective that could help us to predict the future of sea level rise. Welcome to the Antarctic Geological Drilling project, or Andrill.

This international team is extracting two columns of stone from the sea floor. A few kilometres away, scientists at McMurdo Station, a U.S. research base, work 24 hours a day to analyse them. The cores of stone are providing them with a record peering 19 million years into Antarctica's history.

We know that Antarctica froze 35 million years ago, when its detachment from South America unleashed a circumpolar ocean current that isolated it from warmer parts of the world. What we do not know is whether its ice sheets have stayed frozen or melted and reformed many times since then.

It is an urgent question. Understanding how Antarctica's ice responded to past climate swings will help us to predict how it will react as temperatures rise in the coming decades. The mighty ice sheet covering West Antarctica could unleash enough water to raise sea levels by 5 m were it to melt.

Andrill's results reveal a breathtaking picture. They show how the West Antarctic ice sheet has collapsed and regrown at least 60 times in the past few million years. Andrill predicts that it could once again tip toward collapse by the year 2100.

The West Antarctic ice sheet has collapsed and regrown over 60 times in the past few million years

"There seems to be a lot more variability in the ice sheet than anyone pictured," says Robert DeConto, a glaciologist at the University of Massachusetts Amherst. "That's what's so exciting about this. But it's also kind of scary."

Other ocean cores have been extracted from hundreds, and thousands, of miles north of here. They trace past changes in sea level by measuring ratios of oxygen isotopes in the layers of the cores. Since the ice sheets preferentially incorporate water molecules containing oxygen-16, spikes in the rock layers' oxygen-16:oxygen-18 ratio pinpoint episodes when disintegrating ice sheets injected meltwater into the oceans.

Readings of these isotopic tea leaves reveal many spikes in sea level, from 5-30 m. But no one has figured out where on the meltwater fuelling any given spike came from -- whether Antarctica, Greenland, or any of the other ice sheets that have sprawled over parts of Asia, North America and Europe.

That's why Andrill's record may be the most convincing. "What's unique is that we're drilling right next to the ice sheets," says David Harwood, a palaeoecologist at the University of Nebraska-Lincoln and a founding member of the Andrill project. "So we can see the sea level come and go and we can see the ice sheets advance and retreat."

The two Andrill cores come from a pair of holes drilled near the edge of a slab of floating ice called the Ross ice shelf, which hangs off the edge of Antarctica and bobs atop the Southern Ocean (see map).

If you want to reconstruct the history of West Antarctica, then the Ross ice shelf is a good place to start. It is the largest ice shelf on Earth, about the size of Spain and up to 700 m thick in places. Five massive glaciers that flow off the edge of West Antarctica, 800 km south of here, ooze into the Ross ice shelf, which buttresses the glaciers' flow and slows their tumble into the ocean. West Antarctica's ice sheet simply could not survive for long without the Ross and several other ice shelves stabilising its edges, says Douglas MacAyeal, a glaciologist at the University of Chicago. By drilling into the seabed here, the Andrill team believes they can reconstruct West Antarctica's history.

Antarctica's ice sheet is really two sheets that join together like a giant figure eight. Glaciologists have good reason to believe that the smaller West Antarctic ice sheet is especially vulnerable to collapse. Most of the ice here slides across land that sits below sea level, at depths of 2000 metres in some locations. Without its ice, West Antarctica would appear on maps not as a substantial body of land but as an archipelago.

The ice sheet's exposure to warming ocean currents means that parts of West Antarctica are already melting from underneath. Satellite surveys show it sweating 130 km³ of its ice per year, while East Antarctica's ice sits high, dry, and largely intact.

Last year I visited McMurdo Station and dropped in on the stratigraphy lab, where scientists work around the clock analysing the Andrill cores. Sunlight slants in through the windows of the lab at 2 a.m., creating a false impression of late afternoon. Sections of the core a little narrower than a telegraph pole lie end-to-end on tables and half a dozen scientists are pouring over them.

"We do about 30 metres of core each night," says Chris Fielding of the University of Nebraska, Lincoln. A new batch of core arrives here every night at 10:30 p.m., by helicopter.

For the next 2 hours I watch the night shift work. Fielding inches his way along the core, recording in his notebook the alternating layers of gravel conglomerate, mudstone and diatomite, a stone rich in the fossilied shells of marine micro-organisms called diatoms. Layers of diatomite indicate times when the Ross ice shelf had retreated far away, allowing the ocean to teem with life. Gravelly conglomerates laid down on top of these layers show debris swept in by advancing glaciers, and a higher layer of diatomite shows the Ross ice shelf has once again retreated.

Around 3 a.m., Fielding looks up from the core, rubs his eyes, and says: "When I close my eyes I see conglomerate. After a long time, everything you see turns to conglomerate."

At another table Sonia Sandroni, a petrologist with the University of Siena in Italy, sketches pictures in her notebook of marble-sized rocks suspended in the fossilised mud of the core: red pencil for granite, blue pencil for sandstone, and so on.

She has sketched 30,000 rocks this past month. Many are "dropstones," carried by the ice shelf from hundreds of kilometres away and then plunked on the sea floor as icebergs calve off the ice shelf and melt. Sandroni and her colleagues match the minerals in these rocks to the places in Antarctica where they originated to provide a record of how patterns of glacial flow have changed over time.

