Tidal effects on the organic carbon mineralization rate under aerobic conditions in sediments of an intertidal estuary

Sasaki, Akiko; Hagimori, Yu; Nakatsubo, Takayuki; Hoshika, Akira

doi:10.1007/s11284-008-0545-6

Cited by 27 publications

(22 citation statements)

References 21 publications

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“…The effect of the tide on the sediment respiration rates was also considered in the model because a previous study reported that the tide affected the respiration rates, and the rate under air-exposed conditions was higher than the rate under submerged conditions (Sasaki et al 2009). …”

Section: Resultsmentioning

confidence: 99%

“…where R E(T) is the sediment respiration rate (mg CO 2 -C m -2 h -1 ) under air-exposed conditions at sediment temperature T (°C); R S(T 0 ) is the sediment respiration rate (mg CO 2 -C m -2 h -1 ) under submerged conditions at sediment temperature T 0 (°C); R E(30) is 38.8 mg CO 2 -C m -2 h -1 (mean of in situ sediment respiration rates at a sediment temperature 30°C); R S(30) is 16.9 mg CO 2 -C m -2 h -1 (based on a value for R E(T) /R S(T) of 2.3; Sasaki et al 2009); t is the duration of submerged conditions per day (h); and Q 10 is 1.8 (this study; Fig. 3).…”

Section: Resultsmentioning

confidence: 99%

“…We examined CO 2 emission rates from the sediment surface during low tide at each of the 10 stations with a portable infrared gas analyzer (Li-6400, Li-Cor, NE, USA). The measurements were conducted following the procedure described in our previous study, after the lowest sea level when the CO 2 emission rate becomes constant (Sasaki et al 2009). Replicate measurements (n = 8), which took a total of at least 20 min, were conducted at each station.…”

Section: Methodsmentioning

confidence: 99%

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Annual sediment respiration in estuarine sandy intertidal flats in the Seto Inland Sea, Japan

et al. 2011

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To quantify organic matter mineralization at estuarine intertidal flats, we measured in situ sediment respiration rates using an infrared gas analyzer in estuarine sandy intertidal flats located in the northwestern Seto Inland Sea, Japan. In situ sediment respiration rates showed spatial and seasonal variations, and the mean of the rates is 38.8 mg CO 2 -C m -2 h -1 in summer. In situ sediment respiration rates changed significantly with sediment temperature at the study sites (r 2 = 0.70, p \ 0.05), although we did not detect any significant correlations between the rates and sediment characteristics. We prepared a model for estimating the annual sediment respiration based on the in situ sediment respiration rates and their temperature coefficient (Q 10 = 1.8). The annual sediment respiration was estimated to be 92 g CO 2 -C m -2 year -1 . The total amount of organic carbon mineralization for the entire estuarine intertidal flats through sediment respiration (43 t C year -1 ) is equivalent to approximately 25% of the annual organic carbon load supplied from the river basin of the estuary.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Annual sediment respiration in estuarine sandy intertidal flats in the Seto Inland Sea, Japan

et al. 2011

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“…However, the temporal variations in CO 2 and CH 4 effluxes were positively correlated with change in the water table in the littoral zone of Lake Obuchi, Japan (Yamamoto et al 2009(Yamamoto et al , 2011. Also, CO 2 emission was reported to be greatly inhibited by submersion in the Kurose River estuary of Japan (Sasaki et al 2009). These studies were conducted across the semi-diurnal cycle, mainly in STP when soils were inundated or water-saturated most of the time.…”

Section: Introductionmentioning

confidence: 98%

Effects of semi-lunar tidal cycling on soil CO2 and CH4 emissions: a case study in the Yangtze River estuary, China

Hua

et al. 2015

Wetlands Ecol Manage

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Coastal wetlands, commonly inundated by periodic tides, have been recognized as important sources of greenhouse gases. However, little is known of tidal effects on in situ soil CO 2 and CH 4 emissions in a semi-lunar tidal cycle consisting of neap and spring tide periods (NTP and STP). A field study was conducted in the Yangtze River estuary to investigate temporal variations of soil CO 2 and CH 4 emissions along with the transition from NTP to STP in a semilunar tidal cycle. Soil moisture, salinity and sulfate were significantly greater in STP than in NTP, whereas soil redox potential had an opposite pattern because of frequent tidal inundation. Soil CO 2 and CH 4 effluxes decreased significantly in STP, being 29-34 and 28-35 %, respectively, compared with those in NTP. The decrease in soil CO 2 effluxes was likely attributable to two causes, an anaerobic environment inhibiting CO 2 production, and tidal inundation impeding CO 2 diffusion from the soil into the atmosphere. The inhibition of methanogenesis by increased soil salinity and sulfate was likely the primary reason of the decrease in CH 4 effluxes during STP. Our results suggest that the effects of semi-lunar tidal cycling significantly reduce soil carbon emissions, which may be one of the potential mechanisms underlying strong carbon accumulation in wetlands of the Yangtze River estuary.

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“…The marine water supply usually conveys dissolved oxygen (DO) to the system. Moreover, exposure to the air of intertidal sediments at low tide significantly increases mineralization rates (Sasaki et al, 2009). Remineralization processes can be enhanced by water mixing because of both oxygenation and increased contact of catabolites with various kinds of surface, such as bottom sediments, suspended matter and other physical and biological components (e.g.…”

Section: The Concept Of Saprobitymentioning

confidence: 99%

Saprobity: a unified view of benthic succession models for coastal lagoons

2012

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We briefly review and expand upon classic conceptual models describing the succession of benthic communities along a gradient of organic matter (OM) enrichment developed for freshwater (the Saprobity System), coastal marine (the Pearson-Rosenberg [P-R] model) and lagoon (the Guélorget-Perthuisot [G-P] model) ecosystems. Differences and similarities between various approaches and models are highlighted and the P-R and G-P models are unified under a single conceptual framework of habitat saprobity in coastal lagoons. We refer to saprobity as the state of an aquatic ecosystem resulting from the input and decomposition of OM and the removal of its catabolites. In addition to other factors, such as salinity, saprobity is viewed as a selection factor for species diversity. The higher the saprobity is, the more impaired the system is, with progressively poorer benthic communities characterized by species that are increasingly tolerant of reducing conditions and toxicity. In coastal lagoons, these processes are strongly driven by hydrodynamics, which govern the land-sea gradient. Based on our review and analysis, we find that saprobity can be a useful descriptor of ecosystem state as determined by OM metabolism, suitable for characterizing the natural conditions of coastal lagoons and assessing their quality.

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Tidal effects on the organic carbon mineralization rate under aerobic conditions in sediments of an intertidal estuary

Cited by 27 publications

References 21 publications

Annual sediment respiration in estuarine sandy intertidal flats in the Seto Inland Sea, Japan

Annual sediment respiration in estuarine sandy intertidal flats in the Seto Inland Sea, Japan

Effects of semi-lunar tidal cycling on soil CO2 and CH4 emissions: a case study in the Yangtze River estuary, China

Saprobity: a unified view of benthic succession models for coastal lagoons

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