Your search keyword '"Guan, Tiesheng"' showing total 4 results

1. Identifying and Predicting the Responses of Multi-Altitude Vegetation to Climate Change in the Alpine Zone.

Author

Chen, Xin, Guan, Tiesheng, Zhang, Jianyun, Liu, Yanli, Jin, Junliang, Liu, Cuishan, Wang, Guoqing, and Bao, Zhenxin

Subjects

VEGETATION dynamics, CLIMATE change, LEAF area index, ATMOSPHERIC temperature, WATERSHEDS

Abstract

Global climate change has affected vegetation cover in alpine areas. In this paper, we analyzed the correlation between Leaf Area Index (LAI) and climate factors of the Yarlung Tsangpo River basin, and identified their contributions using the quantitative analysis method. The results show that the vegetation cover in the study area generally exhibited an increasing trend. Grassland in the middle- and high-altitude areas was the main contributing area. Temperature is the dominant climatic factor affecting the change, the effect of which increases with the rise in elevation. The influences of precipitation and radiation had obvious seasonality and regionality. The vegetation illustrated a lag response to climate drivers. With the change in the elevation band, the response time to precipitation was significantly less than that to air temperature in the low-elevation area, while the opposite trend was observed in the high-elevation area. In the future, the LAI of the watershed will show different characteristics at different time points, with the increases in the LAI in autumn and winter becoming the main factors for the future increase in the LAI. This provides a crucial basis upon which to explore hydrological and ecological processes as important components of the Third Pole region. [ABSTRACT FROM AUTHOR]

Published

2024

2. Extreme Precipitation Events Variation and Projection in the Lancang-Mekong River Basin Based on CMIP6 Simulations.

Author

Liu, Jing, Liu, Yanli, Chen, Xin, Zhang, Jianyun, Guan, Tiesheng, Wang, Guoqing, Jin, Junliang, Zhang, Ye, and Tang, Liushan

Subjects

CLIMATE change models, WATERSHEDS, RAINSTORMS, CLIMATE change, FLOOD control, FLOOD risk

Abstract

In recent years, global climate change causes more extreme precipitation events in Lancang-Mekong River Basin (Lancang-Mekong Basin). It leads to the increase of rainstorm and flood risk, which poses a threat to the flood control safety of Lancang-Mekong Basin. Based on the precipitation data of four global climate models of CMIP6, this paper selected six indexes, including PRCPTOT and R10, to study the change characteristics of the extreme precipitation indexes in the Lancang-Mekong Basin during 1980–2020 and predicted the development trend of the extreme precipitation indexes in the Lancang-Mekong Basin during 2021–2050. The results show that from 1980 to 2020, the extreme precipitation events in regions I and IV showed an increasing trend, while those in regions II and III showed a decreasing trend. From 2021 to 2050, the extreme precipitation events in all regions of the Lancang-Mekong River show an upward trend, and most indexes increased compared with the historical period. The extreme precipitation indexes in most regions increases the most under the scenario of SSP5-8.5, while the increase is small under the scenario of SSP2-4.5; The six extreme precipitation indexes selected in the paper can better reflect the trend of extreme precipitation events and floods. The trend of extreme precipitation indexes in the Lancang-Mekong River basin in the future is more significant, which indicates that it may be affected more frequently by extreme precipitation events and floods. [ABSTRACT FROM AUTHOR]

Published

2023

3. Centennial Precipitation Characteristics Change in Haihe River Basin, China.

Author

Chen, Xin, Liu, Yanli, Sun, Zhouliang, Zhang, Jianyun, Guan, Tiesheng, Jin, Junliang, Liu, Cuishan, Wang, Guoqing, and Bao, Zhenxin

Subjects

WATERSHEDS, CENTENNIALS, PRECIPITATION probabilities, CLIMATE change, DROUGHTS, CLIMATE research, EXTREME environments

Abstract

Research on precipitation regularity in the past 120 years is an important link in analyzing the precipitation characteristics of watersheds. This paper systematically analyzes the characteristic changes of centennial precipitation data in the Haihe River basin with the help of CRU data, PCI, SPI, and the Pearson type III curve. The results show that the spatial and temporal distribution of precipitation in the Haihe River basin has a more obvious inconsistency. The temporal distribution shows the characteristics of relatively stable in the early period and increasing fluctuation in the later period, the concentration of precipitation gradually decreases, and the overall drought level decreases. The spatial distribution shows a general pattern of gradually decreasing from southwest to northeast, the overall trend of summer precipitation changes from stable to north–south extremes, and the distribution probability of extreme precipitation events in the basin decreases from southeast to northwest, while the drought-prone area transitions from the northeast to the west and southwest of the basin. Under the influence of both climate change and human activities, the seasonal distribution of precipitation tends to be average, the area affected by extreme precipitation rises, and the arid area shifts to the inland area. [ABSTRACT FROM AUTHOR]

Published

2022

4. Quantify Runoff Reduction in the Zhang River Due to Water Diversion for Irrigation.

Author

Chen, Xin, Liu, Yanli, Zhang, Jianyun, Guan, Tiesheng, Sun, Zhouliang, Jin, Junliang, Liu, Cuishan, Wang, Guoqing, and Bao, Zhenxin

Subjects

WATER diversion, RUNOFF analysis, IRRIGATION water, RUNOFF, WATER distribution, FLOODS

Abstract

In order to systematically analyze the impacts of climate change and human activities on runoff, this paper takes the Zhanghe River Basin, which is greatly affected by human activities, as the research object, constructs an attribution analysis model of runoff changes based on historical data and the SWAT (Soil and Water Assessment Tool) model. The results show that the runoff of the watershed has significantly decreased in the past 60 years, in which the contribution rate of climate change is 36.2% and that of human activities is 63.8%. Among the climate change factors, precipitation is the main contributing factor and canal diversion is the main contributing factor among human activities. In addition, with the decrease in precipitation during the flood season and the increase in the crop planting area in the catchment, the distribution of canal water diversion has also changed, and the water consumption of summer crops has gradually become the main factor affecting canal water diversion. [ABSTRACT FROM AUTHOR]

Published

2022