Converting forests into rubber plantations weakened the soil CH<sub>4</sub> sink in tropical uplands

Lang, Rong; Goldberg, Stefanie Daniela; Blagodatsky, Sergey; Piepho, Hans‐Peter; Harrison, Rhett D.; Xu, Jianchu; Cadisch, Georg

doi:10.1002/ldr.3417

Cited by 14 publications

(10 citation statements)

References 58 publications

(90 reference statements)

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“…Our results indicated that land use change from primary forest decreased soil CH 4 oxidation through modifying soil properties. Insufficient air constrained methanotroph activity due to the increase in soil bulk density and soil water filled pore space (Fest, Wardlaw, Livesley, Duff, & Arndt, ; Gutlein, Gerschlauer, Kikoti, & Kiese, ; Lang et al, ). Although there was negative effect of primary forest conversion on soil water holding capacity, illustrated by decreased soil moisture and organic matter, its positive impact on CH 4 oxidation might be overridden by other moderators that constrain CH 4 uptake.…”

Section: Discussionmentioning

confidence: 99%

Changes in soil greenhouse gas fluxes by land use change from primary forest

Han

Zhu

2020

Global Change Biology

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Primary forest conversion is a worldwide serious problem associated with human disturbance and climate change. Land use change from primary forest to plantation, grassland or agricultural land may lead to profound alteration in the emission of soil greenhouse gases (GHG). Here, we conducted a global meta‐analysis concerning the effects of primary forest conversion on soil GHG emissions and explored the potential mechanisms from 101 studies. Our results showed that conversion of primary forest significantly decreased soil CO2 efflux and increased soil CH4 efflux, but had no effect on soil N2O efflux. However, the effect of primary forest conversion on soil GHG emissions was not consistent across different types of land use change. For example, soil CO2 efflux did not respond to the conversion from primary forest to grassland. Soil N2O efflux showed a prominent increase within the initial stage after conversion of primary forest and then decreased over time while the responses of soil CO2 and CH4 effluxes were consistently negative or positive across different elapsed time intervals. Moreover, either within or across all types of primary forest conversion, the response of soil CO2 efflux was mainly moderated by changes in soil microbial biomass carbon and root biomass while the responses of soil N2O and CH4 effluxes were related to the changes in soil nitrate and soil aeration‐related factors (soil water content and bulk density), respectively. Collectively, our findings highlight the significant effects of primary forest conversion on soil GHG emissions, enhance our knowledge on the potential mechanisms driving these effects and improve future models of soil GHG emissions after land use change from primary forest.

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Section: Discussionmentioning

confidence: 99%

Changes in soil greenhouse gas fluxes by land use change from primary forest

Han

Zhu

2020

Global Change Biology

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“…Ray et al [19] found more areas would be suitable for rubber tree plantation in the NE region, whereas further expansion would be limited in the WG region under the projected climate scenario for 2050. Using a statistical regression model (SRM), Lang et al [20] disentangled the links between soil water content, soil texture, and mineral nitrogen in rubber plantations and assessed the impacts of land-use change on methane flux. Land surface models are also increasingly adopted to investigate the impact of land-use change on carbon and energy fluxes at various temporal and spatial scales [21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Implementing a New Rubber Plant Functional Type in the Community Land Model (CLM5) Improves Accuracy of Carbon and Water Flux Estimation

