TY - JOUR
T1 - Tropical peat composition may provide a negative feedback on fire occurrence and severity
AU - Crawford, Alastair J.
AU - Belcher, Claire M.
AU - New, Stacey
AU - Gallego-Sala, Angela
AU - Swindles, Graeme T.
AU - Page, Susan
AU - Blyakharchuk, Tatiana A.
AU - Cadillo-Quiroz, Hinsby
AU - Charman, Dan J.
AU - Gałka, Mariusz
AU - Hughes, Paul D.M.
AU - Lähteenoja, Outi
AU - Mauquoy, Dmitri
AU - Roland, Thomas P.
AU - Väliranta, Minna
PY - 2024/8/27
Y1 - 2024/8/27
N2 - Loss of peat through increased burning will have major impacts on the global carbon cycle. In a normal hydrological state, the risk of fire propagation is largely controlled by peat bulk density and moisture content. However, where humans have interfered with the moisture status of peat either via drainage, or indirectly via climate change, we hypothesise that its botanical composition will become important to flammability, such that peats from different latitudes might have different compositionally-driven susceptibility to ignition. We use pyrolysis combustion flow calorimetry to determine the temperature of maximum thermal decomposition (Tmax) of peats from different latitudes, and couple this to a botanical composition analysis. We find that tropical peat has higher Tmax than other regions, likely on account of its higher wood content which appears to convey a greater resistance to ignition. This resistance also increases with depth, which means that loss of surface peat in tropical regions may lead to a reduction in the subsequent ignitability of deeper peat layers as they are exposed, potentially resulting in a negative feedback on increased fire occurrence and severity.
AB - Loss of peat through increased burning will have major impacts on the global carbon cycle. In a normal hydrological state, the risk of fire propagation is largely controlled by peat bulk density and moisture content. However, where humans have interfered with the moisture status of peat either via drainage, or indirectly via climate change, we hypothesise that its botanical composition will become important to flammability, such that peats from different latitudes might have different compositionally-driven susceptibility to ignition. We use pyrolysis combustion flow calorimetry to determine the temperature of maximum thermal decomposition (Tmax) of peats from different latitudes, and couple this to a botanical composition analysis. We find that tropical peat has higher Tmax than other regions, likely on account of its higher wood content which appears to convey a greater resistance to ignition. This resistance also increases with depth, which means that loss of surface peat in tropical regions may lead to a reduction in the subsequent ignitability of deeper peat layers as they are exposed, potentially resulting in a negative feedback on increased fire occurrence and severity.
KW - Tropical peat composition
KW - peat
KW - fire
KW - fire occurrence
U2 - 10.1038/s41467-024-50916-7
DO - 10.1038/s41467-024-50916-7
M3 - Article
C2 - 39191729
AN - SCOPUS:85202154270
SN - 2041-1723
VL - 15
JO - Nature Communications
JF - Nature Communications
M1 - 7363
ER -