Comparison of nitrogen fertilizer demand for wheat production between humid and semi-arid portions of the Argentinean Pampas using a mass balance method

Abstract. With the aim to understand the spatial and temporal variability of groundwater recharge, a high-resolution, spatially-distributed numerical model (MIKE SHE) representing surface water and groundwater was used to simulate responses to precipitation in a 2.16 km2 upland catchment on fractured sandstone near Los Angeles, California. Exceptionally high temporal and spatial resolution was used for this catchment modeling: an hourly time-step, a 20 × 20 meter grid in the horizontal plane and 240 numerical layers distributed vertically within the thick vadose zone and in the upper part of the groundwater zone. The finest-practical spatial and temporal resolution were selected to accommodate the large degree of surface and subsurface variability of catchment features. Physical property values for the different lithologies were assigned based on previous on-site investigations whereas the parameters controlling streamflow and evapotranspiration were derived from literature information. The calibration of streamflow at the outfall and of transient and average hydraulic head provided confidence in the reasonableness of these input values and in the ability of the model to reproduce observed processes. Confidence in the calibrated model was enhanced by validation through, (i) comparison of simulated average recharge to estimates based on the applications of the chloride mass-balance method from data from the groundwater and vadose zones within and beyond the catchment (Manna et al., 2016; Manna et al., 2017) and, (ii) comparison of the water isotope signature (18O and 2H) in shallow groundwater to the variability of isotope signatures for precipitation events over an annual cycle. The average simulated recharge across the catchment for the period 1995–2014 is 16 mm y−1 (4 % of the average annual precipitation), which is consistent with previous estimates obtained by using the chloride mass balance method (4.2 % of the average precipitation). However, one of the most unexpected results was that local recharge was simulated to vary from 0 to > 1000 mm y−1 due to episodic precipitation and overland runoff effects. This recharge occurs episodically with the major flux events at the bottom of the evapotranspiration zone, as simulated by MIKE SHE and confirmed by the isotope signatures, occurring only at the end of the rainy season. This is the first study that combines MIKE SHE simulations with the analysis of water isotopes in groundwater and rainfall to determine the timing of recharge processes in semi-arid regions. The study advances the understanding of recharge and unsaturated flow processes in semi-arid regions and enhances our ability to predict the effects of surface and subsurface features on recharge rates. This is crucial in highly heterogeneous contaminated sites because different contaminant source areas have widely varying recharge and, hence, groundwater fluxes impacting their mobility.

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Quantifying water quality and flow in multi-branched urban estuaries for a rainfall event with mass balance method

Water Science and Engineering ◽

10.1016/j.wse.2020.12.002 ◽

2020 ◽

Author(s):

Joan Cecilia Casila ◽

Gubash Azhikodan ◽

Katsuhide Yokoyama

Keyword(s):

Water Quality ◽

Mass Balance ◽

Rainfall Event ◽

Balance Method ◽

Mass Balance Method

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Carbon and nitrogen budgets of a winter rapeseed field in Estonia: a methodology for the quantification of all relevant pools and fluxes

10.5194/egusphere-egu21-15668 ◽

2021 ◽

Author(s):

Jordi Escuer-Gatius ◽

Krista Lõhmus ◽

Merrit Shanskiy ◽

Karin Kauer ◽

Hanna Vahter ◽

...

Keyword(s):

Mass Balance ◽

Environmental Parameters ◽

Balance Method ◽

Nitrogen Budgets ◽

N Cycle ◽

Carbon And Nitrogen ◽

Mass Balance Method ◽

C Cycle ◽

Winter Rapeseed ◽

C And N

Agricultural activities can have several adverse impacts on the environment; such as important greenhouse gas (GHG) emissions. To implement effective mitigation measures and create effective policies, it is necessary to know the full carbon and nitrogen budgets of agro-ecosystems. However, very often, information regarding the pools or fluxes involved in the carbon and nitrogen cycles is limited, and essential complementary data needed for a proper interpretation is lacking.This study aimed to quantify all the relevant pools and fluxes of a winter rapeseed, a widely spread crop in the Europe and Baltic regions. The N2O and CH4 fluxes were measured weekly using the closed static chamber method from August 2016 to August 2017 in a winter rapeseed field in Central Estonia. Additionally, nutrient leaching and soil chemical parameters, as well as environmental parameters like soil moisture, electrical conductivity and temperature were monitored. At the end of the season, the rapeseed and weed biomasses were collected, weighed and analyzed. The remaining relevant fluxes in the N cycle were calculated using various non-empirical methods: NH3 volatilization was estimated from slurry and environmental parameters, N deposition and NOx emissions were obtained from national reports, and N2 emissions were calculated with the mass balance method. Regarding the C cycle, gross primary production (GPP) of the rapeseed field was also calculated by the mass balance method. Simultaneously, for comparison and validation purposes, GPP was estimated from the data provided by MOD17A2H v006 series from NASA, and N2 was estimated from the measured emissions of N2O using the N2:N2O ratio calculated from the DAYCENT model equations.N2 emissions and GPP were the biggest fluxes in the N and C cycles, respectively. N2 emissions were followed by N extracted with plant biomass in the N cycle, while in the carbon cycle soil and plant respiration and NPP were the highest fluxes after GPP. The carbon balance was positive at the soil level, with a net increase in soil carbon during the period, mainly due to GPP carbon capture. Contrarily, the nitrogen balance resulted in a net loss of N due to the losses related to gaseous emissions (N2 and N2O) and leaching.To conclude, it was possible to close the C and N budgets, despite the inherent difficulties of estimating the different C and N environmental pools and fluxes, and the uncertainties deriving from some of the fluxes estimations.

