Water Point and Non-Point Nitrogen Pollution Due to Land-Use Change and Nitrate Deposition in China from 2000 to 2020

Xiaoning Zhao; Jiawei Shi; Lihua Xue; Wenwen Li; Kazem Zamanian; Jiangang Han; Shuang Chen

doi:10.3390/w16101396

Details

Original language	English
Article number	1396
Journal	Water
Volume	16
Issue number	10
Publication status	Published - 14 May 2024

Abstract

Water N-NO ₃ ⁻ (mg L ⁻¹) pollution is attracting global concern in the face of combating climate change and human health risks. However, there have been comparatively few comprehensively researched studies on water N-NO ₃ ⁻ pollution with respect to N-NO ₃ ⁻ deposition, soil nitrogen, and land-use changes. We collected a total of 7707 published sampling points on N-NO ₃ ⁻ surface and groundwater during flooding and non-flooding seasons during 2000–2020 in China. The types of water N-NO ₃ ⁻ pollution (>20) can be categorized as point pollution (ΔTN ≤ 0 or > 1.5) and non-point pollution (0 < ΔTN ≤ 1.5), which were then assessed with respect to soil nitrogen (ΔTN g kg ⁻¹) and water N-NO ₃ ⁻ changes in this study. We found non-point pollution was concentrated in the Huaihe River Basin and Haihe River Basin with higher urbanization (+6%, +4%), cropland (72%, 45%), nitrogen fertilization (g m ⁻² yr ⁻¹) (>10), and increased wet N-NO ₃ ⁻ deposition (WND) (kg ha ⁻¹ yr ⁻¹) (+4.6, +3). The Haihe River Basin was found to have the highest N-NO ₃ ⁻ on its surface (306) and in its groundwater (868) and nitrogen fertilization (32). Point pollution was concentrated in the Songhua and Liaohe River Basin with the highest WND (+7.9) but slow urbanization (+1%). N-NO ₃ ⁻ increased during the flooding season compared with the no-flooding season in serious pollution areas. N-NO ₃ ⁻ increased in the Liaohe River and middle and low Yangtze River but was reduced in the Weihe River. Therefore, stringent criteria and management, especially during the flooding season are urgently required to mitigate the degree of N-NO ₃ ⁻ water pollution that occurs due to intensive agriculture and urbanization with increased N-NO ₃ ⁻ deposition.

Keywords

atmospheric nitrogen deposition, human health, land-use change, nitrogen pollution, urbanization

ASJC Scopus subject areas

Environmental Science(all)
Water Science and Technology
Social Sciences(all)
Geography, Planning and Development
Agricultural and Biological Sciences(all)
Aquatic Science
Biochemistry, Genetics and Molecular Biology(all)
Biochemistry

Sustainable Development Goals

Cite this

Water Point and Non-Point Nitrogen Pollution Due to Land-Use Change and Nitrate Deposition in China from 2000 to 2020. / Zhao, Xiaoning; Shi, Jiawei; Xue, Lihua et al.
In: Water, Vol. 16, No. 10, 1396, 14.05.2024.

Research output: Contribution to journal › Article › Research › peer review

Zhao, X, Shi, J, Xue, L, Li, W, Zamanian, K, Han, J & Chen, S 2024, 'Water Point and Non-Point Nitrogen Pollution Due to Land-Use Change and Nitrate Deposition in China from 2000 to 2020', Water, vol. 16, no. 10, 1396. https://doi.org/10.3390/w16101396

Zhao, X., Shi, J., Xue, L., Li, W., Zamanian, K., Han, J., & Chen, S. (2024). Water Point and Non-Point Nitrogen Pollution Due to Land-Use Change and Nitrate Deposition in China from 2000 to 2020. Water, 16(10), Article 1396. https://doi.org/10.3390/w16101396

Zhao X, Shi J, Xue L, Li W, Zamanian K, Han J et al. Water Point and Non-Point Nitrogen Pollution Due to Land-Use Change and Nitrate Deposition in China from 2000 to 2020. Water. 2024 May 14;16(10):1396. doi: 10.3390/w16101396

Zhao, Xiaoning ; Shi, Jiawei ; Xue, Lihua et al. / Water Point and Non-Point Nitrogen Pollution Due to Land-Use Change and Nitrate Deposition in China from 2000 to 2020. In: Water. 2024 ; Vol. 16, No. 10.

