Equilibrium Climate after Spectral and Bolometric Irradiance Reduction in Grand Solar Minimum Simulations

IF 3 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES

Climate Pub Date : 2023-12-19 DOI:10.3390/cli12010001

Nazario Tartaglione, T. Toniazzo, O. Otterå, Y. Orsolini

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Abstract

In this study, we use the Whole Atmosphere Community Climate Model, forced by present-day atmospheric composition and coupled to a Slab Ocean Model, to simulate the state of the climate under grand solar minimum forcing scenarios. Idealized experiments prescribe time-invariant solar irradiance reductions that are either uniform (percentage-wise) across the total solar radiation spectrum (TOTC) or spectrally localized in the ultraviolet (UV) band (SCUV). We compare the equilibrium condition of these experiments with the equilibrium condition of a control simulation, forced by perpetual solar maximum conditions. In SCUV, we observe large stratospheric cooling due to ozone reduction. In both the Northern Hemisphere (NH) and the Southern Hemisphere (SH), this is accompanied by a weakening of the polar night jet during the cold season. In TOTC, dynamically induced polar stratospheric cooling is observed in the transition seasons over the NH, without any ozone deficit. The global temperature cooling values, compared with the control climate, are 0.55±0.03 K in TOTC and 0.39±0.03 K in SCUV. The reductions in total meridional heat transport outside of the subtropics are similar in the two experiments, especially in the SH. Despite substantial differences in stratospheric forcing, similarities exist between the two experiments, such as cloudiness; meridional heating transport in the SH; and strong cooling in the NH during wintertime, although this cooling affects two different regions, namely, North America in TOTC and the Euro–Asian continent in SCUV.

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大太阳极小期模拟中光谱和博勒辐照度降低后的平衡气候

在这项研究中，我们使用全大气层群气候模式，以当今大气成分为强迫，并与板岩海洋模式耦合，模拟大太阳最小强迫情景下的气候状态。理想化的实验设定了时间不变的太阳辐照度下降，这种下降要么在整个太阳辐射光谱（TOTC）上是均匀的（按百分比计算），要么在紫外线（UV）波段（SCUV）上是局部的。我们将这些实验的平衡条件与对照模拟的平衡条件进行了比较，对照模拟是在太阳永久最大值条件下进行的。在 SCUV 波段，我们观察到臭氧减少导致平流层大幅冷却。在北半球（NH）和南半球（SH），伴随着寒冷季节极夜喷流的减弱。在 TOTC 中，在北半球的过渡季节观测到了动态诱导的极地平流层冷却，但没有观测到任何臭氧亏损。与对照气候相比，TOTC 的全球温度冷却值为 0.55±0.03 K，SCUV 为 0.39±0.03 K。两次实验中，亚热带以外地区经向热输送总量的减少情况相似，尤其是在上海地区。尽管在平流层强迫方面存在很大差异，但两个实验之间也存在相似之处，例如云量；高纬度地区的经向热传输；以及冬季北半球的强降温，尽管这种降温影响到两个不同的地区，即 TOTC 中的北美洲和 SCUV 中的欧亚大陆。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Climate Earth and Planetary Sciences-Atmospheric Science

CiteScore

5.50

自引率

5.40%

发文量

172

审稿时长

11 weeks

期刊介绍： Climate is an independent, international and multi-disciplinary open access journal focusing on climate processes of the earth, covering all scales and involving modelling and observation methods. The scope of Climate includes: Global climate Regional climate Urban climate Multiscale climate Polar climate Tropical climate Climate downscaling Climate process and sensitivity studies Climate dynamics Climate variability (Interseasonal, interannual to decadal) Feedbacks between local, regional, and global climate change Anthropogenic climate change Climate and monsoon Cloud and precipitation predictions Past, present, and projected climate change Hydroclimate.