Ali

Fan

Corre

et al. 2022

Land

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Rubber plantations are an economically viable land-use type that occupies large swathes of land in Southeast Asia that have undergone conversion from native forest to intensive plantation forestry. Such land-use change has a strong impact on carbon, energy, and water fluxes in ecosystems, and uncertainties exist in the modeling of future land-use change impacts on these fluxes due to the scarcity of measured data and poor representation of key biogeochemical processes. In this current modeling effort, we utilized the Community Land Model Version 5 (CLM5) to simulate a rubber plant functional type (PFT) by comparing the baseline parameter values of tropical evergreen PFT and tropical deciduous PFT with a newly developed rubber PFT (focused on the parameterization and modification of phenology and allocation processes) based on site-level observations of a rubber clone in Indonesia. We found that the baseline tropical evergreen and baseline tropical deciduous functions and parameterizations in CLM5 poorly simulate the leaf area index, carbon dynamics, and water fluxes of rubber plantations. The newly developed rubber PFT and parametrizations (CLM-rubber) showed that daylength could be used as a universal trigger for defoliation and refoliation of rubber plantations. CLM-rubber was able to predict seasonal patterns of latex yield reasonably well, despite highly variable tapping periods across Southeast Asia. Further, model comparisons indicated that CLM-rubber can simulate carbon and energy fluxes similar to the existing rubber model simulations available in the literature. Our modeling results indicate that CLM-rubber can be applied in Southeast Asia to examine variations in carbon and water fluxes for rubber plantations and assess how rubber-related land-use changes in the tropics feedback to climate through carbon and water cycling.

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“…Whereas the capacity of soil CH 4 uptake increased with the time since land use change under land restoration (Figures 3 and 6f). These results suggested that the capacity of CH 4 oxidation could lose rapidly and recover slowly in response to land degradation and restoration, respectively (Bárcena et al, 2014;Lang et al, 2019;Levine et al, 2011;Petitjean et al, 2019). Land degradation, such as the natural forest converted to plantation or cropland, is always associated with the clear-cutting, fertilization, and other intensive disturbances.…”

Section: Differential Response Of Soil Ch 4 Uptake To Land Degradatmentioning

confidence: 99%

“…Surprisingly, the effect of land degradation on soil CH 4 uptake rate seems to be independent of the time since land use change. For instance, the conversion of natural forest to other land use types can significantly decrease soil CH 4 uptake rate in a very short time interval (less than 10 years; Lang et al., 2019; Petitjean et al., 2019). However, it is unclear whether this phenomenon is common in various terrestrial ecosystems worldwide.…”

Section: Introductionmentioning

confidence: 99%

“…These factors are inevitably influenced by land degradation and restoration. For instance, the natural forest converted to rubber plantations significantly increased the water‐filled pore space (WFPS; Lang et al., 2019), and hence limited the diffusion of atmospheric CH 4 into soils (Lang et al., 2020), ultimately weakened the soil CH 4 sink in the tropical uplands. On the contrary, the conversion of pasture to plantation increased soil CH 4 sink primarily due to the reduced soil water content (Hiltbrunner, Zimmermann, Karbin, Hagedorn, & Niklaus, 2012).…”

Section: Introductionmentioning

confidence: 99%

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Asymmetric response of soil methane uptake rate to land degradation and restoration: Data synthesis

Chen

Jia

et al. 2020

Global Change Biology

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Converting forests into rubber plantations weakened the soil CH₄ sink in tropical uplands

Cited by 14 publications

References 58 publications

Changes in soil greenhouse gas fluxes by land use change from primary forest

Changes in soil greenhouse gas fluxes by land use change from primary forest

Implementing a New Rubber Plant Functional Type in the Community Land Model (CLM5) Improves Accuracy of Carbon and Water Flux Estimation

Asymmetric response of soil methane uptake rate to land degradation and restoration: Data synthesis

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Converting forests into rubber plantations weakened the soil CH4 sink in tropical uplands

Cited by 14 publications

References 58 publications

Changes in soil greenhouse gas fluxes by land use change from primary forest

Changes in soil greenhouse gas fluxes by land use change from primary forest

Implementing a New Rubber Plant Functional Type in the Community Land Model (CLM5) Improves Accuracy of Carbon and Water Flux Estimation

Asymmetric response of soil methane uptake rate to land degradation and restoration: Data synthesis

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Converting forests into rubber plantations weakened the soil CH₄ sink in tropical uplands