Interpreting biogeochemical processes through the relationship between total alkalinity and dissolved inorganic carbon: Theoretical basis and limitations
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Abstract
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.
海洋碳酸盐系统受到人为二氧化碳吸收、生物地球化学过程以及涉及淡水输入和去除的物理变化的影响。量化海水碳酸盐系统的两个常用参数是总碱度(TA)和总溶解无机碳(DIC)。为了说明物理变化,通常将总碱度和总溶解无机碳归一化为参考盐度(即 nTA 和 nDIC),然后根据特定过程的反应化学计量学,利用 nTA 和 nDIC 之间的关系来确定调节碳酸盐系统的主要生物地球化学过程。然而,这种解释的理论基础尚未得到全面研究。在本研究中,我们在理想化条件下验证了这种方法,并讨论了相关假设和局限性。此外,我们还应用该方法解释了墨西哥湾西北部泻湖河口的实地 TA 和 DIC 数据。我们的研究结果表明,评估包含多个站点和时间段的实地数据可能会出现问题。此外,生物地球化学过程的各种组合可导致相同的 nTA-nDIC 关系,尽管每个过程的相对重要性可能会有很大不同。因此,仅依靠 TA 和 DIC 数据的化学计量关系并不是揭示主要生物地球化学过程的最终方法。相反,有必要测量特定过程的参数。
期刊介绍:
Limnology and Oceanography: Methods (ISSN 1541-5856) is a companion to ASLO''s top-rated journal Limnology and Oceanography, and articles are held to the same high standards. In order to provide the most rapid publication consistent with high standards, Limnology and Oceanography: Methods appears in electronic format only, and the entire submission and review system is online. Articles are posted as soon as they are accepted and formatted for publication.
Limnology and Oceanography: Methods will consider manuscripts whose primary focus is methodological, and that deal with problems in the aquatic sciences. Manuscripts may present new measurement equipment, techniques for analyzing observations or samples, methods for understanding and interpreting information, analyses of metadata to examine the effectiveness of approaches, invited and contributed reviews and syntheses, and techniques for communicating and teaching in the aquatic sciences.
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