スーパーエルニーニョを弱めるジオエンジニアリングの可能性(Could Geoengineering Work to Tamp Down Super El Ninos?)

2026-07-08 カリフォルニア大学サンディエゴ校(UCSD)

カリフォルニア大学サンディエゴ校(UC San Diego)の研究チームは、スーパーエルニーニョの発生を弱めるための気候工学(ジオエンジニアリング)の有効性を数値シミュレーションで検証した。研究では、熱帯太平洋の特定海域で海面に人工的な冷却効果を与えた場合の影響を解析した結果、適切な場所と時期で海面水温を低下させることで、スーパーエルニーニョの発達を抑制できる可能性が示された。一方で、冷却を行う場所やタイミングを誤ると効果が得られないばかりか、別の海域の気候や降水パターンに予期しない影響を及ぼす可能性も明らかになった。研究チームは、この成果は実際の気候工学の実施を提案するものではなく、エルニーニョ現象を支配する海洋・大気相互作用の理解を深めるための理論的研究であると強調している。本研究は、極端な気候現象への対応策を検討するうえで、介入技術の可能性とリスクを科学的に評価する重要な知見を提供した。

<関連情報>

海洋雲の集中的な明るさがその後のエルニーニョ現象を弱める Targeted marine cloud brightening weakens subsequent El Niño

Jessica S. Wan, John T. Fasullo, Nan Rosenbloom, Chih-Chieh Chen, and Katharine Ricke
Science Advances  Published:8 Jul 2026
DOI:https://doi.org/10.1126/sciadv.adx3012

スーパーエルニーニョを弱めるジオエンジニアリングの可能性(Could Geoengineering Work to Tamp Down Super El Ninos?)

Abstract

Extreme events are often attributable to the compounding effects of anthropogenic warming and natural variability. Marine cloud brightening (MCB), a solar geoengineering proposal to reduce long-term warming, could theoretically mitigate extremes by instead targeting seasonal-to-multiyear phenomena, such as El Niño–Southern Oscillation (ENSO). Yet the effectiveness of regional MCB to deliberately modify ENSO has not been tested. By exploiting the 2019–2020 Australian wildfire opportunistic experiment, we demonstrate that the “natural” cloud brightening and ensuing La Niña–like response can be reproduced by simulating MCB in the southeast Pacific. We then explore how MCB modifies the 1997–1998 and 2015–2016 El Niño events. MCB initiated during the El Niño growth phase disrupts the Bjerknes feedbacks that normally amplify El Niño conditions, but those effects weaken after MCB is terminated. Only the earliest and longest interventions restore neutral ENSO conditions and weaken teleconnections. Weakening El Niño can result in unintended consequences including an earlier La Niña following the targeted El Niño, although early and short interventions may counter these effects. Our results support the consideration of climate variability and teleconnections as targets in solar geoengineering research.

 

CESM2における、最近のオーストラリアの森林火災に対する熱帯太平洋の複数年にわたる冷却反応 A multiyear tropical Pacific cooling response to recent Australian wildfires in CESM2

John T. Fasullo, Nan Rosenbloom, and Rebecca Buchholz
Science Advances  Published:10 May 2023
DOI:https://doi.org/10.1126/sciadv.adg1213

Abstract

The climate response to biomass burning emissions from the 2019–2020 Australian wildfire season is estimated from two 30-member ensembles using CESM2: one of which incorporates observed wildfire emissions and one that does not. In response to the fires, an increase in biomass aerosol burdens across the southern hemisphere is simulated through late 2019 and early 2020, accompanied by an enhancement of cloud albedo, particularly in the southeastern subtropical Pacific Ocean. In turn, the surface cools, the boundary layer dries, and the moist static energy of the low-level flow into the equatorial Pacific is reduced. In response, the intertropical convergence zone migrates northward and sea surface temperature in the Niño3.4 region cools, with coupled feedbacks amplifying the cooling. A subsequent multiyear ensemble mean cooling of the tropical Pacific is simulated through the end of 2021, suggesting an important contribution to the 2020–2022 strong La Niña events.

1702地球物理及び地球化学
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