Artificial water sediment regulation scheme influences morphology, hydrodynamics and nutrient behavior in the Yellow River estuary

•A small delta was newly formed in the Yellow River estuary during a WSRS.•Material distribution altered to a two-plume pattern.•Estuarine mixing was two times stronger during WSRS.•Nutrients were mostly consumed within one to two weeks after entry to the estuary.•Terrestrial nutrient influenced are...

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Published inJournal of hydrology (Amsterdam) Vol. 539; pp. 102 - 112
Main Authors Xu, Bochao, Yang, Disong, Burnett, William C., Ran, Xiangbin, Yu, Zhigang, Gao, Maosheng, Diao, Shaobo, Jiang, Xueyan
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.08.2016
Subjects
Brackish
China
Control
Estuaries
Fluid dynamics
Fluid flow
Freshwater
humans
Hydrodynamics
hydrology
mixing
Morphology
Nutrient
nutrient content
Nutrients
Radium
river deltas
Rivers
Sediments
tracer techniques
Water sediment regulation scheme
Yellow River
Yellow River estuary
INW, China, People's Rep., Shandong Prov., Huang He Estuary
China
Yellow River
Hydrodynamics
Nutrient
Yellow River estuary
Water sediment regulation scheme
Morphology
Radium
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Abstract •A small delta was newly formed in the Yellow River estuary during a WSRS.•Material distribution altered to a two-plume pattern.•Estuarine mixing was two times stronger during WSRS.•Nutrients were mostly consumed within one to two weeks after entry to the estuary.•Terrestrial nutrient influenced area was 2–3 times larger during WSRS. Anthropogenic controls on water and sediment may play important roles in river system transformations and morphological evolution, which could further affect coastal hydrodynamics and nutrient behavior. We used geochemical tracers to evaluate the influence of an intentional large release of water and sediment during the so-called “Water Sediment Regulation Scheme” (WSRS) on estuarine morphology, hydrodynamics and nutrients in the Yellow River estuary, China. We discovered that there was a newly formed small delta in the river mouth after the 2013 WSRS. This new morphologic feature altered terrestrial material distribution patterns from a single plume to a two-plume pattern within the estuary. Our results show that the WSRS significantly influenced the study area in the following ways: (1) Radium and nutrient concentrations were significantly elevated (two to four times), especially along the two river outlets. (2) Estuarine mixing was about two times stronger during WSRS than before. Average aerial mixing rates before and during WSRS were 50±26km2d−1 and 89±51km2d−1, respectively. (3) Our data is consistent with P limitation and suggest that stoichiometrically based P limitation was even more severe during WSRS. (4) All river-derived nutrients were thoroughly consumed within one to two weeks after entry to near-shore waters. (5) The extent of the area influenced by terrestrial nutrients was two to three times greater during WSRS. Human influence, such as triggered by WSRS regulations, should thus be considered when studying biogeochemical processes and nutrient budgets in situations like the Yellow River estuary.
AbstractList •A small delta was newly formed in the Yellow River estuary during a WSRS.•Material distribution altered to a two-plume pattern.•Estuarine mixing was two times stronger during WSRS.•Nutrients were mostly consumed within one to two weeks after entry to the estuary.•Terrestrial nutrient influenced area was 2–3 times larger during WSRS. Anthropogenic controls on water and sediment may play important roles in river system transformations and morphological evolution, which could further affect coastal hydrodynamics and nutrient behavior. We used geochemical tracers to evaluate the influence of an intentional large release of water and sediment during the so-called “Water Sediment Regulation Scheme” (WSRS) on estuarine morphology, hydrodynamics and nutrients in the Yellow River estuary, China. We discovered that there was a newly formed small delta in the river mouth after the 2013 WSRS. This new morphologic feature altered terrestrial material distribution patterns from a single plume to a two-plume pattern within the estuary. Our results show that the WSRS significantly influenced the study area in the following ways: (1) Radium and nutrient concentrations were significantly elevated (two to four times), especially along the two river outlets. (2) Estuarine mixing was about two times stronger during WSRS than before. Average aerial mixing rates before and during WSRS were 50±26km2d−1 and 89±51km2d−1, respectively. (3) Our data is consistent with P limitation and suggest that stoichiometrically based P limitation was even more severe during WSRS. (4) All river-derived nutrients were thoroughly consumed within one to two weeks after entry to near-shore waters. (5) The extent of the area influenced by terrestrial nutrients was two to three times greater during WSRS. Human influence, such as triggered by WSRS regulations, should thus be considered when studying biogeochemical processes and nutrient budgets in situations like the Yellow River estuary.
