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加拿大不列颠哥伦比亚省两个峡湾的对比海洋碳酸盐系统:海水缓冲能力和对人为 CO2 入侵的响应。

Contrasting marine carbonate systems in two fjords in British Columbia, Canada: Seawater buffering capacity and the response to anthropogenic CO2 invasion.

机构信息

Hakai Institute, Heriot Bay, British Columbia, Canada.

Department of Zoology, University of British Columbia, Vancouver, British Columbia, Canada.

出版信息

PLoS One. 2020 Sep 3;15(9):e0238432. doi: 10.1371/journal.pone.0238432. eCollection 2020.

DOI:10.1371/journal.pone.0238432
PMID:32881918
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7470366/
Abstract

The carbonate system in two contrasting fjords, Rivers Inlet and Bute Inlet, on the coast of British Columbia, Canada, was evaluated to characterize the mechanisms driving carbonate chemistry dynamics and assess the impact of anthropogenic carbon. Differences in the character of deep water exchange between these fjords were inferred from their degree of exposure to continental shelf water and their salinity relationships with total alkalinity and total dissolved inorganic carbon, which determined seawater buffering capacity. Seawater buffering capacity differed between fjords and resulted in distinct carbonate system characteristics with implications on calcium carbonate saturation states and sensitivity to increasing anthropogenic carbon inputs. Saturation states of both aragonite and calcite mineral phases of calcium carbonate were seasonally at or below saturation throughout the entire water column in Bute Inlet, while only aragonite was seasonally under-saturated in portions of the water column in Rivers Inlet. The mean annual saturation states of aragonite in Rivers Inlet and calcite in Bute Inlet deep water layers have declined to below saturation within the last several decades due to anthropogenic carbon accumulation, and similar declines to undersaturation are projected in their surface layers as anthropogenic carbon continues to accumulate. This study demonstrates that the degree of fjord water exposure to open shelf water influences the uptake and sensitivity to anthropogenic carbon through processes affecting seawater buffering capacity, and that reduced uptake but greater sensitivity occurs where distance to ocean source waters and freshwater dilution are greater.

摘要

对加拿大不列颠哥伦比亚省海岸的两个对比峡湾——里弗斯湾和布特湾的碳酸盐系统进行了评估,以描述驱动碳酸盐化学动力学的机制,并评估人为碳的影响。这些峡湾之间深海交换特征的差异是根据其对大陆架水的暴露程度以及它们与总碱度和总溶解无机碳的盐度关系推断出来的,这决定了海水缓冲能力。峡湾之间的海水缓冲能力不同,导致碳酸盐系统特征明显不同,这对碳酸钙饱和度状态和对增加人为碳输入的敏感性有影响。在布特湾,整个水柱中碳酸钙的文石和方解石矿物相的饱和度在整个季节都处于或低于饱和度,而在里弗斯湾的水柱部分,只有文石在季节上处于不饱和状态。由于人为碳的积累,过去几十年里,里弗斯湾的文石和布特湾深部水层的碳酸钙平均年饱和度已经降至不饱和状态,而且随着人为碳的继续积累,其表层也预计会出现类似的不饱和度下降。本研究表明,峡湾水暴露于开阔架水的程度通过影响海水缓冲能力的过程影响对人为碳的吸收和敏感性,而且在距离海洋源水和淡水稀释更远的地方,吸收减少但敏感性增加。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/65f6/7470366/5b422282119c/pone.0238432.g008.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/65f6/7470366/5b422282119c/pone.0238432.g008.jpg

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3
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Front Mar Sci. 2024 Feb 2;11:1293955. doi: 10.3389/fmars.2024.1293955.
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Feedbacks Between Estuarine Metabolism and Anthropogenic CO Accelerate Local Rates of Ocean Acidification and Hasten Threshold Exceedances.河口代谢与人为二氧化碳之间的反馈加速了海洋酸化的局部速率并促使阈值被突破。
J Geophys Res Oceans. 2024 Feb 27;129(3). doi: 10.1029/2023jc020313.
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The source and accumulation of anthropogenic carbon in the U.S. East Coast.美国东海岸人为碳的来源与积累。
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The prokaryotic and eukaryotic microbiome of Pacific oyster spat is shaped by ocean warming but not acidification.太平洋牡蛎幼体的原核生物和真核生物微生物组受海洋变暖影响,但不受酸化影响。
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