Eideard

On the frozen edge of the Kolyma River in northeastern Siberia, in an ancient pantry harboring seeds and other stores, an Arctic ground squirrel burrowed into the dirt and buried a small, dark fruit from a flowering plant. The squirrel’s prize quickly froze in the cold ground and was preserved in permafrost, waiting to grow into a fully fledged flowering plant until it was unearthed again. After 30,000 years, it finally was. Scientists in Russia have now regenerated this Pleistocene plant, transplanting it into a pot in the lab. A year later, it grew forth and bore fruit.

The specimen is distinctly different from the modern-day version of Silene stenophylla, or narrow-leafed Campion. It suggests that the permafrost is a potential new source of ancient gene pools long believed to be extinct, scientists said.

The fruits were buried about 125 feet in undisturbed, never thawed permafrost sediments, nestled at roughly 19.4 degrees F (-7 C). Radiocarbon dating showed the fruits were 31,800 years old, give or take about 300 years. Seeds are incredible things, storing the embryo of a new plant and encasing it in protective material until conditions are right for it to germinate.

Scientists led by David Gilichinsky at the Russian Academy of Sciences worked with three of these fruits and took placental tissue samples. They fed the tissue cultures a cocktail of nutrients to induce root growth, and once the plants were rooted, they were transplanted into pots in a greenhouse. Just as they were supposed to, plants grew, developed flowers and fruits, and went to seed…

All of this is interesting not just because it’s amazing to regenerate a Pleistocene plant, which of course it is, but because the permafrost may be an important new gene pool. Other ancient squirrel burrows have been found in the Yukon territory and in Alaska. That’s interesting for pure research, but also because of what may happen as the planet warms and more permafrost regions thaw. Organisms will be released from their long, cold sleep, and these ancient life forms could become part of modern ecosystems, affecting modern phenotypes and changing the landscape.

Permafrost has long served as a functional deep freeze for animal and vegetable matter reaching back into the last Ice Age. There have been dinners of thawed mammoth for nutball gourmands – and, yes, that brings up the suggestion again of cloning the wooly mammoth in a modern elephant.

Frankly, I’m as interested in the vegetable side of the spectrum of life. It’s more likely to aid in adaptability to climate change – especially since our corporate masters and their flunkies in politics and society seem to have little inclination to respond any useful view of science.

Katey M. Walter Anthony investigating a plume of methane

A bubble rose through a hole in the surface of a frozen lake. It popped, followed by another, and another, as if a pot were somehow boiling in the icy depths.

Every bursting bubble sent up a puff of methane, a powerful greenhouse gas generated beneath the lake from the decay of plant debris. These plants last saw the light of day 30,000 years ago and have been locked in a deep freeze — until now.

“That’s a hot spot,” declared Katey M. Walter Anthony, a leading scientist in studying the escape of methane. A few minutes later, she leaned perilously over the edge of the ice, plunging a bottle into the water to grab a gas sample.

It was another small clue for scientists struggling to understand one of the biggest looming mysteries about the future of the earth.

Read the rest of this entry »

Good thing there’s no permafrost in the United States, eh?

Up to two-thirds of Earth’s permafrost likely will disappear by 2200 as a result of warming temperatures, unleashing vast quantities of carbon into the atmosphere, says a new study by the University of Colorado Boulder’s Cooperative Institute for Research in Environmental Sciences.

The carbon resides in permanently frozen ground that is beginning to thaw in high latitudes from warming temperatures, which will impact not only the climate but also international strategies to reduce fossil fuel emissions, said CU-Boulder’s Kevin Schaefer, lead study author. “If we want to hit a target carbon dioxide concentration, then we have to reduce fossil fuel emissions that much lower than previously thought to account for this additional carbon from the permafrost,” he said. “Otherwise we will end up with a warmer Earth than we want.”

The escaping carbon comes from plant material, primarily roots trapped and frozen in soil during the last glacial period that ended roughly 12,000 years ago, he said. Schaefer, a research associate at CU-Boulder’s National Snow and Ice Data Center, an arm of CIRES, likened the mechanism to storing broccoli in a home freezer. “As long as it stays frozen, it stays stable for many years,” he said. “But if you take it out of the freezer it will thaw out and decay.”

While other studies have shown carbon has begun to leak out of permafrost in Alaska and Siberia, the study by Schaefer and his colleagues is the first to make actual estimates of future carbon release from permafrost…

Schaefer and his team ran multiple Arctic simulations assuming different rates of temperature increases to forecast how much carbon may be released globally from permafrost in the next two centuries. They estimate a release of roughly 190 billion tons of carbon, most of it in the next 100 years…

“The amount we expect to be released by permafrost is equivalent to half of the amount of carbon released since the dawn of the Industrial Age,” said Schaefer. The amount of carbon predicted for release between now and 2200 is about one-fifth of the total amount of carbon in the atmosphere today, according to the study…

Greater reductions in fossil fuel emissions to account for carbon released by the permafrost will be a daunting global challenge, Schaefer said. “The problem is getting more and more difficult all the time,” he said. “It is hard enough to reduce the emissions in any case, but now we have to reduce emissions even more. We think it is important to get that message out now.”

Using importance and science in the same sentence won’t mean much to politicians, pundits – or the pipsqueaks who prance around at the behest of fossil fuel profiteers. And the average consumer isn’t as likely to be impressed by computational analysis as how much their pocketbook is being squeezed for fuel oil and gasoline.

Fortunately, the Oil Patch Boys and their bubbas in the Middle east are doing a reasonably effective job of the last-named activity.

Coastal collapse as permafrost melts, Point Barrow, Alaska

Scientists have recorded a massive spike in the amount of a powerful greenhouse gas seeping from Arctic permafrost, in a discovery that highlights the risks of a dangerous climate tipping point…

The discovery follows a string of reports from the region in recent years that previously frozen boggy soils are melting and releasing methane in greater quantities. Such Arctic soils currently lock away billions of tonnes of methane, a far more potent greenhouse gas than carbon dioxide, leading some scientists to describe melting permafrost as a ticking time bomb that could overwhelm efforts to tackle climate change…

Paul Palmer, a scientist at Edinburgh University who worked on the new study, said: “High latitude wetlands are currently only a small source of methane but for these emissions to increase by a third in just five years is very significant. It shows that even a relatively small amount of warming can cause a large increase in the amount of methane emissions.”

Global warming is occuring twice as fast in the Arctic than anywhere else on Earth. Some regions have already warmed by 2.5C, and temperatures there are projected to increase by more than 10C by 2100 if carbon emissions continue to rise at current rates.

Palmer said: “This study does not show the Arctic has passed a tipping point, but it should open people’s eyes. It shows there is a positive feedback and that higher temperatures bring higher emissions and faster warming…”

The new study, published in the journal Science, shows that methane emissions from the Arctic increased by 31% from 2003-07. The increase represents about 1 million extra tonnes of methane each year. Palmer cautioned that the five-year increase was too short to call a definitive trend.

When I first began studying and debating climate change a number of years ago, it seemed clear to me right from the start that changes in permafrost were going to be critical. You don’t eliminate a phenomenon that took millennia to produce in a short period of time – with no hope of restoration – without unbalancing a number of systems.