Anthropogenic controls on water and sediment may play important roles in river system transformations and morphological evolution, which could further affect coastal hydrodynamics and nutrient behavior. We used geochemical tracers to evaluate the influence of an intentional large release of water and sediment during the so-called "Water Sediment Regulation Scheme" (WSRS) on estuarine morphology, hydrodynamics and nutrients in the Yellow River estuary, China. We discovered that there was a newly formed small delta in the river mouth after the 2013 WSRS. This new morphologic feature altered terrestrial material distribution patterns from a single plume to a two-plume pattern within the estuary. Our results show that the WSRS significantly influenced the study area in the following ways: (1) Radium and nutrient concentrations were significantly elevated (two to four times), especially along the two river outlets. (2) Estuarine mixing was about two times stronger during WSRS than before. Average aerial mixing rates before and during WSRS were 50 plus or minus 26km2d-1 and 89 plus or minus 51km2d-1, respectively. (3) Our data is consistent with P limitation and suggest that stoichiometrically based P limitation was even more severe during WSRS. (4) All river-derived nutrients were thoroughly consumed within one to two weeks after entry to near-shore waters. (5) The extent of the area influenced by terrestrial nutrients was two to three times greater during WSRS. Human influence, such as triggered by WSRS regulations, should thus be considered when studying biogeochemical processes and nutrient budgets in situations like the Yellow River estuary.
Anthropogenic controls on water and sediment may play important roles in river system transformations and morphological evolution, which could further affect coastal hydrodynamics and nutrient behavior. We used geochemical tracers to evaluate the influence of an intentional large release of water and sediment during the so-called “Water Sediment Regulation Scheme” (WSRS) on estuarine morphology, hydrodynamics and nutrients in the Yellow River estuary, China. We discovered that there was a newly formed small delta in the river mouth after the 2013 WSRS. This new morphologic feature altered terrestrial material distribution patterns from a single plume to a two-plume pattern within the estuary. Our results show that the WSRS significantly influenced the study area in the following ways: (1) Radium and nutrient concentrations were significantly elevated (two to four times), especially along the two river outlets. (2) Estuarine mixing was about two times stronger during WSRS than before. Average aerial mixing rates before and during WSRS were 50±26km2d−1 and 89±51km2d−1, respectively. (3) Our data is consistent with P limitation and suggest that stoichiometrically based P limitation was even more severe during WSRS. (4) All river-derived nutrients were thoroughly consumed within one to two weeks after entry to near-shore waters. (5) The extent of the area influenced by terrestrial nutrients was two to three times greater during WSRS. Human influence, such as triggered by WSRS regulations, should thus be considered when studying biogeochemical processes and nutrient budgets in situations like the Yellow River estuary.
Author Yu, Zhigang
Burnett, William C.
Gao, Maosheng
Ran, Xiangbin
Diao, Shaobo
Xu, Bochao
Yang, Disong
Jiang, Xueyan
Author_xml – sequence: 1
  givenname: Bochao
  surname: Xu
  fullname: Xu, Bochao
  email: xubc@ouc.edu.cn
  organization: Key Laboratory of Marine Chemistry Theory and Technology, Ministry of Education, Ocean University of China, Qingdao 266100, China
– sequence: 2
  givenname: Disong
  surname: Yang
  fullname: Yang, Disong
  organization: Key Laboratory of Marine Chemistry Theory and Technology, Ministry of Education, Ocean University of China, Qingdao 266100, China
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  givenname: William C.
  surname: Burnett
  fullname: Burnett, William C.
  organization: Department of Earth, Ocean and Atmospheric Sciences, Florida State University, Tallahassee, FL 32306, USA
– sequence: 4
  givenname: Xiangbin
  surname: Ran
  fullname: Ran, Xiangbin
  organization: Research Center for Marine Ecology, First Institute of Oceanography, State Oceanic Administration, Qingdao 266061, China
– sequence: 5
  givenname: Zhigang
  surname: Yu
  fullname: Yu, Zhigang
  organization: Key Laboratory of Marine Chemistry Theory and Technology, Ministry of Education, Ocean University of China, Qingdao 266100, China
– sequence: 6
  givenname: Maosheng
  surname: Gao
  fullname: Gao, Maosheng
  organization: Qingdao Institute of Marine Geology, Qingdao 266071, China
– sequence: 7
  givenname: Shaobo
  surname: Diao
  fullname: Diao, Shaobo
  organization: Qingdao Institute of Marine Geology, Qingdao 266071, China
– sequence: 8
  givenname: Xueyan
  surname: Jiang
  fullname: Jiang, Xueyan
  organization: Key Laboratory of Marine Chemistry Theory and Technology, Ministry of Education, Ocean University of China, Qingdao 266100, China
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Snippet •A small delta was newly formed in the Yellow River estuary during a WSRS.•Material distribution altered to a two-plume pattern.•Estuarine mixing was two times...
Anthropogenic controls on water and sediment may play important roles in river system transformations and morphological evolution, which could further affect...
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SubjectTerms Brackish
China
Control
Estuaries
Fluid dynamics
Fluid flow
Freshwater
humans
Hydrodynamics
hydrology
mixing
Morphology
Nutrient
nutrient content
Nutrients
Radium
river deltas
Rivers
Sediments
tracer techniques
Water sediment regulation scheme
Yellow River
Yellow River estuary
Title Artificial water sediment regulation scheme influences morphology, hydrodynamics and nutrient behavior in the Yellow River estuary
URI https://dx.doi.org/10.1016/j.jhydrol.2016.05.024
https://www.proquest.com/docview/1808711489
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