TY - JOUR
T1 - Spatial and temporal dynamics of 20th century carbon storage and emissions after wildfire in an old-growth forest landscape
AU - Harris, Lucas B.
AU - Scholl, Andrew E.
AU - Young, Amanda B.
AU - Estes, Becky L.
AU - Taylor, Alan H.
N1 - Funding Information:
Initial field data collection was supported by a Joint Fire Science Program Grant ( 01-3-3-12 ) and additional support was provided by an E.W. and Ruby S. Miller Distinguished Graduate Fellowship from the Penn State Department of Geography. We thank Region 5 of the US Forest Service for their support and Reed Crane and Cody Grout for their assistance in conducting fieldwork. We also thank Matthew Hurteau and two anonymous reviewers for their valuble comments on earlier versions of the manuscript.
Funding Information:
Initial field data collection was supported by a Joint Fire Science Program Grant (01-3-3-12) and additional support was provided by an E.W. and Ruby S. Miller Distinguished Graduate Fellowship from the Penn State Department of Geography. We thank Region 5 of the US Forest Service for their support and Reed Crane and Cody Grout for their assistance in conducting fieldwork. We also thank Matthew Hurteau and two anonymous reviewers for their valuble comments on earlier versions of the manuscript.
Publisher Copyright:
© 2019 Elsevier B.V.
PY - 2019/10/1
Y1 - 2019/10/1
N2 - Both fire exclusion and subsequent wildfires have strongly affected carbon storage in fire-prone dry forests, with implications for how carbon storage will change in the future. Using a reconstruction of forest structure in 1899 and pre- and post-fire field data, we quantified changes in carbon stocks in a 2125-ha old-growth mixed conifer forest landscape over a century of fire exclusion and emissions due to a 2013 wildfire. From 1899 to 2002 aboveground carbon storage in live trees increased 2.5-fold from 97 Mg/ha to 263 Mg/ha. Despite burning in an uncharacteristically severe wildfire, the forest still contained 169 Mg/ha of live aboveground tree carbon in 2014. Direct fire emissions were 72 Mg/ha and did not vary with canopy cover loss because emissions were largely driven by consumption of accumulated surface fuels. Areas that burned at low, moderate and high severity in the wildfire contained similar amounts of carbon in 1899, when the forest was still experiencing frequent low severity fire. By 2002 the low severity areas contained 80 and 86 Mg/ha more aboveground live tree carbon than moderate and high severity areas respectively. The wildfire reinforced and amplified these differences in carbon storage that arose during fire exclusion, such that carbon storage following the wildfire was more variable across the landscape. Additionally, the proportion of carbon stored in shade-intolerant, more fire-sensitive species increased. These changes in where and in what tree species carbon is stored, due to the combination of fire exclusion and wildfire, have implications for the potential future stability of these carbon stocks.
AB - Both fire exclusion and subsequent wildfires have strongly affected carbon storage in fire-prone dry forests, with implications for how carbon storage will change in the future. Using a reconstruction of forest structure in 1899 and pre- and post-fire field data, we quantified changes in carbon stocks in a 2125-ha old-growth mixed conifer forest landscape over a century of fire exclusion and emissions due to a 2013 wildfire. From 1899 to 2002 aboveground carbon storage in live trees increased 2.5-fold from 97 Mg/ha to 263 Mg/ha. Despite burning in an uncharacteristically severe wildfire, the forest still contained 169 Mg/ha of live aboveground tree carbon in 2014. Direct fire emissions were 72 Mg/ha and did not vary with canopy cover loss because emissions were largely driven by consumption of accumulated surface fuels. Areas that burned at low, moderate and high severity in the wildfire contained similar amounts of carbon in 1899, when the forest was still experiencing frequent low severity fire. By 2002 the low severity areas contained 80 and 86 Mg/ha more aboveground live tree carbon than moderate and high severity areas respectively. The wildfire reinforced and amplified these differences in carbon storage that arose during fire exclusion, such that carbon storage following the wildfire was more variable across the landscape. Additionally, the proportion of carbon stored in shade-intolerant, more fire-sensitive species increased. These changes in where and in what tree species carbon is stored, due to the combination of fire exclusion and wildfire, have implications for the potential future stability of these carbon stocks.
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U2 - 10.1016/j.foreco.2019.117461
DO - 10.1016/j.foreco.2019.117461
M3 - Article
AN - SCOPUS:85069660744
SN - 0378-1127
VL - 449
JO - Forest Ecology and Management
JF - Forest Ecology and Management
M1 - 117461
ER -