Greater soil carbon losses from secondary than old-growth tropical forests
Tropical forests play a crucial role in mediating the global carbon cycle and climate. Southeast Asian tropical forests are experiencing ongoing threats of deforestation and degradation. There is an urgent need to determine how the conversion from primary forest to secondary forest coverage may impa...
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sg-ntu-dr.10356-1731792024-01-22T15:30:42Z Greater soil carbon losses from secondary than old-growth tropical forests Raczka, Nanette Christine Ho, Qian Yi Srinivasan, Vupasana Lee, Ming Yang Ko, Chung-Wing Königer, Madeleine Chua, Terence Binny, Delia Ngo, Kang Min Andersen, Kelly M. Asian School of the Environment Social sciences::Geography Belowground Carbon Dynamics Fine Root Biomass Tropical forests play a crucial role in mediating the global carbon cycle and climate. Southeast Asian tropical forests are experiencing ongoing threats of deforestation and degradation. There is an urgent need to determine how the conversion from primary forest to secondary forest coverage may impact C stocks and cycling. While old-growth forests typically contain larger stores of C aboveground than secondary forests, past research has found varied results for belowground soil C storage and fluxes between tropical forest types. We examined differences in annual soil C efflux in a 2-ha old-growth and an adjacent 2-ha 70-year-old secondary ForestGEO plots in Bukit Timah Nature Reserve in Singapore. We hypothesized that the secondary forest would have greater soil C efflux rates than the old-growth forest and explored several potential drivers of soil C efflux including abiotic and biotic factors such as soil moisture, fine root biomass, and ectomycorrhizal association. We found that the hypothesis was supported, suggesting that belowground carbon dynamics fundamentally differ with forest age. Additionally, we found that fine root biomass was the best predictor of soil C efflux in the secondary forest and soil moisture in the old-growth forest. The difference in soil C efflux between forest types indicates that with continued degradation of old-growth forests in Southeast Asia, conversion of old-growth forests into secondary forests may drive greater C loss from soils even after 70 years of regrowth. Ministry of Education (MOE) Nanyang Technological University Published version This study was funded by the Ministry of Education (MOE) award number 002825-00001 Tier 1 Program and Nanyang Technological University to KMA. 2024-01-16T05:52:45Z 2024-01-16T05:52:45Z 2023 Journal Article Raczka, N. C., Ho, Q. Y., Srinivasan, V., Lee, M. Y., Ko, C., Königer, M., Chua, T., Binny, D., Ngo, K. M. & Andersen, K. M. (2023). Greater soil carbon losses from secondary than old-growth tropical forests. Frontiers in Forests and Global Change, 6, 1135270-. https://dx.doi.org/10.3389/ffgc.2023.1135270 2624-893X https://hdl.handle.net/10356/173179 10.3389/ffgc.2023.1135270 2-s2.0-85174923383 6 1135270 en 002825-00001 Frontiers in Forests and Global Change © 2023 Raczka, Ho, Srinivasan, Lee, Ko, Königer, Chua, Binny, Ngo and Andersen. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms. application/pdf |
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Social sciences::Geography Belowground Carbon Dynamics Fine Root Biomass |
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Social sciences::Geography Belowground Carbon Dynamics Fine Root Biomass Raczka, Nanette Christine Ho, Qian Yi Srinivasan, Vupasana Lee, Ming Yang Ko, Chung-Wing Königer, Madeleine Chua, Terence Binny, Delia Ngo, Kang Min Andersen, Kelly M. Greater soil carbon losses from secondary than old-growth tropical forests |
| description |
Tropical forests play a crucial role in mediating the global carbon cycle and climate. Southeast Asian tropical forests are experiencing ongoing threats of deforestation and degradation. There is an urgent need to determine how the conversion from primary forest to secondary forest coverage may impact C stocks and cycling. While old-growth forests typically contain larger stores of C aboveground than secondary forests, past research has found varied results for belowground soil C storage and fluxes between tropical forest types. We examined differences in annual soil C efflux in a 2-ha old-growth and an adjacent 2-ha 70-year-old secondary ForestGEO plots in Bukit Timah Nature Reserve in Singapore. We hypothesized that the secondary forest would have greater soil C efflux rates than the old-growth forest and explored several potential drivers of soil C efflux including abiotic and biotic factors such as soil moisture, fine root biomass, and ectomycorrhizal association. We found that the hypothesis was supported, suggesting that belowground carbon dynamics fundamentally differ with forest age. Additionally, we found that fine root biomass was the best predictor of soil C efflux in the secondary forest and soil moisture in the old-growth forest. The difference in soil C efflux between forest types indicates that with continued degradation of old-growth forests in Southeast Asia, conversion of old-growth forests into secondary forests may drive greater C loss from soils even after 70 years of regrowth. |
| author2 |
Asian School of the Environment |
| author_facet |
Asian School of the Environment Raczka, Nanette Christine Ho, Qian Yi Srinivasan, Vupasana Lee, Ming Yang Ko, Chung-Wing Königer, Madeleine Chua, Terence Binny, Delia Ngo, Kang Min Andersen, Kelly M. |
| format |
Article |
| author |
Raczka, Nanette Christine Ho, Qian Yi Srinivasan, Vupasana Lee, Ming Yang Ko, Chung-Wing Königer, Madeleine Chua, Terence Binny, Delia Ngo, Kang Min Andersen, Kelly M. |
| author_sort |
Raczka, Nanette Christine |
| title |
Greater soil carbon losses from secondary than old-growth tropical forests |
| title_short |
Greater soil carbon losses from secondary than old-growth tropical forests |
| title_full |
Greater soil carbon losses from secondary than old-growth tropical forests |
| title_fullStr |
Greater soil carbon losses from secondary than old-growth tropical forests |
| title_full_unstemmed |
Greater soil carbon losses from secondary than old-growth tropical forests |
| title_sort |
greater soil carbon losses from secondary than old-growth tropical forests |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/173179 |
| _version_ |
1789483203455614976 |