区域耦合气候模型 ROM 预测赤道非洲中部降水变化更合理

IF 3.8 2区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES
Alain T. Tamoffo, Torsten Weber, Daniel Abel, Katrin Ziegler, William Cabos, Dmitry V. Sein, Patrick Laux
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引用次数: 0

摘要

揭示可信的未来降雨量变化(ΔPr)模式对于调整社会应对气候变化引起的灾害至关重要。本研究比较了区域耦合海洋模式(ROM)及其大气组成部分--区域大气模式 REMO 对赤道非洲中部(CEA)降雨量的预测。这两个模式都由地球系统模式 MPI-ESM-LR 按照代表性浓度途径 8.5 进行强迫预测。结果表明,赤道非洲大部分地区降雨量增加,ROM 预测的湿润程度比 REMO 预测的更为广泛和加剧,尽管 REMO 预测未来条件下的降水量更大,这突出表明了历史偏差对 REMO 预测的影响。对变化过程的研究揭示了海洋和陆地表面温度变化对两个模式之间 ΔPr 差异的强烈控制作用。具体地说,与 REMO 相比,ROM 对大西洋变暖的减缓作用大于对东亚大陆的减缓作用,从而导致刚果盆地单元的增强,并通过比湿度增加可降水量,影响深层对流。两种模式都预测萨赫勒和卡拉哈里热低压增强,而 ROM 模式比萨赫勒低压更好地描述了卡拉哈里低压的暖性。由此产生的温度梯度加强了北部和南部浅层经向哈德利翻转环流。ROM 模拟的情况比 REMO 更潮湿,这是因为 REMO 的北部哈德利单胞较弱,从而限制了向萨赫勒北部水汽分流的可能性。此外,中对流层水汽辐合的差异使 ROM 和 REMO 的湿度相对于历史时期和未来条件有所不同。ROM的预测更可信,这与它在历史气候和Δpr基本机制下的附加值的可靠性有关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Regionally Coupled Climate Model ROM Projects More Plausible Precipitation Change Over Central Equatorial Africa

Regionally Coupled Climate Model ROM Projects More Plausible Precipitation Change Over Central Equatorial Africa

Unraveling plausible future rainfall change (ΔPr) patterns is crucial for tailoring societies' responses to climate change-induced hazards. This study compares rainfall projections from the regionally coupled ocean model (ROM) and its atmospheric component, the regional atmospheric model REMO, over Central Equatorial Africa (CEA). Both models are forced by the Earth system model MPI-ESM-LR following the Representative Concentration Pathway 8.5. Results reveal increased rainfall across most of CEA, with ROM projecting more widespread and intensified wetting than REMO, although REMO produces more precipitation under future conditions, underscoring the influence of historical biases on REMO's projection. Examining processes underpinning changes unveils strong controls of sea and land surface temperature changes in ΔPr differences between the two models. Specifically, ROM mitigates warming more over the Atlantic than over CEA landmass compared to REMO, inducing enhancement of the Congo Basin cell and increased precipitable water content through specific humidity, affecting deep convection. Both models project enhanced Sahel and Kalahari thermal lows, with ROM better depicting the Kalahari low's warmer nature than the Sahel low. The resulting temperature gradients strengthen the northern and southern shallow meridional Hadley overturning circulation. ROM simulates the wetter conditions than REMO, attributed to its weaker northern Hadley Cell, which restricts the likelihood of northward moisture divergence toward the Sahel. Additionally, differences in mid-tropospheric moisture convergence differentiate between ROM and REMO's wetness relative to the historical period and under future conditions. ROM projections are more plausible, in association with the reliability of its added value under the historical climate and mechanisms underlying Δpr.

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来源期刊
Journal of Geophysical Research: Atmospheres
Journal of Geophysical Research: Atmospheres Earth and Planetary Sciences-Geophysics
CiteScore
7.30
自引率
11.40%
发文量
684
期刊介绍: JGR: Atmospheres publishes articles that advance and improve understanding of atmospheric properties and processes, including the interaction of the atmosphere with other components of the Earth system.
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