Deciphering the effects of hydrological, biogeochemical and anthropogenic factors on nitrogen species in a subtropical watershed using multiple isotopes
ID:1495 View Protection:ATTENDEE Updated Time:2024-10-14 23:09:05 Hits:782 Poster Presentation

Start Time:2025-01-16 19:50(Asia/Shanghai)

Duration:15min

Session:S18 Session 18-The River-Estuary-Bay Continuum: Unveiling the Carbon and Nitrogen Cycles Under Global Change » S18-PThe River-Estuary-Bay Continuum: Unveiling the Carbon and Nitrogen Cycles Under Global Change

No files

Abstract
The sources and transformations of various nitrogen (N) species in rivers under the influence of anthropogenic inputs are the main concern of eutrophication research, especially in intermediate- and small-sized rivers, and are essential to understand for practical management. A key challenge lies in determining how N species can be altered by diverse biogeochemical processes along flow paths under different hydrological controls (e.g. river discharge). To better understand the response of in-stream N dynamics, we examined N transformation processes and identified the sources of various N species in the Jiulong River (JLR), a eutrophic river in China composed of two main tributaries: the North Stream (NS) and the West Stream (WS), using multiple isotopes (δ15NNO3, δ18ONO3, δ15NNO2, δ15NNH4, δ15NPN, δDH2O and δ18OH2O). Our results reveal that hydrological and biogeochemical processes exert a joint control on river N dynamics. Key processes, such as nitrification and ammonium (NH4+) uptake, predominated in both tributaries during non-rainfall periods, while during rain events, nitrification remained significant. However, denitrification occurred differently in the NS (mainly on particles) and the WS (primarily in sediment), and was influenced by factors such as sediment characteristics and water flow patterns. We also observed differences in the uptake velocity of denitrification and NH4+ between the two tributaries, highlighting the variable importance of these two processes. The main sources of N species varied based on hydrological conditions, with different contributions in the NS and WS. During non-rainfall periods, point sources significantly controlled N species compositions in both tributaries, with manure & sewage contributing 46 % and 42 % of the NH4+, 30 % and 50 % of the nitrate (NO3- ), and sewage accounting for 62 % and 56 % of the particulate N (PN) in the NS and WS, respectively. During rainstorms, non-point sources became the predominant contributors of NO3- in both tributaries (soil organic N: NS = 48 %, WS = 38 %; chemical fertilizers: NS = 29 %, WS = 26 %) and PN (soil: NS = 52 %, WS = 57 %). The insights revealed using multiple isotopes serve as a foundational basis for advanced modeling and scenario development when managing subtropical rivers under complex human interferences and climate change.
Keywords
Nitrogen dynamics;,Multiple isotopes,Hydrology,Subtropical River
Speaker
Anqi Yao
Undergraduate Shantou University

Submission Author
Anqi Yao Shantou University
Xiuli Yan Shantou University
Hongyan Bao Xiamen University
Dawei Li Ocean University of China
Jr-Chuan Huang National Taiwan University
Junwen Wu Shantou University
Lili Han Hainan University
Shuh-Ji Kao XiaMen University;Hainan University
Submit Comment
Verify Code Change Another
All Comments
Important Date
  • Conference Date

    Jan 13

    2025

    to

    Jan 17

    2025

  • Sep 27 2024

    Draft paper submission deadline

  • Feb 17 2025

    Registration deadline

Sponsored By
State Key Laboratory of Marine Environmental Science, Xiamen University
Organized By
State Key Laboratory of Marine Environmental Science, Xiamen University
Department of Earth Sciences, National Natural Science Foundation of China
Contact Information