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海洋酸化的钙化物种敏感性分布

Calcifying species sensitivity distributions for ocean acidification.

作者信息

Azevedo Ligia B, De Schryver An M, Hendriks A Jan, Huijbregts Mark A J

机构信息

International Institute for Applied Systems Analysis , Ecosystem Services and Management Program, Schlossplatz 1, A-2361 Laxenburg, Austria.

出版信息

Environ Sci Technol. 2015 Feb 3;49(3):1495-500. doi: 10.1021/es505485m. Epub 2015 Jan 13.

DOI:10.1021/es505485m

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6485514/

Abstract

Increasing CO2 atmospheric levels lead to increasing ocean acidification, thereby enhancing calcium carbonate dissolution of calcifying species. We gathered peer-reviewed experimental data on the effects of acidified seawater on calcifying species growth, reproduction, and survival. The data were used to derive species-specific median effective concentrations, i.e., pH50, and pH10, via logistic regression. Subsequently, we developed species sensitivity distributions (SSDs) to assess the potentially affected fraction (PAF) of species exposed to pH declines. Effects on species growth were observed at higher pH than those on species reproduction (mean pH10 was 7.73 vs 7.63 and mean pH50 was 7.28 vs 7.11 for the two life processes, respectively) and the variability in the sensitivity of species increased with increasing number of species available for the PAF (pH10 standard deviation was 0.20, 0.21, and 0.33 for survival, reproduction, and growth, respectively). The SSDs were then applied to two climate change scenarios to estimate the increase in PAF (ΔPAF) by future ocean acidification. In a high CO2 emission scenario, ΔPAF was 3 to 10% (for pH50) and 21 to 32% (for pH10). In a low emission scenario, ΔPAF was 1 to 4% (for pH50) and 7 to 12% (for pH10). Our SSDs developed for the effect of decreasing ocean pH on calcifying marine species assemblages can also be used for comparison with other environmental stressors.

摘要

大气中二氧化碳含量的增加导致海洋酸化加剧，从而增强了钙化物种碳酸钙的溶解。我们收集了同行评审的关于酸化海水对钙化物种生长、繁殖和生存影响的实验数据。这些数据用于通过逻辑回归得出物种特异性的半数有效浓度，即pH50和pH10。随后，我们绘制了物种敏感度分布（SSD），以评估暴露于pH下降环境下物种的潜在受影响比例（PAF）。观察到对物种生长的影响发生在比物种繁殖更高的pH值下（两个生命过程的平均pH10分别为7.73和7.63，平均pH50分别为7.28和7.11），并且随着可用于PAF计算的物种数量增加，物种敏感度的变异性也增加（生存、繁殖和生长的pH10标准差分别为0.20、0.21和0.33）。然后将SSD应用于两种气候变化情景，以估计未来海洋酸化导致的PAF增加量（ΔPAF）。在高二氧化碳排放情景下，ΔPAF为3%至10%（对于pH50）和21%至32%（对于pH10）。在低排放情景下，ΔPAF为1%至4%（对于pH50）和7%至12%（对于pH10）。我们针对海洋pH值下降对钙化海洋物种组合的影响所绘制的SSD也可用于与其他环境压力源进行比较。