Download

@article{58c737b6b39b42b4899fc84c41f61154,

title = "Water Point and Non-Point Nitrogen Pollution Due to Land-Use Change and Nitrate Deposition in China from 2000 to 2020",

abstract = "Water N-NO 3 − (mg L −1) pollution is attracting global concern in the face of combating climate change and human health risks. However, there have been comparatively few comprehensively researched studies on water N-NO 3 − pollution with respect to N-NO 3 − deposition, soil nitrogen, and land-use changes. We collected a total of 7707 published sampling points on N-NO 3 − surface and groundwater during flooding and non-flooding seasons during 2000–2020 in China. The types of water N-NO 3 − pollution (>20) can be categorized as point pollution (ΔTN ≤ 0 or > 1.5) and non-point pollution (0 < ΔTN ≤ 1.5), which were then assessed with respect to soil nitrogen (ΔTN g kg −1) and water N-NO 3 − changes in this study. We found non-point pollution was concentrated in the Huaihe River Basin and Haihe River Basin with higher urbanization (+6%, +4%), cropland (72%, 45%), nitrogen fertilization (g m −2 yr −1) (>10), and increased wet N-NO 3 − deposition (WND) (kg ha −1 yr −1) (+4.6, +3). The Haihe River Basin was found to have the highest N-NO 3 − on its surface (306) and in its groundwater (868) and nitrogen fertilization (32). Point pollution was concentrated in the Songhua and Liaohe River Basin with the highest WND (+7.9) but slow urbanization (+1%). N-NO 3 − increased during the flooding season compared with the no-flooding season in serious pollution areas. N-NO 3 − increased in the Liaohe River and middle and low Yangtze River but was reduced in the Weihe River. Therefore, stringent criteria and management, especially during the flooding season are urgently required to mitigate the degree of N-NO 3 − water pollution that occurs due to intensive agriculture and urbanization with increased N-NO 3 − deposition.",

keywords = "atmospheric nitrogen deposition, human health, land-use change, nitrogen pollution, urbanization",

author = "Xiaoning Zhao and Jiawei Shi and Lihua Xue and Wenwen Li and Kazem Zamanian and Jiangang Han and Shuang Chen",

note = "Publisher Copyright: {\textcopyright} 2024 by the authors.",

year = "2024",

month = may,

day = "14",

doi = "10.3390/w16101396",

language = "English",

volume = "16",

journal = "Water",

issn = "2073-4441",

publisher = "Multidisciplinary Digital Publishing Institute",

number = "10",

}

Download

TY - JOUR

T1 - Water Point and Non-Point Nitrogen Pollution Due to Land-Use Change and Nitrate Deposition in China from 2000 to 2020

AU - Zhao, Xiaoning

AU - Shi, Jiawei

AU - Xue, Lihua

AU - Li, Wenwen

AU - Zamanian, Kazem

AU - Han, Jiangang

AU - Chen, Shuang

PY - 2024/5/14

Y1 - 2024/5/14

N2 - Water N-NO 3 − (mg L −1) pollution is attracting global concern in the face of combating climate change and human health risks. However, there have been comparatively few comprehensively researched studies on water N-NO 3 − pollution with respect to N-NO 3 − deposition, soil nitrogen, and land-use changes. We collected a total of 7707 published sampling points on N-NO 3 − surface and groundwater during flooding and non-flooding seasons during 2000–2020 in China. The types of water N-NO 3 − pollution (>20) can be categorized as point pollution (ΔTN ≤ 0 or > 1.5) and non-point pollution (0 < ΔTN ≤ 1.5), which were then assessed with respect to soil nitrogen (ΔTN g kg −1) and water N-NO 3 − changes in this study. We found non-point pollution was concentrated in the Huaihe River Basin and Haihe River Basin with higher urbanization (+6%, +4%), cropland (72%, 45%), nitrogen fertilization (g m −2 yr −1) (>10), and increased wet N-NO 3 − deposition (WND) (kg ha −1 yr −1) (+4.6, +3). The Haihe River Basin was found to have the highest N-NO 3 − on its surface (306) and in its groundwater (868) and nitrogen fertilization (32). Point pollution was concentrated in the Songhua and Liaohe River Basin with the highest WND (+7.9) but slow urbanization (+1%). N-NO 3 − increased during the flooding season compared with the no-flooding season in serious pollution areas. N-NO 3 − increased in the Liaohe River and middle and low Yangtze River but was reduced in the Weihe River. Therefore, stringent criteria and management, especially during the flooding season are urgently required to mitigate the degree of N-NO 3 − water pollution that occurs due to intensive agriculture and urbanization with increased N-NO 3 − deposition.

