Legacy Effects of Late Macroalgal Blooms on Dissolved Inorganic Carbon Pool through Alkalinity Enhancement in Coastal Ocean

Xiong, Tian Ying; Li, Hongmei; Yue, Yufei; Hu, Yunbin; Zhai, Weidong; Xue, Liang; Jiao, Nianzhi; Zhang, Yongyu

doi:10.1021/acs.est.2c09261

Cited by 14 publications

(3 citation statements)

References 57 publications

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“…To account for conservative mixing of water masses with different salinities on TA and DIC, a normalization scheme against a fixed salinity (nTA and nDIC) (Chen and Millero 1979; Friis et al 2003) is commonly employed to investigate the impacts of metabolic activities on seawater carbonate chemistry (e.g., Courtney et al 2021) or to differentiate metabolic effect from anthropogenic CO 2 signals (Peng et al 1998). Moreover, the slope of nTA–nDIC relationship is also widely used to infer major biogeochemical processes affecting carbonate chemistry in coastal environment (Hunt et al 2022; Szymczycha et al 2023; Xiong et al 2023; Yin et al 2023). This data interpretation method is based on the premise that different biogeochemical processes affect TA and DIC differently (Table 1).…”

Section: Process Formula ∆Ta : ∆Dicmentioning

confidence: 99%

Interpreting biogeochemical processes through the relationship between total alkalinity and dissolved inorganic carbon: Theoretical basis and limitations

Yin,

Jin,

2024

Limnology & Ocean Methods

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The marine carbonate system is influenced by anthropogenic CO2 uptake, biogeochemical processes, and physical changes that involve freshwater input and removal. Two frequently used parameters to quantify seawater carbonate system are total alkalinity (TA) and total dissolved inorganic carbon (DIC). To account for the physical changes, both TA and DIC are usually normalized to a reference salinity (i.e., nTA and nDIC), and then the relationship between nTA and nDIC is used to identify major biogeochemical processes that regulate the carbonate system, based on process‐specific reaction stoichiometry. However, the theoretical basis of this interpretation has not been holistically examined. In this study, we validated this method under idealized conditions and discussed the associated assumptions and limitations. Furthermore, we applied this method to interpret field TA and DIC data from a lagoonal estuary in the northwestern Gulf of Mexico. Our results demonstrated that evaluating field data that encompass multiple stations and time periods could be problematic. In addition, various combinations of biogeochemical processes can lead to the same nTA–nDIC relationship, even though the relative importance of each individual process may vary significantly. Therefore, the stoichiometric relationship relying solely on TA and DIC data is not a definitive approach for uncovering dominant biogeochemical processes. Instead, measurements of process‐specific parameters are necessary.

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Section: Process Formula ∆Ta : ∆Dicmentioning

confidence: 99%

Interpreting biogeochemical processes through the relationship between total alkalinity and dissolved inorganic carbon: Theoretical basis and limitations

Yin,

Jin,

2024

Limnology & Ocean Methods

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“…Given the massive biomass of these macroalgae, which can reach millions of tons wet weight (Wang et al, 2018;Xing et al, 2018;Bach et al, 2021), their contribution of CDOM is likely to have a substantial impact on regional marine DOM budgets. While the fate of U. prolifera-and Sargassumderived CDOM with respect to microbial degradation has been relatively well studied (e.g., Zhang and Wang, 2017;Chen et al, 2020;Xiong et al, 2023), less attention has been paid to their photochemical degradation. Shank et al (2010b) found that CDOM leached from Sargassum (S-CDOM hereinafter) could be readily photodegraded by simulated solar radiation, losing absorbance and producing CO 2 and CO. Sun et al (2020) reported that both the abundance and molecular weight of U. prolifera-derived CDOM (UP-CDOM hereinafter) decreased under solar irradiation.…”

Section: Introductionmentioning

confidence: 99%

High photoreactivity of chromophoric dissolved organic matter derived from Ulva prolifera and Sargassum

Zhang,

Fang,

Liu

et al. 2024

Front. Mar. Sci.

