Incorporation of NPP into forest CH4 efflux models
Forest soils are the largest atmospheric methane (CH4) sinks in terrestrial ecosystems, but models simulating this uptake have considerable uncertainties. Soil organic matter derived from aboveground vegetation net primary productivity (NPP) significantly influences CH4 uptake; therefore, we propose...
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description | Forest soils are the largest atmospheric methane (CH4) sinks in terrestrial ecosystems, but models simulating this uptake have considerable uncertainties. Soil organic matter derived from aboveground vegetation net primary productivity (NPP) significantly influences CH4 uptake; therefore, we propose that the incorporation of NPP into global CH4 uptake models will greatly improve model predictions. |
doi_str_mv | 10.1016/j.tplants.2021.09.007 |
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subjects | Atmospheric models CH4 oxidation potential CH4 production potential CH4 uptake Efflux Environment models forest ecosystem Forest soils Life Sciences & Biomedicine Methane Net Primary Productivity Organic matter Organic soils Plant Sciences Science & Technology Soil organic matter Terrestrial ecosystems Terrestrial environments |
title | Incorporation of NPP into forest CH4 efflux models |
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