Surface-to-Interior Transport Timescales and Ventilation Patterns in a Time-Dependent Circulation Driven by Sustained Climate Warming

IF 2.8 2区 地球科学 Q1 OCEANOGRAPHY Journal of Physical Oceanography Pub Date : 2023-11-06 DOI:10.1175/jpo-d-23-0113.1
Y. Liu, F. Primeau
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Abstract

Abstract The effect of climate warming in response to rising atmospheric CO2 on the ventilation of the ocean remains uncertain. Here we make theoretical advances in elucidating the relationship between ideal age and transit time distribution (TTD) in a time-dependent flow. Subsequently, we develop an offline tracer-transport model to characterize the ventilation patterns and timescales in the time-evolving circulation for the 1850-to-2300 period as simulated with the Community Earth System Model version 1 (CESMv1) under business-as-usual warming scenario. We found that by 2300 2.1% less water originates from the high-latitude deep water formation regions (both hemispheres) compared to 1850. In compensation, there is an increase in the water originating from the subantarctic. We also found that slowing meridional overturning circulation causes a gradual increase in mean age during the 1850 to 2300 period, with a globally averaged mean-age increase of ~110 years in 2300. Where and when the water will be re-exposed to the atmosphere depends on the post-2300 circulation. For example, if we assume that the circulation persists in its year-2300 state (scenario 1), the mean interior-to-surface transit time in year 1850 is ~1140 years. In contrast, if we assume that the circulation abruptly recovers to its year-1850 state (scenario 2), the mean interior-to-surface transit time in 1850 is only ~740 years. By 2300, these differences become even larger; in scenario 1, the mean interior-to-surface transit time increases by ~200 years, whereas scenario 2 decreases by ~80 years. The dependence of interior-to-surface transit time on the future ocean circulation produces an additional unavoidable uncertainty in the long-term durability of marine carbon dioxide removal strategies.
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持续气候变暖驱动的时变环流中地表到室内的运输时间尺度和通风模式
气候变暖对大气CO2上升的响应对海洋通风的影响仍然不确定。本文从理论上阐述了时变流中理想年龄与穿越时间分布之间的关系。随后,我们开发了一个离线示踪运输模型,以表征在常规变暖情景下,使用社区地球系统模式1 (CESMv1)模拟的1850- 2300年期间随时间变化的环流的通风模式和时间尺度。我们发现,到2300年,与1850年相比,来自高纬度深水形成区(两个半球)的水减少了2.1%。作为补偿,来自亚南极的水有所增加。经向翻转环流的减缓导致1850 ~ 2300年的平均年龄逐渐增加,2300年全球平均年龄增加了~110年。水将在何时何地重新暴露在大气中取决于2300年后的环流。例如,如果我们假设环流维持在2300年的状态(情景1),那么1850年的平均内部到地面的传输时间为~1140年。相反,如果我们假设环流突然恢复到1850年的状态(情景2),1850年的平均内部到地面的传输时间仅为~740年。到2300年,这些差异变得更大;在情景1中,平均从内部到地面的传输时间增加了~200年,而情景2减少了~80年。内部到地面的传输时间对未来海洋环流的依赖,在海洋二氧化碳清除战略的长期持久性方面产生了另一个不可避免的不确定性。
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来源期刊
CiteScore
2.40
自引率
20.00%
发文量
200
审稿时长
4.5 months
期刊介绍: The Journal of Physical Oceanography (JPO) (ISSN: 0022-3670; eISSN: 1520-0485) publishes research related to the physics of the ocean and to processes operating at its boundaries. Observational, theoretical, and modeling studies are all welcome, especially those that focus on elucidating specific physical processes. Papers that investigate interactions with other components of the Earth system (e.g., ocean–atmosphere, physical–biological, and physical–chemical interactions) as well as studies of other fluid systems (e.g., lakes and laboratory tanks) are also invited, as long as their focus is on understanding the ocean or its role in the Earth system.
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