Greenhouse gas fluxes from the eutrophic Temmesjoki River and its Estuary in the Liminganlahti Bay (the Baltic Sea)

Silvennoinen, Hanna; Liikanen, Anu; Rintala, Jaana; Martikainen, Pertti J.

doi:10.1007/s10533-008-9244-1

Cited by 85 publications

(63 citation statements)

References 65 publications

(130 reference statements)

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“…Concentrations and emissions of N 2 O in estuaries are generally found to be related to the estuarine dissolved inorganic nitrogen (DIN) levels (Seitzinger and Kroeze, 1998;Dong et al, 2004). Mean Silvennoinen et al (2008) DIN concentrations in the Changjiang estuary in this study were 12.5 ± 5.8, 12.6 ± 8.6 and 15.6 ± 8.0 µM for June, August and October 2006, respectively. Although the correlation between N 2 O concentrations and DIN was not obvious at most cruises, N 2 O and DIN data in the Changjiang Estuary fit well in the plot of estuarine N 2 O versus DIN on a global scale (Fig.…”

Section: Computation Of Sea-to-air Fluxesmentioning

confidence: 58%

Nitrous oxide in the Changjiang (Yangtze River) Estuary and its adjacent marine area: Riverine input, sediment release and atmospheric fluxes

Zhang

Liu

et al. 2010

Biogeosciences

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Abstract. Dissolved nitrous oxide (N 2 O) was measured in the waters of the Changjiang (Yangtze River) Estuary and its adjacent marine area during five surveys covering the period of [2002][2003][2004][2005][2006]. Dissolved N 2 O concentrations ranged from 6.04 to 21.3 nM, and indicate great temporal and spatial variations. Distribution of N 2 O in the Changjiang Estuary was influenced by multiple factors and the key factor varied between cruises. Dissolved riverine N 2 O was observed monthly at station Xuliujing of the Changjiang, and ranged from 12.4 to 33.3 nM with an average of 19.4 ± 7.3 nM. N 2 O concentrations in the river waters showed obvious seasonal variations with higher values occurring in both summer and winter. Annual input of N 2 O from the Changjiang to the estuary was estimated to be 15.0 × 10 6 mol/yr. N 2 O emission rates from the sediments of the Changjiang Estuary in spring ranged from −1.88 to 2.02 µmol m −2 d −1 , which suggests that sediment can act as either a source or a sink of N 2 O in the Changjiang Estuary. Average annual sea-toair N 2 O fluxes from the studied area were estimated to be 7.7 ± 5.5, 15.1 ± 10.8 and 17.0 ± 12.6 µmol m −2 d −1 using LM86, W92 and RC01 relationships, respectively. Hence the Changjiang Estuary and its adjacent marine area are a net source of atmospheric N 2 O.

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Section: Computation Of Sea-to-air Fluxesmentioning

confidence: 58%

Nitrous oxide in the Changjiang (Yangtze River) Estuary and its adjacent marine area: Riverine input, sediment release and atmospheric fluxes

Zhang

Liu

et al. 2010

Biogeosciences

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“…Coastal waters receive large inputs of terrestrial material, such as suspended sediments and nutrients in solution or in particulate matter, in organic or inorganic forms and through river and groundwater discharge, as well as by exchange with the atmosphere, the sediments and the open ocean. They therefore tend to show greater temporal and spatial variability than open oceans, and are more affected by human activities (Cameron and Pritchard, 1963;Alongi, 1998;Chen and Tsunogai, 1998;Rabouille et al, 2001;Chen, 2002Chen, , 2003Chen, , 2004Slomp and Van Cappellen, 2004;Beusen et al, 2005;Chavez et al, 2007;Doney et al, 2007;Radach and Patsch, 2007;Peng et al, 2008;Seitzinger et al, 2010;Dürr et al, 2011;Jiang et al, 2013). However, unlike the open oceans, in which millions of observations have been made and the air-sea exchanges of CO 2 have been valued using various developed models (such as by Khatiwala et al, 2013;Schuster et al, 2013;Wanninkhof et al, 2013), coastal waters have been relatively poorly examined.…”

