Microstructural evolution of compacted granular salt: insights from 40-year-old backfill at a former potash mine (Sigmundshall, northern Germany)

IF 2.6 2区地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY

Journal of Structural Geology Pub Date : 2025-04-14 DOI:10.1016/j.jsg.2025.105429

Kristoff Svensson , Bart van Oosterhout , Jürgen Hesser , Christopher J. Spiers , Ben Laurich

{"title":"Microstructural evolution of compacted granular salt: insights from 40-year-old backfill at a former potash mine (Sigmundshall, northern Germany)","authors":"Kristoff Svensson , Bart van Oosterhout , Jürgen Hesser , Christopher J. Spiers , Ben Laurich","doi":"10.1016/j.jsg.2025.105429","DOIUrl":null,"url":null,"abstract":"<div><div>Compacted granular salt backfill is widely regarded as the most favorable geotechnical barrier for sealing a radioactive waste repository within a rock salt formation. However, the reduction of salt backfill porosity and permeability during compaction by slowly converging cavity walls is still a matter of on-going research, both in laboratory and underground experiments, as well as in computational forecasting. Here, we present an in-depth microstructural analysis of a dense, formerly deployed salt backfill material, recovered from the decommissioned salt mine Sigmundshall, Bokeloh, Germany. The backfill compacted over 40 years, resulting in as little as 1 % porosity (+4/-1 %). Some differences are inevitable compared to a potential future backfill emplaced in a radioactive repository, notably in grain size, moisture content and backfill height (178 m vs. ∼ 5 m). However, this valuable “natural laboratory” sampling opportunity has allowed microstructural evidence to be sought for the deformation mechanisms that control salt backfill compaction under in-situ deployment conditions and on timescales that cannot be achieved in laboratory tests. For the present example of grain sizes in the range of 50 μm to 3 mm, our results show that more or less complete densification of granular salt is feasible in a timeframe of decades (<40 y). Pressure solution is likely the main deformation mechanism along with limited cataclasis, which presumably occurred only in the early stages during/after emplacement. This conclusion is evident from tight, indenting, truncating and interpenetrating grain boundaries, as well as from the fact that almost all grains appear to be substructure-free, despite limited signs of recrystallization. The absence of intra-crystalline deformation indicators excludes dislocation creep as a compaction-contributing mechanism, which, on the other hand, is known to occur in many laboratory-based compaction tests. We outline the impact of this difference on the long-term in-situ compaction under repository conditions.</div><div>Note: The Sigmundshall mine is not considered as a future repository for radioactive waste.</div></div>","PeriodicalId":50035,"journal":{"name":"Journal of Structural Geology","volume":"197 ","pages":"Article 105429"},"PeriodicalIF":2.6000,"publicationDate":"2025-04-14","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Structural Geology","FirstCategoryId":"89","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S019181412500104X","RegionNum":2,"RegionCategory":"地球科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"GEOSCIENCES, MULTIDISCIPLINARY","Score":null,"Total":0}

引用次数: 0

Abstract

Compacted granular salt backfill is widely regarded as the most favorable geotechnical barrier for sealing a radioactive waste repository within a rock salt formation. However, the reduction of salt backfill porosity and permeability during compaction by slowly converging cavity walls is still a matter of on-going research, both in laboratory and underground experiments, as well as in computational forecasting. Here, we present an in-depth microstructural analysis of a dense, formerly deployed salt backfill material, recovered from the decommissioned salt mine Sigmundshall, Bokeloh, Germany. The backfill compacted over 40 years, resulting in as little as 1 % porosity (+4/-1 %). Some differences are inevitable compared to a potential future backfill emplaced in a radioactive repository, notably in grain size, moisture content and backfill height (178 m vs. ∼ 5 m). However, this valuable “natural laboratory” sampling opportunity has allowed microstructural evidence to be sought for the deformation mechanisms that control salt backfill compaction under in-situ deployment conditions and on timescales that cannot be achieved in laboratory tests. For the present example of grain sizes in the range of 50 μm to 3 mm, our results show that more or less complete densification of granular salt is feasible in a timeframe of decades (<40 y). Pressure solution is likely the main deformation mechanism along with limited cataclasis, which presumably occurred only in the early stages during/after emplacement. This conclusion is evident from tight, indenting, truncating and interpenetrating grain boundaries, as well as from the fact that almost all grains appear to be substructure-free, despite limited signs of recrystallization. The absence of intra-crystalline deformation indicators excludes dislocation creep as a compaction-contributing mechanism, which, on the other hand, is known to occur in many laboratory-based compaction tests. We outline the impact of this difference on the long-term in-situ compaction under repository conditions.

Note: The Sigmundshall mine is not considered as a future repository for radioactive waste.

查看原文本刊更多论文

密实颗粒盐的微观结构演化：来自前钾肥矿40年回填的见解（德国北部西格蒙德肖）

压实颗粒盐充填体被广泛认为是密封岩盐地层中放射性废物储存库的最有利的岩土技术屏障。然而，通过缓慢收缩空腔壁压实降低盐充填体孔隙度和渗透率仍然是一个正在进行的研究问题，无论是在实验室和地下实验中，还是在计算预测中。在这里，我们提出了一个深入的微观结构分析密集，以前部署的盐回填材料，从退役的盐矿Sigmundshall， Bokeloh，德国回收。充填体经过40年的压实，孔隙率低至1%（+4/- 1%）。与放射性储存库中潜在的未来回填体相比，一些差异是不可避免的，特别是在粒度、含水率和回填体高度（178米对~ 5米）方面。然而，这一宝贵的“自然实验室”采样机会使人们能够在实验室测试中无法实现的现场部署条件和时间尺度下，寻找控制盐回填体压实的变形机制的微观结构证据。对于50 μm至3 mm的晶粒尺寸，我们的结果表明，在几十年（40 y）的时间框架内，颗粒盐或多或少完全致密化是可行的。压力溶解可能是主要的变形机制，而有限的碎裂可能只发生在放置期间/之后的早期阶段。这一结论可以从紧密的、凹陷的、截断的和互穿的晶界，以及几乎所有晶粒都没有亚结构的事实中得到证明，尽管有有限的再结晶迹象。晶体内变形指标的缺失排除了位错蠕变作为压实促进机制的可能性，另一方面，在许多实验室压实试验中，位错蠕变是已知的。我们概述了这种差异对储存库条件下长期原位压实的影响。注：西格蒙德沙尔矿不被认为是未来的放射性废物储存库。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Journal of Structural Geology 地学-地球科学综合

CiteScore

6.00

自引率

19.40%

发文量

192

审稿时长

15.7 weeks

期刊介绍： The Journal of Structural Geology publishes process-oriented investigations about structural geology using appropriate combinations of analog and digital field data, seismic reflection data, satellite-derived data, geometric analysis, kinematic analysis, laboratory experiments, computer visualizations, and analogue or numerical modelling on all scales. Contributions are encouraged to draw perspectives from rheology, rock mechanics, geophysics,metamorphism, sedimentology, petroleum geology, economic geology, geodynamics, planetary geology, tectonics and neotectonics to provide a more powerful understanding of deformation processes and systems. Given the visual nature of the discipline, supplementary materials that portray the data and analysis in 3-D or quasi 3-D manners, including the use of videos, and/or graphical abstracts can significantly strengthen the impact of contributions.