AGL 40.20 Decreased By ▼ -1.30 (-3.13%)
AIRLINK 129.11 Increased By ▲ 1.11 (0.87%)
BOP 6.60 Increased By ▲ 0.34 (5.43%)
CNERGY 4.03 Decreased By ▼ -0.10 (-2.42%)
DCL 8.45 Increased By ▲ 0.01 (0.12%)
DFML 41.25 Increased By ▲ 0.56 (1.38%)
DGKC 87.00 Decreased By ▼ -0.90 (-1.02%)
FCCL 33.35 Decreased By ▼ -0.75 (-2.2%)
FFBL 65.90 Decreased By ▼ -0.43 (-0.65%)
FFL 10.54 Decreased By ▼ -0.02 (-0.19%)
HUBC 110.70 Increased By ▲ 2.00 (1.84%)
HUMNL 15.23 Increased By ▲ 0.77 (5.33%)
KEL 4.78 Increased By ▲ 0.13 (2.8%)
KOSM 7.83 Increased By ▲ 0.50 (6.82%)
MLCF 41.90 Decreased By ▼ -0.82 (-1.92%)
NBP 60.50 Decreased By ▼ -0.34 (-0.56%)
OGDC 182.80 Increased By ▲ 3.83 (2.14%)
PAEL 25.36 Decreased By ▼ -0.34 (-1.32%)
PIBTL 6.26 Increased By ▲ 0.20 (3.3%)
PPL 147.81 Increased By ▲ 1.66 (1.14%)
PRL 24.56 Decreased By ▼ -0.35 (-1.41%)
PTC 16.24 Increased By ▲ 0.10 (0.62%)
SEARL 70.50 Increased By ▲ 0.30 (0.43%)
TELE 7.30 Increased By ▲ 0.08 (1.11%)
TOMCL 36.30 Increased By ▲ 0.10 (0.28%)
TPLP 7.85 Increased By ▲ 0.01 (0.13%)
TREET 15.30 Decreased By ▼ -0.29 (-1.86%)
TRG 51.70 Increased By ▲ 1.34 (2.66%)
UNITY 27.35 Increased By ▲ 0.45 (1.67%)
WTL 1.23 Decreased By ▼ -0.01 (-0.81%)
BR100 9,842 Increased By 47.4 (0.48%)
BR30 30,036 Increased By 389.6 (1.31%)
KSE100 92,520 Increased By 499.1 (0.54%)
KSE30 28,786 Increased By 121.7 (0.42%)

A new research from ancient sediment cores has indicated that a warming climate could make the world's arctic tundra far more susceptible to fires than previously thought.
Carried out by Montana State University post-doctoral researcher Philip Higuera and his team, the research is important given the potential for tundra fires to release organic carbon - which could add significantly to the amount of greenhouse gases already blamed for global warming, BBC radio reported. For the research, Higuera and his co-authors examined ancient sediments from four lakes in a remote region of Alaska in and around Gates of the Arctic National Park to determine what kind of vegetation existed in the area after the last ice age, 14,000 to 9,000 years ago.
By looking at fossilized pollen grains in the sediment cores, Higuera and his co-authors determined that after the last ice age, the arctic tundra was very different from what it is now. Instead of being covered with grasses, herbs, and short shrubs, it was covered with vast expanses of tall birch shrubs. Charcoal preserved in the sediment cores also showed evidence that those shrub expanses burned frequently.
This was a surprise," said Higuera. "Modern tundra burns so infrequently that we don't really have a good idea of how often tundra can burn. Best estimates for the most flammable tundra regions are that it burns once every 250-plus years," he added.
The ancient sediment cores showed the shrub tundra burned as frequently as modern boreal forests in Alaska - every 140 years on average, but with some fires spaced only 30 years apart. Higuera's research is important because other evidence indicates that as the climate has warmed in the past 50 to 100 years, shrubs have expanded across the world's tundra regions.
There is evidence of increasing shrub biomass in modern tundra ecosystems, and we expect temperatures to continue to increase and overall moisture levels to decrease. Combine these two factors and it suggests a greater potential for fires," Higuera said. "The sediment cores indicate that it's happened before." The world's high latitude tundra and boreal forest ecosystems contain roughly 30 percent of the planet's total soil carbon.
Currently, much of the carbon is locked in permafrost. But a warming climate could cause the permafrost to melt and release its carbon stores into the atmosphere where it would contribute to the greenhouse effect. Vegetation change through an increase in shrub biomass and more frequent burning will change a great deal of the carbon cycle in these high latitudes," said Higuera.

Copyright Associated Press of Pakistan, 2008

Comments

Comments are closed.