Spatial multi-criteria play-based analysis for HT-ATES systems across the Swiss Molasse Plateau

IF 4.7 3区工程技术 Q2 ENERGY & FUELS

Energy Reports Pub Date : 2025-06-09 DOI:10.1016/j.egyr.2025.05.064

L. Guglielmetti , R. Lehu , A. Daniilidis , B. Valley , A. Moscariello

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Abstract

Energy storage plays a crucial role in decarbonizing the global energy system, particularly in the heating sector, which accounts for nearly 50 % of global energy demand. However, a significant challenge remains in balancing supply and demand from renewable energy sources. High-Temperature Aquifer Thermal Energy Storage (HT-ATES) presents a promising solution by enabling seasonal energy storage and shifting thermal loads efficiently. The successful implementation of HT-ATES requires a comprehensive understanding of both subsurface geological conditions and surface constraints to identify optimal storage sites. This study introduces a favorability assessment framework for HT-ATES systems across the Swiss Molasse Plateau (SMP), utilizing spatial multi-criteria play-based analysis (SMCPBA). Two key geological targets—the Cenozoic Molasse and Upper Mesozoic formations—are assessed alongside energy system criteria to pinpoint high-potential areas for future development. The findings highlight major urban centers such as Geneva, Lausanne, and Zurich as prime candidates due to their significant heat demand. However, broad-scale estimations necessitate higher-resolution data and site-specific feasibility studies for accurate assessment and implementation. The scalability of this methodology makes it applicable to various geographic contexts, supporting targeted pilot projects and feasibility assessments. Advancing HT-ATES technologies through refined methodologies and practical applications will contribute to Switzerland’s sustainable energy transition and long-term energy resilience.

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瑞士Molasse高原HT-ATES系统的空间多标准游戏分析

能源储存在全球能源系统脱碳方面发挥着至关重要的作用，特别是在供热部门，该部门占全球能源需求的近50% %。然而，平衡可再生能源的供需仍然是一个重大挑战。高温含水层热能储存（HT-ATES）是一种很有前途的解决方案，可以实现季节性能量储存和有效地转移热负荷。HT-ATES的成功实施需要全面了解地下地质条件和地表限制条件，以确定最佳储存地点。本研究利用基于空间的多标准游戏分析（SMCPBA），介绍了瑞士Molasse高原（SMP） HT-ATES系统的好感度评估框架。两个关键的地质目标-新生代Molasse和上中生代地层-与能源系统标准一起进行评估，以确定未来开发的高潜力区域。研究结果强调，日内瓦、洛桑和苏黎世等主要城市中心因其巨大的热需求而成为主要候选者。然而，大规模的估算需要更高分辨率的数据和具体地点的可行性研究，以便进行准确的评估和执行。该方法的可扩展性使其适用于各种地理环境，支持有针对性的试点项目和可行性评估。通过完善的方法和实际应用推进HT-ATES技术将有助于瑞士的可持续能源转型和长期能源弹性。

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

Energy Reports Energy-General Energy

CiteScore

8.20

自引率

13.50%

发文量

2608

审稿时长

38 days

期刊介绍： Energy Reports is a new online multidisciplinary open access journal which focuses on publishing new research in the area of Energy with a rapid review and publication time. Energy Reports will be open to direct submissions and also to submissions from other Elsevier Energy journals, whose Editors have determined that Energy Reports would be a better fit.