Longitudinal Dynamics of Hydrological Connectivity in the Yellow River Delta, China

River deltas are formed by the interaction of connecting water and sediment, and they are among the most economically and ecologically valuable ecosystems on Earth. Because of their special locations, together with direct and indirect human interference, river deltas are expected to be more vulnerable and fragmented. The increasing fragmentation of deltas is largely due to longitudinal hydrological connectivity disruption caused by human activities. However, the dynamics of longitudinal connectivity are unknown, especially in the Yellow River Delta (YRD), which has been subjected to heavy reclamation in recent years. In this study, we divided the whole YRD into three subregions, the erosion zone, the oilfield zone and the deposition zone, and then we used indicators to explore the spatiotemporal variation in hydrological connectivity on the whole scale and on the zonal scale of the delta during 1984-2018 in the YRD. We found that the variation in longitudinal hydrological connectivity was closely related to the geometry of the tidal channel networks, and that the changes in longitudinal hydrological connectivity varied with research scales. A weak increasing trend of connectivity was found on the whole scale of the delta during the past three decades. A decreasing trend of connectivity was found in both the erosion zone and the oilfield zone. In the deposition zone, however, the connectivity degree was enhanced. Furthermore, we also identified the key impaired area and relatively stable area of hydrological connectivity in the YRD and implied that the key impaired area may be a priority restoration zone of the impaired hydrological connectivity zone. Our study provides useful scientific guidance for the subsequent restoration of damaged wetlands.

[1]  S. Pan,et al.  Climate-driven flyway changes and memory-based long-distance migration , 2021, Nature.

[2]  Demin Zhou,et al.  Parameterizing the Yellow River Delta tidal creek morphology using automated extraction from remote sensing images. , 2021, The Science of the total environment.

[3]  Hongbo Ma,et al.  Predicting Water and Sediment Partitioning in a Delta Channel Network Under Varying Discharge Conditions , 2020, Water Resources Research.

[4]  Leo F. Isikdogan,et al.  System wide channel network analysis reveals hotspots of morphological change in anthropogenically modified regions of the Ganges Delta , 2020, Scientific Reports.

[5]  S. K. Tandon,et al.  Geomorphic connectivity and its application for understanding landscape complexities: a focus on the hydro‐geomorphic systems of India , 2020, Earth Surface Processes and Landforms.

[6]  E. Blackwell,et al.  Tracking California's sinking coast from space: Implications for relative sea-level rise. , 2020, Science advances.

[7]  B. Cui,et al.  Reclamation shifts the evolutionary paradigms of tidal channel networks in the Yellow River Delta, China. , 2020, The Science of the total environment.

[8]  Changkuan Zhang,et al.  Simulating the impacts of land reclamation and de-reclamation on the morphodynamics of tidal networks , 2020, Anthropocene Coasts.

[9]  B. Cui,et al.  Hydrological connectivity dynamics of tidal flat systems impacted by severe reclamation in the Yellow River Delta. , 2020, The Science of the total environment.

[10]  Runqiu Huang,et al.  Recent Evolution of Coastal Tidal Flats and the Impacts of Intensified Human Activities in the Modern Radial Sand Ridges, East China , 2020, International journal of environmental research and public health.

[11]  Guifang Zhang,et al.  Hydrological connectivity: One of the driving factors of plant communities in the Yellow River Delta , 2020 .

[12]  B. C. Prooijen,et al.  Sediment Connectivity: A Framework for Analyzing Coastal Sediment Transport Pathways , 2020, Journal of Geophysical Research: Earth Surface.

[13]  D. S. van Maren,et al.  Resilience of River Deltas in the Anthropocene , 2020, Journal of Geophysical Research: Earth Surface.

[14]  A. Kettner,et al.  Global-scale human impact on delta morphology has led to net land area gain , 2020, Nature.

[15]  N. Giesen Human activities have changed the shapes of river deltas , 2020 .

[16]  R. Sinha,et al.  Evaluating dynamic hydrological connectivity of a floodplain wetland in North Bihar, India using geostatistical methods. , 2019, The Science of the total environment.

[17]  Alexander Veremyev,et al.  Critical Nodes in River Networks , 2019, Scientific Reports.

[18]  P. Passalacqua,et al.  Hydrological Connectivity in Vegetated River Deltas: The Importance of Patchiness Below a Threshold , 2018, Geophysical Research Letters.

[19]  Yamir Moreno,et al.  Multiplex Networks: A Framework for Studying Multiprocess Multiscale Connectivity Via Coupled‐Network Theory With an Application to River Deltas , 2018, Geophysical Research Letters.