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The epipelagic macroalgae of Ulva prolifera and Sargassum are the primary contributors to widespread seaweed tides globally. Both ocean plants release large amounts of chromophoric dissolved organic matter (CDOM) into the surrounding seawater. The photochemical reactivity of this CDOM, however, has not been adequately addressed. In this study, we extracted CDOM from Ulva prolifera and Sargassum, examined their ultraviolet (UV)-visible absorption characteristics, and quantified their broadband apparent quantum yields (AQY) of absorbance photobleaching and photomineralization (in terms of CO2, CO, and CH4 photoproduction). On a per-unit-weight basis, Sargassum leached 3.5 times more CDOM than did Ulva prolifera in terms of the absorption coefficient averaged over 254–500 nm. Both Ulva prolifera and Sargassum CDOM were characterized by quasi-exponential decay absorption spectra, with Sargassum CDOM exhibiting a distinct shoulder over 310–350 nm suggestive of mycosporine amino acids. The Sargassum CDOM had a higher photobleaching AQY but lower photomineralization AQYs compared to Ulva prolifera CDOM. The photobleaching and photomineralization AQYs of both macroalgal CDOM are, however, orders of magnitude higher than those of CDOM in various natural waters. Potential photoproduction rates of CO2 and CO from the Ulva prolifera CDOM and Sargassum CDOM during the bloom periods are several times to orders of magnitude higher than the air-sea fluxes of these gases in the absence of the macroalgae. This study demonstrates that CDOM released by Ulva prolifera and Sargassum is extremely prone to photobleaching and photomineralization, rendering floating mats of these plants in oceans as potential “hotspots” of greenhouse gas emissions to the atmosphere. This photochemical feedback should be considered when assessing ocean afforestation as a CO2 removal approach to mitigate climate warming.

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“…Macroalgae are the most productive plants in coastal vegetated ecosystems . They have a net primary productivity (NPP) of 1.32 Pg C yr –1 worldwide and contribute significantly to ocean carbon sequestration through pathways such as macroalgal carbon burial in local sediments or long-distance carbon export to deep sea as well as contribution of recalcitrant dissolved organic carbon (RDOC), thus receiving much attention under climate change scenarios. − Macroalgal carbon sequestration processes are complex, involving the conversion between different forms of carbon, and are largely regulated by microbial decomposition and photodegradation. − For example, microbial degradation of dead macroalgal debris produces different forms of carbon, some of which can be returned to the atmosphere as carbon gas and some can be stored in forms of RDOC, recalcitrant particulate organic carbon (RPOC), and relatively stable dissolved carbonate in the ocean . In addition to dead macroalgal debris, a large amount of organic carbon, including DOC and POC, can be released during macroalgal growth. − ,, Microbial carbon pump plays an important role in driving macroalgal DOC from the labile to recalcitrant state, indirectly involving in macroalgal carbon sequestration. , However, the fate of the POC released during macroalgal growth and their carbon sequestration effect are still unclear.…”

Section: Introductionmentioning

confidence: 99%

Particulate Organic Carbon Released during Macroalgal Growth Has Significant Carbon Sequestration Potential in the Ocean

Li,

Feng,

Xiong

et al. 2023

Environ. Sci. Technol.

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Substantial amounts of particulate organic carbon (POC) are released during macroalgal growth; however, the fate of these POCs and their carbon sequestration effects remain unclear. Here, field investigations found that Ulva prolifera caused a significant increase of POC in seawater below the surface during a macroalgal bloom. However, laboratory simulations revealed that 77.6% of these POC was easily degraded by microorganisms in a short period of time, concurrently resulting in the production of dissolved organic carbon (DOC) from POC transformation. Over a period of 3 months, the bioavailable components of macroalgae-released POC and POC-transformed DOC were degraded, leaving 39.6% of the antibiodegradable substances composed of biorecalcitrant POC and biorecalcitrant DOC. However, although the biorecalcitrant POC was rich in humic-like components resisting biodegradation, the biorecalcitrant POC exhibited greater sensitivity to photodegradation than biorecalcitrant DOC. The photodegradation removal rate of biorecalcitrant POC (14.1%) was more than 10 times that of biorecalcitrant DOC (1.2%). Ultimately, a substantial portion (36.3%) of the POC released by growing macroalgae could potentially perform long-term carbon sequestration after conversion to recalcitrant POC and recalcitrant DOC, and these inert carbons derived from macroalgal POC have been previously ignored and should also be included in macroalgal carbon sequestration accounting.

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Legacy Effects of Late Macroalgal Blooms on Dissolved Inorganic Carbon Pool through Alkalinity Enhancement in Coastal Ocean

Cited by 14 publications

References 57 publications

Interpreting biogeochemical processes through the relationship between total alkalinity and dissolved inorganic carbon: Theoretical basis and limitations

Interpreting biogeochemical processes through the relationship between total alkalinity and dissolved inorganic carbon: Theoretical basis and limitations

High photoreactivity of chromophoric dissolved organic matter derived from Ulva prolifera and Sargassum

Particulate Organic Carbon Released during Macroalgal Growth Has Significant Carbon Sequestration Potential in the Ocean

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