理想化模拟中气候变暖时强热带气旋加深机制的变化

IF 4.8 2区 地球科学 Q1 METEOROLOGY & ATMOSPHERIC SCIENCES
Ting-Chen Chen, Christoph Braun, Aiko Voigt, Joaquim G. Pinto
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引用次数: 0

摘要

摘要 为了解在气候变暖的情况下热带气旋(ETC)可能发生的变化,我们利用 ICON-NWP 模式在不同的初始条件下进行了理想化的气旋生命周期模拟。针对当今气候,重点介绍了两个实验:4K 均匀变暖和 CMIP6 模型预测的更现实的 21 世纪晚期变暖模式。通过压力趋势方程分析,量化了不同的 ETC 深化机制,特别是二重过程,并通过对比粗网格(80 千米)和对流允许(2.5 千米)模拟,研究了水平模型分辨率的依赖性。虽然我们模拟的 ETC 主要由气压驱动,由地表低气压上方气柱中的水平暖空气平流主导,但这种效应在两次升温实验中都只增强了 10%。然而,绝热加热对地表压降的直接贡献几乎增加了一倍,这可能会对水平暖空气平流产生正反馈。虽然它们对变暖的综合响应很明显,但在很大程度上被由于较暖较湿的 ETC 向上运动增强而加强的绝热冷却(17%)所抵消,导致 ETC 在成熟时略有加深(降低约 1.5-4 hPa)。然而,近地面影响强烈增加,特别是局地极端降水(高达 56%)。对流允许模拟和粗网格模拟对全球变暖的 ETC 反应在本质上是一致的。我们认为,与 80 公里模拟相比,2.5 公里模拟的 ETC(中心气压较高)系统性较弱,这可能主要是由于模型在表示气旋核心附近暖锋上的对流绝热加热时存在不确定性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Changes of intense extratropical cyclone deepening mechanisms in a warmer climate in idealized simulations
Abstract To understand how extratropical cyclones (ETCs) may change in a warmer climate, we conduct idealized baroclinic life cycle simulations using the ICON-NWP model with varied initial conditions. With respect to a present-day climate, two experiments are highlighted: a 4K uniform warming and a more realistic late 21st-century warming pattern projected by a CMIP6 model. Different ETC deepening mechanisms, especially by diabatic processes, are quantified via the pressure tendency equation analysis, and the horizontal model resolution dependency is examined by contrasting coarse-grid (80 km) and convection-permitting (2.5 km) simulations. While our simulated ETCs are primarily baroclinically driven, dominated by the horizontal warm-air advection in the air column above the surface low, such an effect only strengthens by 10% in both warming experiments. However, the direct contribution of diabatic heating to surface pressure drop almost doubles, which likely feeds back positively to horizontal warm-air advection. Although their combined response to warming is pronounced, it is largely offset by the strengthened adiabatic cooling (17%) due to enhanced upward motions in warmer and moister ETCs, leading to a marginal ETC deepening at maturity (lowers by ~ 1.5–4 hPa). Nevertheless, the near-surface impacts strongly increase, particularly the local extreme precipitation (up to 56%). The convection-permitting and the coarse-grid simulations show qualitatively consistent ETC responses to global warming. We suggest that the systematically weaker ETCs (with higher central pressure) in 2.5 km compared to 80 km simulations might be primarily caused by model uncertainty in representing the convective-diabatic heating over the warm front near the cyclone core.
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来源期刊
Journal of Climate
Journal of Climate 地学-气象与大气科学
CiteScore
9.30
自引率
14.30%
发文量
490
审稿时长
7.5 months
期刊介绍: The Journal of Climate (JCLI) (ISSN: 0894-8755; eISSN: 1520-0442) publishes research that advances basic understanding of the dynamics and physics of the climate system on large spatial scales, including variability of the atmosphere, oceans, land surface, and cryosphere; past, present, and projected future changes in the climate system; and climate simulation and prediction.
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