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Studies with a Mass Balance Method of Measuring Fibrinogen Synthesis

Ciba Foundation Symposium 9 - Protein Turnover - Novartis Foundation Symposia ◽

10.1002/9780470719923.ch6 ◽

2008 ◽

pp. 91-111

Author(s):

E. B. Reeve ◽

Y. Chen

Keyword(s):

Mass Balance ◽

Balance Method ◽

Mass Balance Method

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A simplified implementation of the stationary liquid mass balance method for on-line OUR monitoring in animal cell cultures

Journal of Chemical Technology & Biotechnology ◽

10.1002/jctb.5551 ◽

2018 ◽

Vol 93 (6) ◽

pp. 1757-1766 ◽

Cited By ~ 4

Author(s):

Andreu Fontova ◽

Martí Lecina ◽

Jonatan López-Repullo ◽

Iván Martínez-Monge ◽

Pere Comas ◽

...

Keyword(s):

Mass Balance ◽

Cell Cultures ◽

Animal Cell ◽

Balance Method ◽

Mass Balance Method ◽

Liquid Mass ◽

Stationary Liquid ◽

Animal Cell Cultures ◽

On Line

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Determination of the volatilization of ammonia from surface-applied cattle slurry by the micrometeorological mass balance method

The Journal of Agricultural Science ◽

10.1017/s0021859600081181 ◽

1987 ◽

Vol 109 (1) ◽

pp. 205-207 ◽

Cited By ~ 24

Author(s):

R. J. Stevens ◽

H. J. Logan

Keyword(s):

Mass Balance ◽

Field Trials ◽

Balance Method ◽

Cattle Slurry ◽

Ammonia Loss ◽

Mass Balance Method ◽

Direct Measurements ◽

Balance Technique ◽

Land Surfaces ◽

Grass Growth

Agronomic experiments have shown that nitrogen applied in organic manures gives variable responses in grass growth (van Dijk & Sturm, 1983; Smith, Unwin & Williams, 1985). In a series of field trials in southern England, the average apparent recovery in herbage of the nitrogen from cow slurry was only 13% (Unwin, Pain & Whinham, 1986). The volatilization of ammonia from spread slurry is one possible mechanism for the nitrogen inefficiency (Freney, Simpson & Denmead, 1983; Ryden, 1984). Direct measurements of ammonia loss from land surfaces can be made by micrometeorological methods (Denmead, 1983) and, using the micrometeorological mass balance technique, high rates of ammonia loss were recorded after the land spreading of liquid dairy cattle manure in Canada (Beauchamp, Kidd & Thurtell, 1982). The micrometeorological mass balance method has been used in England to measure ammonia loss from a grazed sward (Ryden & McNeill, 1984). This paper presents the results of an experiment where the same method was used to measure the ammonia loss after land-spreading cattle slurry in Northern Ireland.

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THE CHEMICAL MASS BALANCE METHOD FOR ESTIMATING ATMOSPHERIC PARTICLE SOURCES IN SOUTHERN CALIFORNIA

Chemical Engineering Communications ◽

10.1080/00986449608936548 ◽

1996 ◽

Vol 151 (1) ◽

pp. 187-209 ◽

Cited By ~ 15

Author(s):

GEORGE M. HIDY ◽

CHANDRA VENKATARAMAN

Keyword(s):

Mass Balance ◽

Southern California ◽

Balance Method ◽

Chemical Mass Balance ◽

Atmospheric Particle ◽

Mass Balance Method

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Leaf-litter accretion and decomposition in interior and coastal old-growth redwood stands

Canadian Journal of Forest Research ◽

10.1139/x93-073 ◽

1993 ◽

Vol 23 (3) ◽

pp. 552-557 ◽

Cited By ~ 10

Author(s):

Michael D. Pillers ◽

John D. Stuart

Keyword(s):

Mass Balance ◽

Litter Decomposition ◽

Balance Method ◽

Litter Fall ◽

Old Growth ◽

Litter Bag ◽

Mass Balance Method ◽

Balance Analysis ◽

Average Relative Humidity ◽

Mass Balance Analysis

Litter fall and litter decomposition were measured in old-growth coastal redwood (Sequoiasempervirens (D. Don) Endl.) forests. Hillside and bottomland areas at inland and coastal locations were selected as representative sites. Both litter-bag and insitu mass-balance analyses were used to determine decomposition rates. Average annual litter fall at the four sites ranged from 3120 to 4690 kg•ha−1•year−1. Decomposition rate constants (k) calculated from the mass-balance analysis ranged from 0.117 to 0.238 year−1. Values of k estimated from the litter-bag analysis ranged from 0.273 to 0.405 year−1. Equilibrium litter loads from mass-balance analysis ranged from 15 700 to 30 000 kg•ha−1. Equilibrium litter loads estimated from litter-bag analysis ranged from 7760 to 14 500 kg•ha−1. Litter-layer equilibrium was between 12 and 26 years using the mass-balance analysis and between 7 and 11 years with the litter-bag study. The mass-balance method for calculating decomposition constants showed that litter at coastal sites decomposed faster than at inland sites. There were no differences between upland and bottomland sites. The litter-bag method, in contrast, indicated that litter at inland sites decomposed faster than at coastal sites. Significant regressions of litter decomposition constants as functions of summer average relative humidity, temperature, vapor-pressure deficit, and litter moisture were found with the mass-balance method. There were no significant regressions of temperature and moisture variables with litter decomposition constants calculated with the litter-bag analysis.

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