期刊
JOURNAL OF HYDROLOGY
卷 595, 期 -, 页码 -出版社
ELSEVIER
DOI: 10.1016/j.jhydrol.2021.126036
关键词
Coastal inorganic carbon; Biogeochemistry; Mangrove; Intertidal aquifer; Wetlands
资金
- Southern Marine Science and Engineering Guangdong Laboratory (Zhuhai)
- Research Grants Council of the Hong Kong Special Administrative Region, China [106190154]
- National Natural Science Foundation of China [91747204, 41877172]
- [c896499]
The study investigates the biogeochemistry of inorganic carbon in an intertidal aquifer in Hong Kong and its impact on Tolo Harbor through submarine groundwater discharge (SGD). It found that locally produced total alkalinity (TAlk) and dissolved inorganic carbon (DIC) in the aquifer contribute over 50% of the discharged TAlk and DIC to the ocean. The distributions of TAlk and DIC in different zones (mangrove and bare beach) vary due to hydrogeological and geochemical conditions. Additionally, TAlk and DIC fluxes discharged with SGD were found to be significantly higher during the wet season compared to the dry season.
While submarine groundwater discharge (SGD) is well known to release large amounts of dissolved nutrients and organic carbon into the ocean, the contribution of SGD to the marine inorganic carbon cycle is poorly understood. Here, the biogeochemistry of inorganic carbon in an intertidal aquifer and related SGD-derived fluxes into Tolo Harbor, Hong Kong was investigated over tidal and seasonal time scales. The results revealed the production of total alkalinity (TAlk) and dissolved inorganic carbon (DIC) in the intertidal aquifer over the entire salinity range. The locally produced TAlk and DIC in the intertidal aquifer contributed to >50% of the TAlk and DIC discharged with SGD to the ocean. The distributions of TAlk and DIC in the transition (mangrove) and high salinity (bare beach) zones were different due to the distinct hydrogeological and geochemical conditions. In the organic-rich mangrove zone, TAlk and DIC productions were driven by biotic processes such as aerobic respiration, denitrification, and sulfate reduction. In the organic-poor bare beach zone, TAlk and DIC productions were likely driven by abiotic processes such as precipitation/dissolution of carbonate minerals. Temperature, pH, physical mixing, and iron cycling in the intertidal aquifer also considerably influenced the carbonate biogeochemistry. TAlk inventory in the intertidal aquifer was seasonally stable but TAlk discharged with SGD was similar to 60% greater in the wet season than in the dry season (73.3 vs. 45.6 mol d(-1) per m coastline). The DIC inventory in the intertidal aquifer and DIC discharged with SGD were similar to 24% and 95% higher, respectively, in the wet season than dry season. Overall, through analyzing TAlk:DIC ratios and related fluxes, SGD was thought to reduce the CO2 buffering capacity of the receiving ocean, and act as a local driver of ocean acidification.
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