Section: C-t a Chen Et Al: Air-sea Exchanges Of Co 2 In The Worldmentioning

confidence: 99%

Air–sea exchanges of CO<sub>2</sub> in the world's coastal seas

et al. 2013

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Abstract. The air-sea exchanges of CO 2 in the world's 165 estuaries and 87 continental shelves are evaluated. Generally and in all seasons, upper estuaries with salinities of less than two are strong sources of CO 2 (39 ± 56 mol C m −2 yr −1 , positive flux indicates that the water is losing CO 2 to the atmosphere); mid-estuaries with salinities of between 2 and 25 are moderate sources (17.5 ± 34 mol C m −2 yr −1 ) and lower estuaries with salinities of more than 25 are weak sources . Mixing with low-pCO 2 shelf waters, water temperature, residence time and the complexity of the biogeochemistry are major factors that govern the pCO 2 in estuaries, but wind speed, seldom discussed, is critical to controlling the air-water exchanges of CO 2 . The total annual release of CO 2 from the world's estuaries is now estimated to be 0.10 Pg C yr −1 , which is much lower than published values mainly because of the contribution of a considerable amount of heretofore unpublished or new data from Asia and the Arctic. The Asian data, although indicating high pCO 2 , are low in sea-to-air fluxes because of low wind speeds. Previously determined flux values rely heavily on data from Europe and North America, where pCO 2 is lower but wind speeds are much higher, such that the CO 2 fluxes are higher than in Asia. Newly emerged CO 2 flux data in the Arctic reveal that estuaries there mostly absorb rather than release CO 2 .Most continental shelves, and especially those at high latitude, are undersaturated in terms of CO 2 and absorb CO 2 from the atmosphere in all seasons. Shelves between 0 and 23.5 • S are on average a weak source and have a small flux per unit area of CO 2 to the atmosphere. Water temperature, the spreading of river plumes, upwelling, and biological production seem to be the main factors in determining pCO 2 in the shelves. Wind speed, again, is critical because at high latitudes, the winds tend to be strong. Since the surface water pCO 2 values are low, the air-to-sea fluxes are high in regions above 50 • N and below 50 • S. At low latitudes, the winds tend to be weak, so the sea-to-air CO 2 flux is small. Overall, the world's continental shelves absorb 0.4 Pg C yr −1 from the atmosphere.

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“…While agricultural activities, including rice cultivation, animal husbandry, and N fertilization, represent the primary anthropogenic source of CH 4 and N 2 O in anthropogenically impacted river systems (Silvennoinen et al, 2008;Garnier et al, 2013), the relative contribution of wastewater and landfills often increases drastically in urbanized watersheds (Yu et al, 2013;Smith et al, 2017;Wang et al, 2017b). Downstream changes in CH 4 concentrations along the lower reach reflect localized 430 impacts of urban tributary inputs, which caused pulsatile increases in the mainstem CH 4 concentrations and decreases in δ 13 C in CH 4 downstream of the tributary inflow (Fig.…”

Section: Tracking Sources Of Dom and Ghgs Using C Isotopesmentioning

confidence: 99%

“…Measurements of multiple GHGs in highly human-impacted river systems have provided drastically different pictures of the longitudinal and seasonal patterns of GHGs from those observed in large natural rivers (Silvennoinen et al, 2008;Burgos et al, 2015;Crawford et al, 2016;Smith et al, 2017;Wang et al, 2017b). A growing number of dams constructed on rivers worldwide have altered riverine flows of water and materials to the oceans, trapping over 100 billion metric tons of sediment and up to 3 billion metric tons of C in the reservoirs constructed over the last five decades (Syvitski et al, 2005).…”

