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Data-driven approaches to link climate drivers to energy impacts

気候変動影響をエネルギーシステムに結び付けるデータ駆動型アプローチ (AI 翻訳)

Esther Bakels, Nadia Bloemendaal, W. Jäger, Dim Coumou, Philip Ward

📚 査読済 / ジャーナル2026-06-22#エネルギー転換Origin: EU対象セクター: power
DOI: 10.5194/ems2026-640
原典: https://doi.org/10.5194/ems2026-640

🤖 gxceed AI 要約

日本語

本論文は、気候変動とエネルギーシステムの影響を結び付けるデータ駆動型フレームワークを提案する。欧州の再生可能エネルギー導入加速に伴う気象依存性の高まりを受け、エネルギー不足や高価格イベントなどの指標を用いて気候リスクを評価する。AIベースの予測手法を活用し、将来のシステムストレスをより正確に予測することを目指す。

English

This paper proposes a data-driven framework to link climate variability with energy system impacts, focusing on indicators like energy shortfall and high-price events. It explores AI-based forecasting to improve prediction of system stress under climate change, aiming to bridge the gap between climate and energy modeling communities.

Unofficial AI-generated summary based on the public title and abstract. Not an official translation.

📝 gxceed 編集解説 — Why this matters

日本のGX文脈において

欧州の再生可能エネルギー導入に伴う気候リスク分析は、日本でも電力システムの安定性評価に示唆を与える。特に気象依存電源の増加を踏まえ、データ駆動型の気候影響評価手法は日本企業のエネルギー調達リスク管理に応用可能。SSBJや有報での気候リスク開示とも関連する。

In the global GX context

This research supports global energy transition planning by integrating climate risk into energy system models. It aligns with TCFD/ISSB climate risk disclosure requirements, offering a methodology for assessing weather-driven impacts on electricity reliability and pricing.

👥 読者別の含意

🔬研究者:Useful for those studying climate-energy interactions and seeking methods to incorporate climate uncertainty into energy system models.

🏢実務担当者:Energy planners and grid operators can apply the framework to assess reliability risks and improve operational planning under future climate scenarios.

🏛政策担当者:Informs energy policy and climate adaptation strategies by highlighting the need for cross-disciplinary modeling to ensure resilient low-carbon systems.

📄 Abstract(原文)

The transition from fossil fuels to renewable energy sources in Europe is accelerating under climate policy commitments (Kapica et al., 2024), including the Paris Agreement (2015) and European Green deal (2019). This shift increasingly relies on weather-dependent generation from wind and solar power, while climate change is simultaneously intensifying summer heatwaves and associated cooling demand (Filahi et al., 2024). As a result, electricity systems are becoming more exposed to weather-driven variability, highlighting the need for more research in regions historically characterised by winter peak loads.Despite the growing importance of climate–energy interactions, progress in understanding these dynamics is still limited by a disconnect between climate and energy modelling communities. Climate modellers often do not provide outputs that are directly usable for energy system applications, while energy system models tend to overlook climate related uncertainty (Craig et al., 2022). This mismatch makes it difficult to properly assess system reliability and economic stress under future climate conditions.Some recent studies have started to bridge this gap by linking large-scale weather patterns to energy system impacts. For example, targeted circulation types have been developed to better capture weather sensitivity in electricity systems (Bloomfield et al., 2020), while other studies connect weather regimes directly to metrics such as Energy Not Served (ENS), reflecting system reliability from a grid operator perspective (Biewald et al., 2025; Wuijts et al., 2023). However, these approaches still struggle to fully account for climate uncertainty and economic signals such as price variability.This paper proposes a data-driven framework to better connect climate variability with energy system impacts, focusing on indicators such as energy shortfall, ENS and high-price events. Data-driven methods are explored to identify climate drivers behind these energy impacts, allowing a more system-relevant characterization of climate risks. These drivers can then be used as input for AI-based forecasting approaches, improving the prediction of system stress under uncertain future conditions. Bridging this gap is essential for ensuring reliable, affordable, and resilient low-carbon energy systems in a changing climate.

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