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Web edition: February 25, 2013
Print edition: April 6, 2013; Vol.183 #7 (p. 10)
A stalagmite’s past may help reveal Earth’s future. By studying Siberian cave formations as old as 500,000 years, researchers have found that even moderate climate warming may set off significant thawing of permafrost.
If such extensive thawing of frozen soil occurred today, it could trigger a massive release of greenhouse gases, scientists report online February 21 in Science. Permafrost locks in huge amounts of carbon, so if the frozen ground thaws, much of the carbon could convert to carbon dioxide and methane and boost global warming.
During an era with average temperatures just 1.5 degrees Celsius warmer than preindustrial times, permafrost melted in areas that today are frozen year-round, the researchers report. Alarmingly, this melting came with a change in climate less than the 2 degrees that the United Nations has set as a target for averting catastrophic effects of warming, says Ted Schuur of the University of Florida, Gainesville, who was not involved in the study.
The new research, he says, is the first to shed light on permafrost from hundreds of thousands of years ago. “It's nice to look back in the past and see what's already happened on the Earth, and that gives us some confidence about our future predictions,” Schuur says.
Researchers can use soil and ice to calculate the age of existing — but not past — permafrost.
Anton Vaks of the University of Oxford and an international team probed what happened to permafrost in warmer climates long ago by studying speleothems, ancient cave formations that include stalactites on cave ceilings and stalagmites on cave floors. These formations grow as mineral-laden water seeps into caves. In areas with permafrost, that only happens when the climate is warm enough to cause thawing, the researchers say. So determining the age of speleothem layers gave the researchers an indirect way to study ancient thawing permafrost.
Vaks and his team sampled speleothems from six caves along a path from northern Siberia south to the Gobi Desert. They dated layers going back 500,000 years by measuring the amounts of certain radioactive elements within the layers.
In nearly all of the warm periods studied, layers grew on speleothems in areas that today have partial permafrost cover, the researchers found. During the warmest period studied, some 400,000 years ago, global temperature was 1.5 degrees higher than in preindustrial times. Only during that period did speleothems grow in the cave farthest to the north.
That suggests that 1.5 degrees of warming was enough to thaw permafrost even in areas that are fully covered today. And the finding implies the same could happen in the future, says George Kling of the University of Michigan in Ann Arbor. “Our challenge is to predict how much and how fast the carbon currently frozen in permafrost will enter the atmosphere,” he says.
Vladimir Romanovsky of the University of Alaska Fairbanks praises the study but warns against generalizing its findings to permafrost in other regions of the globe, noting that the method has some uncertainty. “Permafrost could be only one of the possible causes of growing or not growing of speleothems.” One possibility is that fractures in still-frozen permafrost could allow water to seep through, he says.
Another concern is that the method the researchers used might not detect partial thawing. If that had happened, water may not have reached caves, and speleothems would not have grown, Romanovsky says. But even partial thawing could change the climate, he warns, by turning previously locked-up carbon into greenhouse gases.
Citations
Vaks et al. Speleothems Reveal 500,000-Year History of Siberian Permafrost. Science Express. doi: 10.1126/science.1228729. [Go to]
Suggested Reading
S. Perkins. Not-So-Perma Frost. Science News. Vol.171, March 10, 2007, p. 154. Available online: [Go to]
S. Perkins. For past climate clues, ask a stalag-mite. Science News. Vol. 160, July 8, 2001, p. 55. Available online: [Go to]
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CO2 is a trace gas in the atmosphere and plants are starved for it. Luckily, when the planet warms and thaws, more of it is released to provide nutrition to grow more plant life on newly exposed land. Today, we have massive forests growing on land that, just a few thousand years ago, was covered by glaciers.
A visit to New York's Central Park allows examination of the rocks ground and sculpted by the mile-thick glacier that, in very recent history, ground along the Hudson valley. Enjoy a day on the green lawns and be thankful a modest warming cycle has made it possible.
CO2 is the primary terrestrial driver of global warming, and is thus primary driver of another greenhouse gas, atmospheric water vapor. The warmer the Earth becomes, the more water vapor the atmosphere will hold. If there were no CO2 in the atmosphere, the atmosphere would cool, thus reducing the amount of water vapor in the atmosphere and leading to additional cooling.
Humans have been pumping ever increased the amount of CO2 in the environment over the last 150 years or so through the combustion of fossil fuels. Most of that production has come since the first quarter of the last century. Oceans have absorbed much of the CO2 that humans have produced, but what has not been absorbed by the oceans has remained in the atmosphere. The result of additional CO2 in the oceans is a 30% increase in ocean acidity. The atmospheric CO2 generated by humans accounts for 42% of the Earth's current atmospheric CO2 content. It is this additional CO2 in the atmosphere that is driving the current rapid global warming that the Earth is experiencing.
Atmospheric CO2 levels are increasing rapidly, having gone up 3/4 of a percent in just the last year. The fact that CO2 levels are rising rapidly is evidence that plants are not capable of using all of the additional CO2 humans are dumping into the atmosphere. Projections of future fossil fuel combustion indicate that CO2 levels will continue to climb dramatically. The first doubling of CO2 in the atmosphere will have taken in the neighborhood of 200 years. The next doubling will take place in less than 100 years. This geometric progression means that even in the face of the logarithmic energy requirement to drive the heating of atmospheric CO2, the temperature increase on Earth will be linear -- a steadily rising trend.
The "modest warming cycle" is not modest and it is rising rapidly. Within the next century, Earth's temperature will have risen between 5 and 11 degrees Fahrenheit. Such a dramatic temperature rise will raise the sea level and cause environmental changes that will impinge upon the Earth's habitability for human beings.
Enjoy your visit to Central Park today. In the future it may not be available for you to visit. Think about the future and take steps to reduce your carbon footprint so that we might be able to preserve the nice parks and beaches that we can visit today.
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