AB - Water N-NO 3 − (mg L −1) pollution is attracting global concern in the face of combating climate change and human health risks. However, there have been comparatively few comprehensively researched studies on water N-NO 3 − pollution with respect to N-NO 3 − deposition, soil nitrogen, and land-use changes. We collected a total of 7707 published sampling points on N-NO 3 − surface and groundwater during flooding and non-flooding seasons during 2000–2020 in China. The types of water N-NO 3 − pollution (>20) can be categorized as point pollution (ΔTN ≤ 0 or > 1.5) and non-point pollution (0 < ΔTN ≤ 1.5), which were then assessed with respect to soil nitrogen (ΔTN g kg −1) and water N-NO 3 − changes in this study. We found non-point pollution was concentrated in the Huaihe River Basin and Haihe River Basin with higher urbanization (+6%, +4%), cropland (72%, 45%), nitrogen fertilization (g m −2 yr −1) (>10), and increased wet N-NO 3 − deposition (WND) (kg ha −1 yr −1) (+4.6, +3). The Haihe River Basin was found to have the highest N-NO 3 − on its surface (306) and in its groundwater (868) and nitrogen fertilization (32). Point pollution was concentrated in the Songhua and Liaohe River Basin with the highest WND (+7.9) but slow urbanization (+1%). N-NO 3 − increased during the flooding season compared with the no-flooding season in serious pollution areas. N-NO 3 − increased in the Liaohe River and middle and low Yangtze River but was reduced in the Weihe River. Therefore, stringent criteria and management, especially during the flooding season are urgently required to mitigate the degree of N-NO 3 − water pollution that occurs due to intensive agriculture and urbanization with increased N-NO 3 − deposition.

KW - atmospheric nitrogen deposition

KW - human health

KW - land-use change

KW - nitrogen pollution

KW - urbanization

UR - http://www.scopus.com/inward/record.url?scp=85194157476&partnerID=8YFLogxK

U2 - 10.3390/w16101396

DO - 10.3390/w16101396

M3 - Article

VL - 16

JO - Water

JF - Water

SN - 2073-4441

IS - 10

M1 - 1396

ER -

Research@Leibniz University

Water Point and Non-Point Nitrogen Pollution Due to Land-Use Change and Nitrate Deposition in China from 2000 to 2020

Authors

Research Organisations

External Research Organisations

Details

Abstract

Keywords

ASJC Scopus subject areas

Sustainable Development Goals

Cite this

By the same author(s)

Microbial Community and Functions Depending on Tillage and Straw Returning Management: Consequences for Soil Health and Ecosystem Services

Oat/Soybean Intercropping Reshape the Soil Bacterial Community for Enhanced Nutrient Cycling

Deep-root respiration: The unknown CO₂ removed from the atmosphere

Changes in the soil inorganic carbon dynamics in the tilled layer of a semi-arid Mediterranean soil due to irrigation and a change in crop: Uncertainties in the calculation of pedogenic carbonates

Inversion of coastal cultivated soil salt content based on multi-source spectra and environmental variables

Water Point and Non-Point Nitrogen Pollution Due to Land-Use Change and Nitrate Deposition in China from 2000 to 2020

Authors

Research Organisations

External Research Organisations

Details

Abstract

Keywords

ASJC Scopus subject areas

Sustainable Development Goals

Cite this

By the same author(s)

Microbial Community and Functions Depending on Tillage and Straw Returning Management: Consequences for Soil Health and Ecosystem Services

Oat/Soybean Intercropping Reshape the Soil Bacterial Community for Enhanced Nutrient Cycling

Deep-root respiration: The unknown CO2 removed from the atmosphere

Changes in the soil inorganic carbon dynamics in the tilled layer of a semi-arid Mediterranean soil due to irrigation and a change in crop: Uncertainties in the calculation of pedogenic carbonates

Inversion of coastal cultivated soil salt content based on multi-source spectra and environmental variables

Deep-root respiration: The unknown CO₂ removed from the atmosphere