The terrestrial ecosystems of Qinghai-Tibet Plateau (QTP) are highly sensitive to climate change, yet the magnitude and distribution of the carbon budget for QTP remain quite uncertain. Here, utilizing long short-term memory networks (LSTM), in conjunction with available eddy covariance flux data from recent extensive observation campaigns, multiple satellite land surface data, and observation-based environmental data (e.g., soil organic carbon, SOC), we revisit the regional carbon budget estimation over the QTP with a special focus on investigating the impacts of considering memory effect and incorporating SOC. Our estimate points the QTP region to a mean carbon sink of 20.89 Tg C yr-1 during 2003–2018. Spatially, the major sinks distribute in the western and northern QTP dominated by alpine steppes, while major sources in the eastern QTP dominated by alpine meadows. During the study period, the regional sink declines at the rate of 0.0003 Tg C yr-2, which is primarily contributed by the reduced carbon sink of alpine steppes and the increased carbon source of alpine meadows. We found that considering memory effect and incorporating SOC are critical for estimating the regional carbon budget for QTP. Without considering memory effect leads to a huge carbon source of 161.10 Tg C yr-1, with unreasonable seasonal and interannual variation of carbon budgets. Without incorporating SOC leads to a larger estimated carbon sink (61.94 Tg C yr-1), with clearly overestimated sink in steppes ecosystems and underestimated source in meadows ecosystems. Our study provides new insights into the carbon budget estimation for the QTP region.

Elevated CO 2 generally increases the photosynthetic rate of rice, yet with a tendency for decreased foliar nitrogen (N) concentration at elevated CO 2. The evidence for how photosynthetic N partitioning affect the response of rice to elevated CO 2, however, is still limited. Here in this study, based on the two-years field experiments conducted at free-air CO 2 enrichment (FACE) system and the open-top chambers (OTC), along with a pot experiment with a variety of rice cultivars and the evidence from a global meta-analysis, we aim to investigate the relationship between foliar N allocation strategy and the CO 2 fertilization effect (CFE) of rice. We found that the CFE of rice were highly correlated with the foliar N allocation strategy. The photosynthetic N allocation to both the carboxylation system ( PNcb) and the electron transport system ( PNet) is strongly positively correlated with CFE, with an R 2 of 0.65 for both. This finding is also supported by the results from structural equation model, which further indicates that these two factors jointly determine the CFE of rice. We then able to generate a robust model to predict the CFE of rice on the basis of PNcb and PNet, which showed a 73% confidence level for the global meta-data across 56 experimental sites. Furthermore, this model was also robust and valid for various field N application rates. Our findings thus indicate that the foliar N allocation strategy has a controlling role on regulating the CFE of rice. This study offers a new perspective on understanding rice’s response to climate change and also will be beneficial for accurately projecting global crop yield in the context of future climate change.