Your search keyword '"Xing, Xiaoyu"' showing total 3 results

1. The effects of intrinsic water-use efficiency and climate on wood anatomy

Author

Hong, Yixue, Liu, Xiaohong, Camarero, J. Julio, Xu, Guobao, Zhang, Lingnan, Zeng, Xiaomin, Aritsara, Amy Ny Aina, Zhang, Yu, Wang, Wenzhi, Xing, Xiaoyu, and Lu, Qiangqiang

Published

2023

2. Resistance of Grassland under Different Drought Types in the Inner Mongolia Autonomous Region of China.

Author

Guo, Jian, Yang, Xiuchun, Jiang, Weiguo, Xing, Xiaoyu, Zhang, Min, Chen, Ang, Yang, Dong, Yang, Mingxin, Wei, Lunda, and Xu, Bin

Subjects

DROUGHT management, DROUGHTS, GRASSLANDS, CARBON cycle, STEPPES, BIOMES

Abstract

The increasing frequency of global drought events poses a significant threat to the stability of grassland ecosystems' functionality. The Inner Mongolian grasslands stand out as one of the world's most drought-prone regions, facing elevated drought risks compared to other biomes. An in-depth comprehension of the impact of drought on grassland ecosystems is paramount for their long-term sustainability. Using the Standardized Precipitation Evapotranspiration Index (SPEI) from 1982 to 2018, this study identified various drought events within the Inner Mongolian grasslands, encompassing moderate drought, severe drought, and extreme drought. The resistance of the vegetation to the different drought conditions, assessed through net primary productivity (NPP) as a metric (reflecting its capacity to maintain its original level during drought periods), was examined. The research findings indicated that the period from 2001 to 2018 witnessed a substantial increase in both the frequency and the extent of drought events compared to the period from 1982 to 2000, particularly concerning severe and extreme droughts. The areas most severely impacted by extreme drought were the Xilingol League and the Alxa League. From 1982–2000 to 2001–2018, under moderate drought conditions, vegetation resistance exhibited a minor decrease in the central and eastern regions but experienced a slight increase in the western region. In contrast, under severe drought conditions, the western region saw a significant decrease in vegetation resistance. Remarkably, under extreme drought conditions, the western region showed a substantial increase in vegetation resistance, while the central and eastern regions experienced a slight decrease. Across all three drought conditions, as precipitation levels declined, the resistance of the meadow–steppe–desert ecosystems demonstrated a high–low–high distribution pattern. The temperate desert steppe exhibited a minimal vulnerability to drought, boasting resistance levels exceeding 0.9. Notably, extreme drought had the most pronounced impact on the temperate meadow steppe, temperate steppe, and temperate desert steppe, particularly within the temperate meadow steppe category. Given these findings, the authorities responsible for grassland management should prioritize regions characterized by frequent drought occurrences and low drought resistance, such as Ulanqab City, the Xilingol League, and the western part of Hulun Buir City. Safeguarding steppe ecosystems is of paramount importance for stabilizing vegetation productivity and land carbon sinks, especially under the anticipated exacerbation of climate conditions in the future. [ABSTRACT FROM AUTHOR]

Published

2023

3. Spatial Heterogeneity of Vegetation Resilience Changes to Different Drought Types.

Author

Zhang, Yu, Liu, Xiaohong, Jiao, Wenzhe, Wu, Xiuchen, Zeng, Xiaomin, Zhao, Liangju, Wang, Lixin, Guo, Jiaqi, Xing, Xiaoyu, and Hong, Yixue

Subjects

DROUGHTS, DROUGHT management, VEGETATION dynamics, LEAF area index, ECOSYSTEM management, VAPOR pressure, TREE-rings

Abstract

Resilience is a fundamental concept for vegetation health. The increasing drought frequency and severity may pose severe threat to vegetation resilience. However, it is still not clear how vegetation resilience is evolving in response to climate change in pivotal biographical zones. Here, we examined the resilience changes in terms of leaf area index (LAI, an indicator of canopy structure) and gross primary productivity (GPP, an indicator of carbon uptake) in responding to the Standardized Precipitation‐Evapotranspiration Index (SPEI) and vapor pressure deficit (VPD) over China's Loess Plateau and Qinling Mountains. Linking remote sensing variables and tree ring width allows the upscaling of plot‐based vegetation growth information. We further explored potential explanatory factors associated with the heterogeneous spatial distributions of resilience changes. Results revealed that the resilience of GPP weakened more than LAI in response to drought, suggesting that compared to LAI, productivity requires more time to recover to the pre‐drought levels. Regionally, the change of vegetation resilience on the Loess Plateau and in high‐altitude areas was highly susceptible to SPEI and VPD, respectively. The observed spatial heterogeneity in resilience changes was mainly attributed by climate zone, water deficit, and their interactions. Our findings provide direct and empirical evidence that the vegetation in the Loess Plateau and Qinling Mountains is gradually losing resilience. The results indicate that sustained ecosystem water deficit and atmospheric dryness will continue to threaten vegetation survival and terrestrial ecosystem service. Plain Language Summary: Vegetation resilience in pivotal biographical regions is altered by increasingly severe drought pressures. However, to what extent resilience changes and how the regional responses vary to different drought indicators have not yet been well explored. Here we quantify the resilience changes regarding vegetation physiological function and canopy structure after the significant changes in drought conditions over the Loess Plateau and Qinling Mountains of China. Results show that the vegetation physiological function has been damaged more seriously than the canopy structure, suggesting vegetation is gradually losing resilience. In relatively high‐altitude regions, the change of vegetation resilience is more sensitive to high vapor pressure deficit than the Standardized Precipitation‐Evapotranspiration Index, but in opposite direction on the Loess Plateau. Spatial heterogeneity analysis shows that these changes are mainly affected by climate zone, water‐related factors (precipitation, relative humidity, soil water), and their interactive effects. Characterizing of resilience changes as reference conditions for ecosystem management and restoration has significant implications in the context of global warming. Key Points: The resilience of vegetation productivity weakened more than that of canopy structure in response to droughtThe impacts of atmospheric dryness on vegetation resilience changes are much larger than those of Standardized Precipitation‐Evapotranspiration Index (SPEI) in high‐altitude regionsCombined effects of climate zone (CZ) and water deficits explain the spatial heterogeneity of vegetation resilience changes [ABSTRACT FROM AUTHOR]

Published

2023