Mineral replacement reactions under advective flow often suffer from severe spatial inefficiency: dissolution causes the flow to self-focus into a few dominant wormholes that bypass the surrounding matrix, leaving most of the rock unreplaced. Here we show—through two-dimensional pore-network simulations—that replacement can be effective in two regimes. The first arises when the precipitation rate significantly exceeds the dissolution rate, leading to in situ replacement in which a uniform front of the secondary mineral advances through the matrix. The second, exploratory mode, occurs when the system repeatedly self-blocks and re-routes. In this regime, each channel lives only long enough to deliver reactant a short distance ahead of the front before its tip is cemented by the product phase; pressure re-routes through an adjacent corridor, and the cycle begins anew. Over time, the replacement front advances as a mosaic of overlapping micro-fronts, distributing the secondary mineral almost uniformly. We derive design criteria for achieving exploratory-mode behaviour and discuss implications for both natural and engineered reactive-infiltration systems.
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9 July 2026
Research Article|
March 19 2026
Retreat to advance: self-blocking enables efficient mineral replacement
A. Budek;
A. Budek
*Department of Earth and Environmental Sciences,
University of Minnesota
, Minneapolis, MN, USA
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T. Szawełło;
T. Szawełło
†Institute of Theoretical Physics, Faculty of Physics,
University of Warsaw
, Warsaw, Poland
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V. Voller;
‡Department of Civil, Environmental, and Geo Engineering and Saint Anthony Falls Laboratory,
University of Minnesota
, Minneapolis, MN, USA
Corresponding author V. Voller (piotrek@fuw.edu.pl)
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P. Szymczak
P. Szymczak
§Institute of Theoretical Physics, Faculty of Physics,
University of Warsaw
, Warsaw, Poland
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Corresponding author V. Voller (piotrek@fuw.edu.pl)
Publisher: Emerald Publishing
Received:
August 30 2025
Accepted:
December 26 2025
Online ISSN: 2045-2543
© 2026 Emerald Publishing Limited
2026
Emerald Publishing Limited
Licensed re-use rights only
Geotechnique Letters (2026) 16 (2): 124–130.
Article history
Received:
August 30 2025
Accepted:
December 26 2025
Citation
Budek A, Szawełło T, Voller V, Szymczak P (2026), "Retreat to advance: self-blocking enables efficient mineral replacement". Geotechnique Letters, Vol. 16 No. 2 pp. 124–130, doi: https://doi.org/10.1680/jgele.25.00094
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