Diffuse hydrological mass transport through catchments: scenario analysis of coupled physical and biogeochemical uncertainty effects

Persson, Klas; Jarsjö, Jerker

doi:10.5194/hess-15-3195-2011

Cited by 26 publications

(35 citation statements)

References 51 publications

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“…1), which is a value that is consistent with historical observations of N attenuation in Amu Darya River Basin (Törnqvist et al 2015). Independent assessments additionally show that this attenuation product value agrees with observed attenuation of nitrogen at the field scale (Darracq et al 2010a, b;Persson et al 2011). Specifically, Fig.…”

Section: Changing Regional Climatesupporting

confidence: 73%

Climate-driven change of nitrogen retention–attenuation near irrigated fields: multi-model projections for Central Asia

Jarsjö

Törnqvist

2017

Environ Earth Sci

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Agricultural intensification in semiarid regions comes at a cost of relatively high water losses through evapotranspiration and can contribute to releases of nutrients and pesticides that affect downstream water quality. In addition, highly managed river basins may be particularly sensitive to future climate change. However, effects on retention-attenuation of nutrients are difficult to quantify due to the complexity and variability of relevant processes. We here use the example case of the large (covering 1.3% of the earth's land surface) and extensively irrigated Aral Sea Drainage Basin (ASDB) in Central Asia, together with 73 general circulation model (GCM) projection results and field-data driven nitrogen retention-attenuation modeling, to investigate to which extent projected future climate change (for years 2025, 2050 and 2100) can influence nitrogen loads and concentrations in the water systems of the basin. Results for the principal Amu Darya River of the ASDB suggest that riverine concentrations of nitrogen will decrease considerably throughout the coming century. This is due to projected climate-related decreases in runoff and river discharge, which increases internal nitrogen recirculation ratios, average transport distances and nitrogen retention-attenuation. However, in groundwater near the agricultural fields, there is in contrast a risk of considerable nitrogen accumulation. More generally, the sensitivity of nitrogen concentrations in the ADRB to climate-driven changes in runoff and discharge is likely to be shared with many highly managed basins in arid and semiarid regions of Central Asia, and the world.

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Section: Changing Regional Climatesupporting

confidence: 73%

Climate-driven change of nitrogen retention–attenuation near irrigated fields: multi-model projections for Central Asia

Jarsjö

Törnqvist

2017

Environ Earth Sci

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“…(5) Equations (3)- (5) provide a generic framework for solute release and transport through a catchment, which can be used to quantify different cases of subsurface DOC and DIC release and subsequent transport into streams. Different types and forms of the pdf g(τ ) are possible and relevant for different catchment conditions (Lindgren et al, 2004;Cvetkovic, 2011;Persson et al, 2011). In the following section, we test and illustrate results of the catchment-average solution Eq.…”

Section: A Mechanistic Framework For Modeling Of Solute Release and Tmentioning

confidence: 99%

Subsurface release and transport of dissolved carbon in a discontinuous permafrost region

Jantze

Lyon

Destouni

2013

Hydrol. Earth Syst. Sci.

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Abstract. Subsurface hydrological flow pathways and advection rates through the landscape affect the quantity and timing of hydrological transport of dissolved carbon. This study investigates hydrological carbon transport through the subsurface to streams and how it is affected by the distribution of subsurface hydrological pathways and travel times through the landscape. We develop a consistent mechanistic, pathway-and travel time-based modeling approach for release and transport of dissolved organic carbon (DOC) and dissolved inorganic carbon (DIC). The model implications are tested against observations in the subarctic Abiskojokken catchment in northernmost Sweden (68 • 21 N, 18 • 49 E) as a field case example of a discontinuous permafrost region. The results show: (a) For DOC, both concentration and load are essentially flow-independent because their dynamics are instead dominated by the annual renewal and depletion. Specifically, the flow independence is the result of the small characteristic DOC respiration-dissolution time scale, in the range of 1 yr, relative to the average travel time of water through the subsurface to the stream. (b) For DIC, the load is highly flow-dependent due to the large characteristic weatheringdissolution time, much larger than 1 yr, relative to the average subsurface water travel time to the stream. This rate relation keeps the DIC concentration essentially flow-independent, and thereby less fluctuating in time than the DIC load.

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“…Due to inherent complexities of coupled subsurface-surface water systems (Jarsjö et al 2008;Destouni et al 2010;Persson et al 2011), effective remediation measures need to be underpinned by a relatively detailed understanding of nutrient transport processes, and not least Fig. 4 Anthropogenic P-load contributions from catchments of the NBS-RBD to their outlets (x-axis) and to the Baltic Sea (y-axis).…”

Section: Discussionmentioning

confidence: 99%

“…A failure to fully meet these goals will occur for three main reasons: (i) Relatively radical measures are needed, such as extensive land use change (e.g., Wulff et al 2007), which are not feasible from a socio-economic perspective (Volk et al 2009). For example, in the most populated river basin district (RBD) of Sweden, the Northern Baltic Sea (NBS) RBD, the reduction demand of P from the RBD authority (RBDA) of 100 tons per year is larger than the estimated anthropogenic load contribution from agriculture within the RBD to the Baltic Sea (Larsson and Pettersson 2009). (ii) Retention processes and slow transport through the subsurface water systems (Darracq et al , 2010Destouni et al 2010;Persson et al 2011) can delay targeted effects of mitigation measures considerably. Furthermore, ecosystems need to respond to measures taken, which may considerably prolong the time it takes to reach WFD targets (Hering et al 2010).…”

Section: Problem Statement and Research Questionmentioning

confidence: 99%

Saving the Baltic Sea, the Inland Waters of Its Drainage Basin, or Both? Spatial Perspectives on Reducing P-Loads in Eastern Sweden

Andersson

Jarsjö

Petersson

2014

AMBIO

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Nutrient loads from inland sources to the Baltic Sea and adjacent inland waters need to be reduced in order to prevent eutrophication and meet requirements of the European Water Framework Directive (WFD) and the Baltic Sea Action Plan (BSAP). We here investigate the spatial implications of using different possible criteria for reducing water-borne phosphorous (P) loads in the Northern Baltic Sea River Basin District (NBS-RBD) in Sweden. Results show that most catchments that have a high degree of internal eutrophication do not express high export of P from their outlets. Furthermore, due to lake retention, lake catchments with high P-loads per agricultural area (which is potentially of concern for the WFD) did not considerably contribute to the P-loading of the Baltic Sea. Spatially uniform water quality goals may, therefore, not be effective in NBS-RBD, emphasizing more generally the need for regional adaptation of WFD and BSAP-related goals.

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Diffuse hydrological mass transport through catchments: scenario analysis of coupled physical and biogeochemical uncertainty effects

Cited by 26 publications

References 51 publications

Climate-driven change of nitrogen retention–attenuation near irrigated fields: multi-model projections for Central Asia

Climate-driven change of nitrogen retention–attenuation near irrigated fields: multi-model projections for Central Asia

Subsurface release and transport of dissolved carbon in a discontinuous permafrost region

Saving the Baltic Sea, the Inland Waters of Its Drainage Basin, or Both? Spatial Perspectives on Reducing P-Loads in Eastern Sweden

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