Stones from far away indicate a robust Ross ice shelf channelling the flow of distant glaciers toward the drill sites. Stones from nearby indicate an absence of the Ross ice shelf. And a total absence of dropstones reveals times when the glaciers retreated so far they no longer calved icebergs into the ocean.

Other scientists in the room catalogue fossils of shells, worms, and tiny amoeboid creatures called foraminifers. Identifying the species reveals not only the prevailing climates when the critters lived, but also how much sea ice covered the ocean.

The scientists work till morning. At 8:30 a.m., Fielding presents a slide show of photographed fossils and stripy sediment layers from last night's core to two dozen freshly awakened scientists. He departs for dinner and bed, leaving the day shift to examine the core until evening. At 10:30 p.m. another 30 metres of core will arrive and the cycle will begin anew until the team has examined all 1100 metres.

Shape of things to come

The Andrill team has focused on a period of time called the Pliocene, from 5 million to 2 million years ago. The 2007 report from the Intergovernmental Panel on Climate Change cites the Pliocene as an important analogue to climates that Earth might see as it warms in the coming decades. Global temperatures during that time peaked at 3-5 °C warmer than today -- temperatures that the IPCC predicts could return by the year 2100. That warmth was driven by higher levels of carbon dioxide in the atmosphere.

Harwood, Fielding and 50 other scientists have detailed their findings from this critical period in a paper in Nature last month (Vol. 458, p. 322). The cores show at least 60 cycles of glacial collapse, retreat, and re-advance during the last 14 million years, with 40 of them occurring during the early Pliocene. "It was spectacular," says Timothy Naish of Victoria University of Wellington in New Zealand and Andrill's scientific director. "To see the physical evidence for what we had suspected from other information was pretty exciting."

The big deglaciations seen by Andrill also line up with rises and falls in sea level read from ocean cores drilled in other parts of the world. Together the results show that expansions and collapses of the West Antarctic ice sheet really were helping to drive changes in sea level.

But most striking of all is a 60-m segment of deep green diatomite in the core, laid down 4 million years ago. This shows the Ross Sea continuously free of an ice shelf and brimming with life for 200,000 years.

Compare the climate conditions of the Pliocene with those predicted for the next few decades and the implications are unmistakable. "We know that CO₂ was around 400 or 450 parts per million in the atmosphere, and there was no ice sheet on West Antarctica," says Naish. "That's where we're almost at now. So it's a really important window into what we'll be facing in the next 100 years."

The results are significant when you consider the IPCC's latest report, published in 2007. Depending on the future climate scenario, the IPCC predicted sea level rises between 18 and 59 centimetres by 2100 -- with Antarctic melting contributing little or nothing to those amounts. But these estimates omit some huge factors. While they predict increased snowfall in Antarctica, they fail to account for an opposing effect: the increased loss of ice that could result from glaciers accelerating as their ice-shelf buffers around the edges of West Antarctica collapse.

The IPCC sidestepped these issues because the ice sheet models they would have used to calculate such effects had proved unreliable. They successfully predicted snow fall and surface melting on ice sheets. However, they failed to predict factors such as warming ocean currents, thought to underlie the recent thinning of ice shelves and accelerations in ice loss observed since about 2000 in parts of Greenland and parts of West Antarctica.

Richard Alley is a glaciologist at Pennsylvania State University in University Park who helped write the IPCC section on sea level rise. Those older models' biggest weakness, he says, "is this business of warm water getting at the edge of the ice sheet and triggering changes that propagate inward."

Andrill will help fill this gap, says Alley. Climate scientists validate their models by showing that they can reproduce what's seen in palaeo-records drilled from sea floors and ice sheets. DeConto and David Pollard of Pennsylvania State University are now using Andrill's record to do the same with a model that predicts ice sheet changes.

Their model of Antarctica's ice sheets includes forces that most other models leave out, such as underside melting by ocean currents and rapid acceleration and thinning of glaciers when ice shelves collapse. In a Nature paper last month, they show that their model successfully reproduces the sequence of ice sheet collapses and expansions seen over the last 5 million years in the Andrill cores (Vol. 458, p. 332).

They'll soon run their model into the future and they expect it to predict more rapid ice loss than previous models have. "I think that the numbers over the next 100 years or so are going to raise a few eyebrows," DeConto warns.

According to the Andrill cores, each collapse of the West Antarctic ice sheet happened over 1000 to 3000 years, seemingly placing any crisis far into the future. But even that slow collapse could translate into 10-50 cm of sea level rise per century. Combine that with increased ice loss from Greenland and the sea level could rise to 50-100 cm by 2100 -- the same amount predicted by another group at a climate change conference in Copenhagen last month.

To someone standing atop an ice shelf, the mischief that ocean currents are inflicting on its underside seems a world away. One day during my McMurdo Station stay, a group of us drives far out onto the Ross ice shelf for an overnight survival course. The ice shelf that we eat, sleep, and wield our ice axes upon seems as sturdy as bedrock. But if Andrill is right, the Ross ice shelf and West Antarctic's ice sheet are nowhere near as timeless as they seem.

Link to article: http://www.newscientist.com/article/mg20227036.400-driller-thriller-antarcticas-tumultuous-past-revealed.html