A. M. Palacio-Castro, I. C. Enochs, N. Besemer, A. Boyd, M. Jankulak, G. Kolodziej, H. K. Hirsh, A. E. Webb, E. K. Towle, C. Kelble, I. Smith, D. P. Manzello
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引用次数: 0
Abstract
Ocean acidification (OA) threatens coral reef persistence by decreasing calcification and accelerating the dissolution of reef frameworks. The carbonate chemistry of coastal areas where many reefs exist is strongly influenced by the metabolic activity of the underlying benthic community, contributing to high spatiotemporal variability. While characterizing this variability is difficult, it has important implications for the progression of OA and the persistence of the ecosystems. Here, we characterized the carbonate chemistry at 38 permanent stations located along 10 inshore-offshore transects spanning 250 km of the Florida Coral Reef (FCR), which encompass four major biogeographic regions (Biscayne Bay, Upper Keys, Middle Keys, and Lower Keys) and four shelf zones (inshore, mid-channel, offshore, and oceanic). Data have been collected since 2010, with approximately bi-monthly periodicity starting in 2015. Increasing OA, driven by increasing DIC, was detected in the mid-channel, offshore, and oceanic zones in every biogeographic region. In the inshore zone, however, increasing TA counteracted any measurable OA trend. Strong seasonal variability occurred at inshore sites and included periods of both exacerbated and mitigated OA. Seasonality was region-dependent, with greater variability in the Lower and Middle Keys. Elevated pH and aragonite saturation states (ΩAr) were observed in the Upper and Middle Keys, which could favor reef habitat persistence in these regions. Offshore reefs in the FCR could be more susceptible to global OA by experiencing open-ocean-like water chemistry conditions. By contrast, higher seasonal variability at inshore reefs could offer a temporary OA refuge during periods of enhanced primary production.
海洋酸化(OA)会降低钙化程度,加速珊瑚礁框架的溶解,从而威胁珊瑚礁的存续。许多珊瑚礁所在的沿海地区的碳酸盐化学性质受到底栖生物群落新陈代谢活动的强烈影响,从而导致高度的时空变异性。虽然描述这种变化很困难,但它对 OA 的进展和生态系统的持续性有重要影响。在此,我们对位于佛罗里达珊瑚礁(FCR)横跨 250 千米的 10 个近岸-近岸横断面上的 38 个永久性站点的碳酸盐化学特征进行了描述,这些站点包括四个主要生物地理区域(比斯坎湾、上礁群、中礁群和下礁群)和四个陆架区(近岸、中通道、近岸和大洋区)。数据自 2010 年开始收集,从 2015 年开始大约每两个月收集一次。在每个生物地理区域的中层通道、近海和大洋区,都检测到由 DIC 增加驱动的 OA 增加。然而,在近岸区域,TA 的增加抵消了任何可测量的 OA 趋势。近岸地点出现了强烈的季节性变化,包括 OA 加剧期和 OA 减缓期。季节性与地区有关,下礁和中礁地区的变化更大。在上礁和中礁观察到 pH 值和文石饱和状态(ΩAr)升高,这可能有利于这些地区珊瑚礁生境的持续存在。渔业资源保护区的近海珊瑚礁可能更容易受到全球 OA 的影响,因为它们经历了类似于公海的水化学条件。相比之下,近岸珊瑚礁较高的季节性变化可能会在初级生产力增强期间提供一个临时的 OA 庇护所。
期刊介绍:
Global Biogeochemical Cycles (GBC) features research on regional to global biogeochemical interactions, as well as more local studies that demonstrate fundamental implications for biogeochemical processing at regional or global scales. Published papers draw on a wide array of methods and knowledge and extend in time from the deep geologic past to recent historical and potential future interactions. This broad scope includes studies that elucidate human activities as interactive components of biogeochemical cycles and physical Earth Systems including climate. Authors are required to make their work accessible to a broad interdisciplinary range of scientists.