Perspectives of human–water co‐evolution of blue–green water resources in subtropical areas

Pan, Zihao; Yang, Shengtian; Lou, Hezhen; Li, Chao‐Jun; Zhang, Jun; Zhang, Yujia; Luo, Yiqi; Li, Xi

doi:10.1002/hyp.14818

Cited by 5 publications

(3 citation statements)

References 87 publications

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“…The Yangchang River Basin is located in the rural transitional zone between Guiyang city and Anshun city, with an area of 605.61 km 2 . Vegetation is dominated by crops and shrubs due to agricultural cultivation-led human activities, while forests are concentrated in karst peaks (Pan et al, 2023). The Nanming River Basin is located in Guiyang city and its surrounding areas, with an area of 1131.26 km 2 .…”

Section: Study Areamentioning

confidence: 99%

The barrier risk to the ecological connectivity of plant diversity in karst landscapes in Guizhou Province, China

Zhou,

Lou,

Yang

et al. 2024

Front. Environ. Sci.

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Ecological connectivity in landscapes is crucial for plant diversity conservation. The barrier risk to ecological connectivity represents the risk to ecological connectivity loss or weakening, resulting from the barrier to biological information exchange among habitats. Therefore, clarifying the barrier risk to the ecological connectivity of plant diversity in space can reveal the spatial impacts of reduced ecological connectivity on plant diversity. This study analyzed effects of karst peak, river network, arable land, and impervious surface on plant diversity in karst natural, countryside, urban, and island landscapes in Guizhou Province with fragile environment. Then, we calculated the barrier distance of ecological connectivity to reveal the barrier risk to the ecological connectivity of plant diversity in space. The results showed that karst peak was the source of high plant diversity, and plant diversity could diffuse about 400 m around karst peaks. River network and arable land enhanced the connectivity among karst peaks to maintain plant diversity, and the effect on enhancing the connectivity was about 300 m and 450 m, respectively, while the weakening effect of impervious surface on connectivity was about 350 m. Based on the distance for plant diversity diffusing around karst peaks, the barrier distance of ecological connectivity was determined by the combination type of river network, arable land and impervious surface in landscapes. From low to high, the barrier risk to the ecological connectivity of plant diversity was about 1,110 m in the combination of river network and arable land, about 790 m in the combination of river network, arable land and impervious surface, about 520 min the combination of arable land and impervious surface, about 400 m in the combination of river network and impervious surface. Our findings clarify the barrier risk to the ecological connectivity of plant diversity in space, and provide a scientific basis for plant diversity conservation from the perspective of ecological connectivity.

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Section: Study Areamentioning

confidence: 99%

The barrier risk to the ecological connectivity of plant diversity in karst landscapes in Guizhou Province, China

Zhou,

Lou,

Yang

et al. 2024

Front. Environ. Sci.

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“…1 A series of UAV observations and field investigations were conducted in the target river sections to obtain high-precision UAV images and measurement values of relevant hydraulic parameters, such as the water depth and velocity [27] (Figure 2 (Step 1)).…”

Section: Remote Sensing Hydrological Station Technology For River Dis...mentioning

confidence: 99%

“…Pix4d software was used to process the obtained UAV images and to generate digital orthophoto maps (DOMs) and digital surface models (DSMs). These were combined with the measured elevation model (DEM) data[27] to establish a digital river section model (Figure2 (Step 3)) 3. The normalized difference water index was calculated by using satellite remote sensing images with a 10 m spatial resolution, and the principal period of the flow sequence was determined based on remote sensing images with a long time span[28].…”

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confidence: 99%

Detection and Analysis of the Variation in the Minimum Ecological Instream Flow Requirement in the Chinese Northwestern Inland Arid Region by Using a New Remote Sensing Method

Yang,

Li,

Lou

et al. 2023

Remote Sensing

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With the development of human society, the balance between the minimum ecological instream flow requirement (MEIFR), which is an essential part of the ecological water demand in arid areas, and anthropogenic water depletion has received increasing attention. However, due to the lack of hydrological station data and river information on arid basins, previous researchers usually considered only the individual ecological water demand of rivers, lakes, or oases. To address this issue, a new method that combines river hydraulic parameters and the wet circumference obtained by an unmanned aerial vehicle (UAV) and remote sensing hydrological station (RSHS) technologies was applied to obtain the MEIFR and, then, systematically and quantitatively explore the balance from the perspective of the entire basin of Aiding Lake from 1990 to 2022, which is the lowest point of Chinese terrestrial territory. The results showed the following: (1) since 1990, the discharge of the seven rivers in the study area increased by 1–6%, and the MEIFR of these rivers increased by 15–100%; both quantities decreased by 3–5% from the upper to the lower reaches of the basin; (2) the surface area and water level of Aiding Lake decreased by 5% and 14%, respectively, but the MEIFR first decreased by 25% from 1990 to 2013 and, then, increased by 66.7% from 2013 to 2022; and (3) from 2011 to 2022, the MEIFR and anthropogenic water depletion exhibited a balance. Against the background of climate change, this research revealed that the MEIFR of the rivers in the Aiding Lake Basin have shown an upward trend over the past 30 years and quantitatively determined the above balance relationship and the period of its occurrence. This study supplied a method that could provide guidance for water resource management by decision-makers at a global level, thus helping achieve the sustainable development goals (SDGs).

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Evaluation of water resource balance in the Urmia Lake Basin: Integrating carrying capacity and water footprint model for sustainable management

Hadipour,

Pourebrahim,

Heidari

et al. 2024

Ecological Indicators

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Perspectives of human–water co‐evolution of blue–green water resources in subtropical areas

Cited by 5 publications

References 87 publications

The barrier risk to the ecological connectivity of plant diversity in karst landscapes in Guizhou Province, China

The barrier risk to the ecological connectivity of plant diversity in karst landscapes in Guizhou Province, China

Detection and Analysis of the Variation in the Minimum Ecological Instream Flow Requirement in the Chinese Northwestern Inland Arid Region by Using a New Remote Sensing Method

Evaluation of water resource balance in the Urmia Lake Basin: Integrating carrying capacity and water footprint model for sustainable management

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