Section: Introductionmentioning

confidence: 99%

Longitudinal discontinuities in riverine greenhouse gas dynamics generated by dams and urban wastewater

Jin¹,

Yoon²,

Begum³

et al. 2018

Preprint

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Abstract.Riverine emissions of CO 2 and other greenhouse gases (GHGs) represent crucial, but poorly constrained components of the global GHG budgets. Three major GHGs -CO 2 , CH 4 , and N 2 O -have rarely been measured simultaneously in river systems modified by human activities, adding uncertainties to the estimates of global riverine GHG emissions. Measurements of C isotopes in dissolved organic carbon (DOC), CO 2 , and CH 4 were combined with basin-wide surveys of three GHGs in the Han 15 River, South Korea to investigate the effects of dams and urban water pollution as primary controls on GHG dynamics in the highly human-impacted river basin with a population >25 million. Monthly monitoring and two-season comparison were conducted at 6 and 15 sites, respectively, to measure surface water concentrations of three GHGs, along with DOC and its optical properties. The basin-wide surveys were complemented with a boat cruise along the lower reach and synoptic samplings along a polluted tributary delivering effluents from a large wastewater treatment plant (WWTP) to the lower reach. The basin-20 wide surveys of three GHGs revealed distinct increases in the concentrations of three gases along the lower reach receiving urban tributaries enriched in GHGs and DOC. Compared to the spatial patterns of GHGs observed in the upper and lower reaches, the levels of pCO 2 were consistently lower across the impounded middle reach, whereas concentrations of CH 4 and N 2 O were relatively high in some impoundment-affected sites. Similar levels and temporal variations in three GHGs at the WWTP effluents and the receiving tributary indicated a disproportionate contribution of the WWTP to the tributary exports of 25 DOC and GHGs. Measurements of δ 13 C in surface water CO 2 and CH 4 sampled during the cruise along the lower reach, combined with δ 13 C and Δ 14 C in dissolved organic matter (DOM) sampled across the basin, implied that longitudinal decreases in Δ 14 C in DOM mighte be associated with wastewater-derived, old DOM in urban tributaries, which, together with enhanced photosynthesis and CH 4 oxidation in the eutrophic lower reach, appear to constrain downstream changes in δ 13 C in CO 2 and CH 4 . The overall results suggest that dams and urban wastewater may create longitudinal discontinuities in riverine metabolic 30 processes leading to large spatial variations in three GHGs. Further research is required to evaluate the relative contributions Biogeosciences Discuss., https://doi

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Greenhouse gas fluxes from the eutrophic Temmesjoki River and its Estuary in the Liminganlahti Bay (the Baltic Sea)

Cited by 85 publications

References 65 publications

Nitrous oxide in the Changjiang (Yangtze River) Estuary and its adjacent marine area: Riverine input, sediment release and atmospheric fluxes

Nitrous oxide in the Changjiang (Yangtze River) Estuary and its adjacent marine area: Riverine input, sediment release and atmospheric fluxes

Air–sea exchanges of CO<sub>2</sub> in the world's coastal seas

Longitudinal discontinuities in riverine greenhouse gas dynamics generated by dams and urban wastewater

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Greenhouse gas fluxes from the eutrophic Temmesjoki River and its Estuary in the Liminganlahti Bay (the Baltic Sea)

Cited by 85 publications

References 65 publications

Nitrous oxide in the Changjiang (Yangtze River) Estuary and its adjacent marine area: Riverine input, sediment release and atmospheric fluxes

Nitrous oxide in the Changjiang (Yangtze River) Estuary and its adjacent marine area: Riverine input, sediment release and atmospheric fluxes

Air–sea exchanges of CO&lt;sub&gt;2&lt;/sub&gt; in the world's coastal seas

Longitudinal discontinuities in riverine greenhouse gas dynamics generated by dams and urban wastewater

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Product

Resources

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Air–sea exchanges of CO<sub>2</sub> in the world's coastal seas