TY - JOUR
T1 - Large contribution of recent photosynthate to soil respiration in tropical dipterocarp forest revealed by girdling
AU - Nottingham, Andrew T.
AU - Cheesman, Alexander W.
AU - Riutta, Terhi
AU - Doughty, Christopher E.
AU - Telford, Elizabeth
AU - Huaraca Huasco, Walter
AU - Svátek, Martin
AU - Kvasnica, Jakub
AU - Majalap, Noreen
AU - Malhi, Yadvinder
AU - Meir, Patrick
AU - Arn Teh, Yit
N1 - Funding Information:
This study is a product of the BALI consortium, part of the UK Natural Environment Research Council (NERC) Human modified tropical forests program and part of the Stability of Altered Forest Ecosystem (SAFE) Project, funded by the Sime Darby Foundation. The study was led using support from the NERC, grant numbers NE/K01627X/1 and NE/G018278/1 to P.M. M.S. was funded by a grant from the Ministry of Education, Youth and Sports of the Czech Republic (grant number INTER‐TRANSFER LTT19018). A.T.N. was supported by the NERC, grant NE/T012226. We would like to acknowledge Dr. Rob Ewers for his role in setting up the SAFE experiment, Laura Kruitbos for logistical support, Elelia Nahun, Dg Ku Shamirah binti Pg Bakar, Unding Jami, Ryan Gray, Rostin Jantan, Suhaini Patik and Rohid Kailoh and the BALI and Lombok project research assistants for their contributions to the field campaign. We thank Bernadus Bala Ola, MinSheng Khoo and Magat bin Japar for tree species identification. Royal Society South East Asia Rainforest Research Partnership (SEARRP), Sabah Foundation, Benta Wawasan, the State Secretary, Sabah Chief Minister's Departments, Sabah Forestry Department, Sabah Biodiversity Centre (access permit reference: JKM/MBS.1000‐2/2 JLD.4 (3)), and the Economic Planning Unit are acknowledged for their support and access to the sites.
Funding Information:
This study is a product of the BALI consortium, part of the UK Natural Environment Research Council (NERC) Human modified tropical forests program and part of the Stability of Altered Forest Ecosystem (SAFE) Project, funded by the Sime Darby Foundation. The study was led using support from the NERC, grant numbers NE/K01627X/1 and NE/G018278/1 to P.M. M.S. was funded by a grant from the Ministry of Education, Youth and Sports of the Czech Republic (grant number INTER-TRANSFER LTT19018). A.T.N. was supported by the NERC, grant NE/T012226. We would like to acknowledge Dr. Rob Ewers for his role in setting up the SAFE experiment, Laura Kruitbos for logistical support, Elelia Nahun, Dg Ku Shamirah binti Pg Bakar, Unding Jami, Ryan Gray, Rostin Jantan, Suhaini Patik and Rohid Kailoh and the BALI and Lombok project research assistants for their contributions to the field campaign. We thank Bernadus Bala Ola, MinSheng Khoo and Magat bin Japar for tree species identification. Royal Society South East Asia Rainforest Research Partnership (SEARRP), Sabah Foundation, Benta Wawasan, the State Secretary, Sabah Chief Minister's Departments, Sabah Forestry Department, Sabah Biodiversity Centre (access permit reference: JKM/MBS.1000-2/2 JLD.4 (3)), and the Economic Planning Unit are acknowledged for their support and access to the sites.
Publisher Copyright:
© 2021 British Ecological Society
PY - 2022/2/9
Y1 - 2022/2/9
N2 - Tropical forests are the most productive terrestrial ecosystems, fixing over 40 Pg of carbon from the atmosphere each year. A substantial portion of this carbon is allocated below-ground to roots and root-associated micro-organisms. However, there have been very few empirical studies on the dynamics of this below ground transfer, especially in tropical forests where carbon allocation processes are influenced by high plant species diversity. We used a whole-stand girdling experiment to halt the below-ground transfer of recent photosynthates in a lowland tropical forest in Borneo. By girdling 209 large trees in a 0.48 ha plot, we determined: (a) the contribution of recent photosynthate to root-rhizosphere respiration and; (b) the relationships among the disruption of this below-ground carbon supply, tree species composition and mortality. Mortality of the 209 trees was 62% after 370 days, with large variation among species and particularly high mortality within the Dipterocarpaceae (99%) and Fagaceae (100%) families. We also observed a higher risk of mortality following girdling for species with lower wood density. Soil CO
2 emissions declined markedly (36 ± 5%) over ~50 days following girdling in three of six monitored subplots. In the other three subplots there was either a marginal decline or no response of soil CO
2 emissions to girdling. The decrease in soil CO
2 efflux was larger in subplots with dominance of Dipterocarpaceae. Synthesis. Our results indicate high spatial variation in the coupling of below-ground carbon allocation and root-rhizosphere respiration in this tropical forest, with a closer coupling in forest dominated by Dipterocarpaceae. Our findings highlight the implications of tree species composition of tropical forests in affecting the dynamics of below-ground carbon transfer and its release to the atmosphere.
AB - Tropical forests are the most productive terrestrial ecosystems, fixing over 40 Pg of carbon from the atmosphere each year. A substantial portion of this carbon is allocated below-ground to roots and root-associated micro-organisms. However, there have been very few empirical studies on the dynamics of this below ground transfer, especially in tropical forests where carbon allocation processes are influenced by high plant species diversity. We used a whole-stand girdling experiment to halt the below-ground transfer of recent photosynthates in a lowland tropical forest in Borneo. By girdling 209 large trees in a 0.48 ha plot, we determined: (a) the contribution of recent photosynthate to root-rhizosphere respiration and; (b) the relationships among the disruption of this below-ground carbon supply, tree species composition and mortality. Mortality of the 209 trees was 62% after 370 days, with large variation among species and particularly high mortality within the Dipterocarpaceae (99%) and Fagaceae (100%) families. We also observed a higher risk of mortality following girdling for species with lower wood density. Soil CO
2 emissions declined markedly (36 ± 5%) over ~50 days following girdling in three of six monitored subplots. In the other three subplots there was either a marginal decline or no response of soil CO
2 emissions to girdling. The decrease in soil CO
2 efflux was larger in subplots with dominance of Dipterocarpaceae. Synthesis. Our results indicate high spatial variation in the coupling of below-ground carbon allocation and root-rhizosphere respiration in this tropical forest, with a closer coupling in forest dominated by Dipterocarpaceae. Our findings highlight the implications of tree species composition of tropical forests in affecting the dynamics of below-ground carbon transfer and its release to the atmosphere.
KW - SAFE project
KW - autotrophic respiration
KW - below-ground carbon allocation
KW - heterotrophic respiration
KW - plant–soil interactions
KW - soil CO efflux
KW - terrestrial carbon cycle
KW - tree mortality
U2 - 10.1111/1365-2745.13806
DO - 10.1111/1365-2745.13806
M3 - Article
SN - 0022-0477
VL - 110
SP - 387
EP - 403
JO - Journal of Ecology
JF - Journal of Ecology
IS - 2
ER -