[20]  于小娟,et al.  1989 年以来7 个时期黄河三角洲潮沟的形态特征及连通性研究 , 2018 .

[21]  Saskia Keesstra,et al.  The way forward: Can connectivity be useful to design better measuring and modelling schemes for water and sediment dynamics? , 2018, The Science of the total environment.

[22]  Stuart N. Lane,et al.  Connectivity as an emergent property of geomorphic systems , 2018, Earth Surface Processes and Landforms.

[23]  Youpeng Xu,et al.  Impacts of human activities on the structural and functional connectivity of a river network in the Taihu Plain , 2018, Land Degradation & Development.

[24]  Sang-Hoon Hong,et al.  Assessment of hydrologic connectivity in an ungauged wetland with InSAR observations , 2018 .

[25]  Louise B. Firth,et al.  Eco-engineering urban infrastructure for marine and coastal biodiversity: Which interventions have the greatest ecological benefit? , 2018 .

[26]  Paola Passalacqua,et al.  Process connectivity in a naturally prograding river delta , 2017 .

[27]  Paola Passalacqua,et al.  The Delta Connectome: A network-based framework for studying connectivity in river deltas , 2017 .

[28]  Ronald E. Poeppl,et al.  A conceptual connectivity framework for understanding geomorphic change in human-impacted fluvial systems , 2017 .

[29]  M. López‐Vicente,et al.  Hydrological Connectivity Does Change Over 70 Years of Abandonment and Afforestation in the Spanish Pyrenees , 2017 .

[30]  S. Temmerman,et al.  On the potential of plant species invasion influencing bio‐geomorphologic landscape formation in salt marshes , 2016 .

[31]  Stephen J. Hawkins,et al.  Eco-engineered rock pools: a concrete solution to biodiversity loss and urban sprawl in the marine environment , 2016 .

[32]  Ilya Zaliapin,et al.  Quantifying the signature of sediment composition on the topologic and dynamic complexity of river delta channel networks and inferences toward delta classification , 2016 .

[33]  L. Castello,et al.  Large‐scale degradation of Amazonian freshwater ecosystems , 2016, Global change biology.

[34]  S. Fagherazzi,et al.  Salt marsh vegetation promotes efficient tidal channel networks , 2014, Nature Communications.

[35]  Anthony Longjas,et al.  Delta channel networks: 1. A graph‐theoretic approach for studying connectivity and steady state transport on deltaic surfaces , 2015 .

[36]  Paola Passalacqua,et al.  Hydrological connectivity in river deltas: The first‐order importance of channel‐island exchange , 2015 .

[37]  John Day,et al.  Climate change: Protect the world's deltas , 2014, Nature.

[38]  Wolfgang Schwanghart,et al.  Graph theory-recent developments of its application in geomorphology , 2014 .

[39]  M. Kirwan,et al.  Tidal wetland stability in the face of human impacts and sea-level rise , 2013, Nature.

[40]  Doerthe Tetzlaff,et al.  Concepts of hydrological connectivity: Research approaches, pathways and future agendas , 2013 .

[41]  L. Larsen,et al.  Directional connectivity in hydrology and ecology. , 2012, Ecological applications : a publication of the Ecological Society of America.

[42]  Ferenc Jordán,et al.  Contribution of habitat patches to network connectivity: Redundancy and uniqueness of topological indices , 2011 .

[43]  Baoshan Cui,et al.  River channel network design for drought and flood control: A case study of Xiaoqinghe River basin, Jinan City, China. , 2009, Journal of environmental management.

[44]  Stuart N. Lane,et al.  Representation of landscape hydrological connectivity using a topographically driven surface flow index , 2009 .

[45]  Praveen Kumar,et al.  Ecohydrologic process networks: 1. Identification , 2009 .

[46]  J. Wainwright,et al.  Linking environmental régimes, space and time: Interpretations of structural and functional connectivity , 2008 .

[47]  S. Saura,et al.  Comparison and development of new graph-based landscape connectivity indices: towards the priorization of habitat patches and corridors for conservation , 2006, Landscape Ecology.

[48]  Huang Haijun Change Detection of Tidal Flats and Tidal Creeks in the Yellow River Delta Using Landsat TM/ETM+ Images , 2004 .

[49]  Mark E. J. Newman,et al.  The Structure and Function of Complex Networks , 2003, SIAM Rev..

[50]  C. Pringle HYDROLOGIC CONNECTIVITY AND THE MANAGEMENT OF BIOLOGICAL RESERVES: A GLOBAL PERSPECTIVE , 2001 .