An Integrated Hydrological Model for the Restoration of Ecosystems in Arid Regions: Application in Zhangye Basin of the Middle Heihe River Basin, Northwest China

Liu, Minghuan; Xu, Xu; Jiang, Yao; Huang, Quanzhong; Huo, Zailin

doi:10.1029/2018jd028449

Cited by 4 publications

(4 citation statements)

References 50 publications

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“…The development and utilization of water resources in arid regions of Northwest China are expounded from the levels and zones of river hydrology and ecosystem [11][12]. Heihe River Basin in Northwest China has the most extended history, the most profound depth and the most investment in the study of human development of water resources and its impact on local ecology in arid areas which suffers severe ecological problems [13][14][15].…”

Section: Zhang Et Almentioning

confidence: 99%

Soil moisture variations of wetland at different altitudes in desert regions, China

Zhang¹,

Sun²,

Fei³

et al. 2022

IJEAB

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Desert wetland is a special ecological environment as water is fundamental to maintaining existence. The soil water of sandy wetland links surficial water and groundwater. This study Takes Habahu National Wetland Nature Reserve as the research area and the water movement characteristics of soil profile as the research purpose. According to the altitude and topographic characteristics, the main focus is monitoring soil moisture in different layers at specific sites. The results show that: (1) In the core area of sandy wetland, the water movement of the soil profile is slow with lower infiltration and evaporation; (2) On the slopes around the wetland, the surface water is recharged by rapid leakage along with the underlying impermeable layer after precipitation due to the sand coverage; (3) In the desert hinterland outside the wetland, the water rapidly infiltrates after precipitation and flows into different groundwater systems along the structural characteristics of the underlying stratum to supplement the nearby wetlands. Based on these characteristics, we put forward the unique viewpoints of environmental protection in sandy wetlands: (1) focus on the protection of surface organisms in the core area of sandy wetland to reduce evaporation and improvethe soil water-holding capacity; (2) Appropriate engineering and biological measures should be applied to the slope outside the core area to reduce surface evaporation and plant transpiration and improve the soil moisture; (3) In the periphery area of the wetland, infiltration should be promoted to ensure the source of water supply to wetlands, which would maintain the existence of wetlands and give full play to their ecological functions. In addition, this study analyzed the relationship between soil moisture and plant diversity of 35 species. 16 plants are considered to be suitable for planting in core area of sandy wetland and 9 plants for planting in the desert hinterland outside the wetland.

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Section: Zhang Et Almentioning

confidence: 99%

Soil moisture variations of wetland at different altitudes in desert regions, China

Zhang¹,

Sun²,

Fei³

et al. 2022

IJEAB

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“…The interaction between surface water and groundwater is an important part of the hydrological cycle in a basin (Lago et al 2010; Maassen and Dagmar 2010). Many human activities cause interstitial sedimentation or damage to surface–groundwater hydrological connections, affecting the ecological processes between the two (Wei et al 2011; Cheng et al 2014; Liu et al 2018).…”

Section: Summary Of Restoration Strategies For Wetland System Hcmentioning

confidence: 99%

“…It is widely recognized that successful wetland rehabilitation must include the restoration of vertical links of surface water and groundwater (Kasahara and Hill 2006; Boulton 2007). For the excessive extraction of groundwater, the groundwater irrigation amount per hectare of farmland should be calculated to more accurately calculated the lost amount of groundwater and improve irrigation efficiency (Liu et al 2018; Li and Ren 2019). An increase in the amount of water replenished in the wetland, in turn, increases the amount of groundwater recharge for the wetland (Fan et al 2012).…”

Section: Summary Of Restoration Strategies For Wetland System Hcmentioning

confidence: 99%

Methodologies and Management Framework for Restoration of Wetland Hydrologic Connectivity: A Synthesis

Meng

Liu

Bao

et al. 2020

Integr Envir Assess & Manag

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Under the dual influences of high‐intensity anthropogenic activity and climate change, wetland hydrologic connectivity (HC) has decreased significantly, resulting in the severe fragmentation of wetlands, a decrease in wetland area, and a degradation of hydrological functions, resulting in a worsening disaster response to floods and droughts. Dynamic changes in wetland HC are affected by a variety of factors. Many degraded wetlands have undergone measures to restore HC. Recovery can improve the HC pattern of degraded wetlands. Based on the knowledge of practitioners and a review of the literature, it was found that recovery measures can be divided into structural recovery and functional recovery according to the specific recovery objectives. However, the current recovery method lacks a holistic analysis of the HC pattern. To this end, we propose a hydrologic network–water balance‐based HC recovery and management framework that overcomes the limitations of single‐drive‐factor repair and local repair effects. Integr Environ Assess Manag 2020;16:438–451. © 2020 SETAC

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“…To investigate the interactions between groundwater, soil freezing and thawing process, and human water use, a high‐resolution land model CAS‐LSM including groundwater lateral flow and human water regulation was developed and applied for the entire HRB (Xie et al, ). For the agricultural oasis in the midstream area of the HRB, an integrated model coupling river water, groundwater, vadose zone waterflow, and canal conveyance was developed, and based on scenario analysis and model prediction, how to reduce agricultural water use and restore the natural ecosystem was proposed (Liu, Xu, et al, ).…”

Section: Major Findingsmentioning

confidence: 99%

Introduction to the Water‐Soil‐Air‐Plant‐Human Nexus: Modeling and Observing Complex Land Surface Systems at River Basin Scale

Xie

2019

JGR Atmospheres

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Bidirectional coupling of complex human‐nature system can be referred to as water‐soil‐air‐plant‐human nexus, and integrated studies of this nexus have been carried out in many river basins around the world. This special issue reports contributions for modeling, observing, and understanding of water‐soil‐air‐plant‐human nexus at river basin scale, particularly those from the “Integrated research on the eco‐hydrological process of the Heihe River Basin” program. This paper highlights key results as an introduction to the special issue.

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An Integrated Hydrological Model for the Restoration of Ecosystems in Arid Regions: Application in Zhangye Basin of the Middle Heihe River Basin, Northwest China

Cited by 4 publications

References 50 publications

Soil moisture variations of wetland at different altitudes in desert regions, China

Soil moisture variations of wetland at different altitudes in desert regions, China

Methodologies and Management Framework for Restoration of Wetland Hydrologic Connectivity: A Synthesis

Introduction to the Water‐Soil‐Air‐Plant‐Human Nexus: Modeling and Observing Complex Land Surface Systems at River Basin Scale

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