Assessment of streamflow components and hydrologic transit times using stable isotopes of oxygen and hydrogen in waters of a subtropical watershed in eastern China

Abstract: Streamflow components (e.g., young water vs old water) and hydrological transit times play an important role in water resource and water quality management. We collected a four-year record of stable isotopes of oxygen and hydrogen (δ 18 O and δ 2 H) in precipitation, groundwater and stream water for six catchments in the Yongan watershed of eastern China. The stable isotope records were used to identify spatio-temporal variations in the young water fraction (F yw , defined as the proportion of the transit-time… Show more

“…10 We used stable isotopes of H 2 O and NO 3 to assess hydrological processes and potential denitrification processes, respectively. 32,36 Groundwater, rainfall, and river water samples at the river outlets of Trib for , Trib res , Trib agr , and mainstream were collected for the analysis of δ 15 N−NO 3 and δ 18 O−NO 3 as well as δ 18 O−H 2 O and δ 2 H−H 2 O.…”

“…4 Given the significantly decreased N 2 O concentrations from groundwater to streamwater (Table S2), N 2 O should experience the attenuation process during groundwater delivery. Therefore, the groundwater N 2 O contribution (G) was expressed as groundwater N 2 O load with an assumed N 2 O attenuation coefficient (K 1 , year −1 ) during groundwater discharge to rivers 16,37,38 with delivery time T gw (year): 36,39…”

“…The monthly BFI was estimated using the hydrological module of the regional nutrient management (ReNuMa) model 39 and further verified with stable isotopes of oxygen and hydrogen (Supporting Information, Part IV, Table S5). 36 In addition, we estimated the proportions of riverine N load from groundwater (P gw ) and surface runoff (L Runoff ) from results obtained using dual nitrate stable isotopes. 32 The Markov chain Monte Carlo (MCMC) method was implemented to calibrate parameters (F, K gw , K 2 , v f , d, TP runoff , and TP r ) for the four sampling sites (Trib agr , Trib for , Trib res , and mainstream) using MATLAB (Ver.…”

“…Given the significantly decreased N 2 O concentrations from groundwater to streamwater (Table S2), N 2 O should experience the attenuation process during groundwater delivery. Therefore, the groundwater N 2 O contribution ( G ) was expressed as groundwater N 2 O load with an assumed N 2 O attenuation coefficient ( K 1 , year –1 ) during groundwater discharge to rivers ,, with delivery time T gw (year): , where Q gw is groundwater discharge (m 3 s –1 ) expressed as the product of Q and BFI (base flow index), and C gw is groundwater N 2 O concentration (μg N 2 O–N L –1 ). To address the temporal variation of the groundwater N 2 O attenuation rate, K 1 is expressed as a function of the constant N 2 O attenuation coefficient K gw (year –1 ) and groundwater DO concentration (mg L –1 ): …”

“…Model Calibration and Statistical Analyses. T gw , T runoff and transit time distribution (TTD) for different tributary and mainstream sites in the Yongan River were determined using δ18 O−H 2 O and δ 2 H−H 2 O with the lumpedparameter convolution method:36…”

Modeling Riverine N₂O Sources, Fates, and Emission Factors in a Typical River Network of Eastern China

“…10 We used stable isotopes of H 2 O and NO 3 to assess hydrological processes and potential denitrification processes, respectively. 32,36 Groundwater, rainfall, and river water samples at the river outlets of Trib for , Trib res , Trib agr , and mainstream were collected for the analysis of δ 15 N−NO 3 and δ 18 O−NO 3 as well as δ 18 O−H 2 O and δ 2 H−H 2 O.…”

“…4 Given the significantly decreased N 2 O concentrations from groundwater to streamwater (Table S2), N 2 O should experience the attenuation process during groundwater delivery. Therefore, the groundwater N 2 O contribution (G) was expressed as groundwater N 2 O load with an assumed N 2 O attenuation coefficient (K 1 , year −1 ) during groundwater discharge to rivers 16,37,38 with delivery time T gw (year): 36,39…”

“…The monthly BFI was estimated using the hydrological module of the regional nutrient management (ReNuMa) model 39 and further verified with stable isotopes of oxygen and hydrogen (Supporting Information, Part IV, Table S5). 36 In addition, we estimated the proportions of riverine N load from groundwater (P gw ) and surface runoff (L Runoff ) from results obtained using dual nitrate stable isotopes. 32 The Markov chain Monte Carlo (MCMC) method was implemented to calibrate parameters (F, K gw , K 2 , v f , d, TP runoff , and TP r ) for the four sampling sites (Trib agr , Trib for , Trib res , and mainstream) using MATLAB (Ver.…”

“…Given the significantly decreased N 2 O concentrations from groundwater to streamwater (Table S2), N 2 O should experience the attenuation process during groundwater delivery. Therefore, the groundwater N 2 O contribution ( G ) was expressed as groundwater N 2 O load with an assumed N 2 O attenuation coefficient ( K 1 , year –1 ) during groundwater discharge to rivers ,, with delivery time T gw (year): , where Q gw is groundwater discharge (m 3 s –1 ) expressed as the product of Q and BFI (base flow index), and C gw is groundwater N 2 O concentration (μg N 2 O–N L –1 ). To address the temporal variation of the groundwater N 2 O attenuation rate, K 1 is expressed as a function of the constant N 2 O attenuation coefficient K gw (year –1 ) and groundwater DO concentration (mg L –1 ): …”

“…Model Calibration and Statistical Analyses. T gw , T runoff and transit time distribution (TTD) for different tributary and mainstream sites in the Yongan River were determined using δ18 O−H 2 O and δ 2 H−H 2 O with the lumpedparameter convolution method:36…”

Modeling Riverine N₂O Sources, Fates, and Emission Factors in a Typical River Network of Eastern China

Spatial variability of runoff recharge sources and influence mechanisms in an arid mountain flow‐producing zone

Quantifying groundwater phosphorus flux to rivers in a typical agricultural watershed in eastern China