School of Environmental Sciences, University of East Anglia, Norwich NR4 7TJ, UK.
Philos Trans A Math Phys Eng Sci. 2012 Sep 13;370(1974):4317-42. doi: 10.1098/rsta.2012.0167.
Fundamental changes to marine chemistry are occurring because of increasing carbon dioxide (CO(2)) in the atmosphere. Ocean acidity (H(+) concentration) and bicarbonate ion concentrations are increasing, whereas carbonate ion concentrations are decreasing. There has already been an average pH decrease of 0.1 in the upper ocean, and continued unconstrained carbon emissions would further reduce average upper ocean pH by approximately 0.3 by 2100. Laboratory experiments, observations and projections indicate that such ocean acidification may have ecological and biogeochemical impacts that last for many thousands of years. The future magnitude of such effects will be very closely linked to atmospheric CO(2); they will, therefore, depend on the success of emission reduction, and could also be constrained by geoengineering based on most carbon dioxide removal (CDR) techniques. However, some ocean-based CDR approaches would (if deployed on a climatically significant scale) re-locate acidification from the upper ocean to the seafloor or elsewhere in the ocean interior. If solar radiation management were to be the main policy response to counteract global warming, ocean acidification would continue to be driven by increases in atmospheric CO(2), although with additional temperature-related effects on CO(2) and CaCO(3) solubility and terrestrial carbon sequestration.
由于大气中二氧化碳(CO(2))的增加,海洋化学发生了根本性的变化。海洋酸度(氢离子浓度)和碳酸氢根离子浓度增加,而碳酸根离子浓度降低。海洋上层的平均 pH 值已经下降了 0.1,若继续不受限制地排放碳,到 2100 年,海洋上层的平均 pH 值将进一步降低约 0.3。实验室实验、观测和预测表明,这种海洋酸化可能会产生持续数千年的生态和生物地球化学影响。这种影响的未来规模将与大气中的 CO(2)非常密切相关;因此,它们将取决于减排的成功,也可能受到基于大多数二氧化碳去除(CDR)技术的地球工程的限制。然而,一些基于海洋的 CDR 方法(如果在气候上具有重要意义)会将酸化从海洋上层转移到海底或海洋内部的其他地方。如果太阳辐射管理成为应对全球变暖的主要政策反应,那么海洋酸化将继续受到大气中 CO(2)增加的驱动,尽管 CO(2)和 CaCO(3)溶解度以及陆地碳封存会受到额外的温度相关影响。
