Charcoal remains could accelerate CO2 emissions after forest fires
Charcoal remains after a forest fire help decompose fine roots in the soil, potentially accelerating CO2 emissions in boreal forests.
Boreal forests are a huge carbon sink. The fine roots, not only the leaves, stems and branches of trees, largely contribute to carbon accumulation. The Russian Far East has had an increasing number of forest fires, many of which are believed to be caused by global warming and human activities. Burning trees in forest fires naturally cause the emission of CO2, but little is known about the extent to which fire-derived charcoal influences ecosystem processes, such as soil organic matter decomposition.
The researchers, including Russian Academy of Science Senior Researcher Semyon Bryanin and Hokkaido University Assistant Professor Makoto Kobayashi, performed field litterbag experiments over 515 days, incubating fine larch roots with varying concentrations of charcoal in the soil. Mass loss of fine roots was measured in each of four conditions over nearly two years: control (no charcoal); mean charcoal content measured in the field; twice the mean charcoal content measured in the field; and charcoal content equal to the maximum concentration in the field.
According to the results, charcoal had little effect on the decomposition of fine roots right after they were buried in soil. But at the end of the experiment, the loss of root mass in samples incubated with higher concentrations of charcoal was greater (double content: 40 percent; maximum content: 42 percent) than in the control (30 percent) and the average content conditions (27 percent). "Our study has provided the first field evidence that fire-derived charcoal might accelerate the decomposition of fine larch roots and consequently CO2 emissions from boreal forest," says Makoto Kobayashi.
The finding likely will help predict future changes in CO2 concentration in the atmosphere should more forest fires be triggered by global warming and human activities.