The paleoclimatic footprint in the soil carbon stock of the Tibetan permafrost region

Ding, Jinzhi; Wang, Tao; Piao, Shilong; Smith, Pete; Zhang, Gan‐Lin; Yan, Zhengjie; Ren, Shuai; Liú, Dan; Wang, Shiping; Chen, Shengyun; Dai, Fuqiang; He, Jin‐Sheng; Li, Yingnian; Liu, Yongwen; Mao, Jiafu; Arain, A. M.; Tian, Hanqin; Shi, Xiaoying; Yang, Yuanhe; Zeng, Ning; Zhao, Lin

doi:10.1038/s41467-019-12214-5

Cited by 52 publications

(43 citation statements)

References 57 publications

(83 reference statements)

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“…We estimated the spatial distribution of the Q 10 values by using the moving window method. Specifically, we took the 2D 0 scale (21 × 21 pixels) as the size of the window (Feng et al 2018, Ding et al 2019. Within each window, the calculation of the Q 10 value was performed when at least 20 k values were available within the 21 × 21 pixels.…”

Section: Predicted Spatial Distribution Of the Q 10 Valuementioning

confidence: 99%

Temperature sensitivity of plant litter decomposition rate in China's forests

Zhang

Feng²,

Song

et al. 2021

Ecosphere

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The decomposition of litter from forest tree species is a fundamental process in the carbon (C) cycle of terrestrial ecosystems and is closely related to ongoing climate change. However, the spatial distribution of the forest litter decomposition rate (k) and its potential response to changing air temperature (temperature sensitivity) remain poorly understood. Here, we estimated the spatial pattern of forest plant k values in China by performing a random forest model based on 433 standardized k values from 124 published studies. Nine potential predictors, including climate-related factors, vegetation characteristics, and soil physical and chemical factors, were considered in the model. The results of spatial extrapolation indicated that the average k value for China's forests was 0.53, and the mean annual temperature (MAT) was the most important factor. We also mapped the spatial pattern of the temperature sensitivity of the k value (Q 10 ) by using a moving window method. We found that the Q 10 values had considerable variation (from 0.05 to 11.68, 95% confidence interval, CI) across forest types and regions. The Q 10 values were lower in the warmer regions (primarily in the sub-tropical evergreen forests) and higher in the semi-humid regions (primarily in the temperate deciduous forests and boreal Larix forests) than those in the other regions of China. However, the Q 10 values of the broadleaved forests were higher than those of coniferous forests. These results suggest that the temperature sensitivity of the litter decomposition rate will decline under the ongoing global warming. Changing patterns of precipitation will also affect not only the forest litter decomposition rate but also its temperature sensitivity.

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Section: Predicted Spatial Distribution Of the Q 10 Valuementioning

confidence: 99%

Temperature sensitivity of plant litter decomposition rate in China's forests

Zhang

Feng²,

Song

et al. 2021

Ecosphere

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“…In the past few decades, permafrost in the Third Pole region has experienced obvious degradation (Mu et al, 2020b;Ran et al, 2018;Turetsky et al, 2019;Wu et al, 2012). Permafrost degradation will not only cause serious geological disasters and affect engineering construction in cold areas, but it will also accelerate the decomposition of the huge SOC pool stored in permafrost (Cheng and Wu, 2007;Cheng et al, 2019;Ding et al, 2021). Moreover, it will emit a large amount of greenhouse gases into the atmosphere, thus increasing the rate of climate change in the future (Schuur et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

A 1 km resolution soil organic carbon dataset for frozen ground in the Third Pole

Wang

Zhao

et al. 2021

Earth Syst. Sci. Data

Self Cite

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Abstract. Soil organic carbon (SOC) is very important in the vulnerable ecological environment of the Third Pole; however, data regarding the spatial distribution of SOC are still scarce and uncertain. Based on multiple environmental variables and soil profile data from 458 pits (depth of 0–1 m) and 114 cores (depth of 0–3 m), this study uses a machine-learning approach to evaluate the SOC storage and spatial distribution at a depth interval of 0–3 m in the frozen ground area of the Third Pole region. Our results showed that SOC stocks (SOCSs) exhibited a decreasing spatial pattern from the southeast towards the northwest. The estimated SOC storage in the upper 3 m of the soil profile was 46.18 Pg for an area of 3.27×106 km2, which included 21.69 and 24.49 Pg for areas of permafrost and seasonally frozen ground, respectively. Our results provide information on the storage and patterns of SOCSs at a 1 km resolution for areas of frozen ground in the Third Pole region, thus providing a scientific basis for future studies pertaining to Earth system models. The dataset is open-access and available at https://doi.org/10.5281/zenodo.4293454 (Wang et al., 2020).

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“…However, we estimate that alpine permafrost zones outside the circumarctic contain 83.2 Gt SOC (Table 20). This estimate includes SOC in global mountain permafrost (IPCC, 2019) and an updated estimate of SOC in the top 3 m of the Tibetan Plateau (36.6 Gt C; Ding et al, 2019). We note that 46 percent of this Tibetan C is estimated to be in permafrost.…”

Section: Global Carbon Stocks and Additional Carbon Storage Potentialmentioning

confidence: 99%

Recarbonizing global soils – A technical manual of recommended management practices

2021

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The designations employed and the presentation of material in this information product do not imply the expression of any opinion whatsoever on the part of the Food and Agriculture Organization of the United Nations (FAO) concerning the legal or development status of any country, territory, city or area or of its authorities, or concerning the delimitation of its frontiers or boundaries. The mention of specific companies or products of manufacturers, whether or not these have been patented, does not imply that these have been endorsed or recommended by FAO or ITPS in preference to others of a similar nature that are not mentioned.The views expressed in this information product are those of the author(s) and do not necessarily reflect the views or policies of FAO or ITPS.

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The paleoclimatic footprint in the soil carbon stock of the Tibetan permafrost region

Cited by 52 publications

References 57 publications

Temperature sensitivity of plant litter decomposition rate in China's forests

Temperature sensitivity of plant litter decomposition rate in China's forests

A 1 km resolution soil organic carbon dataset for frozen ground in the Third Pole

Recarbonizing global soils – A technical manual of recommended management practices

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