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Main Authors: Menke, Hannah P., Jangda, Zaid Z., Webb, Max, Buckman, Jim, Gough, Amy
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.09466
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author Menke, Hannah P.
Jangda, Zaid Z.
Webb, Max
Buckman, Jim
Gough, Amy
author_facet Menke, Hannah P.
Jangda, Zaid Z.
Webb, Max
Buckman, Jim
Gough, Amy
contents Natural hydrogen generated by water-rock interaction in ultramafic rocks is increasingly recognised as a potentially important primary energy resource, but the pore-scale processes that control the initiation and early transport of a free gas phase remain poorly constrained. Here we present an in situ X-ray micro-tomography experiment in which an ultramafic granular pack of dunnite from West Papua, Indonesia, saturated with KI-doped brine, is heated to 100C with a pore pressure of 4bar under 10bar confining pressure inside a micro-CT scanner. Time-resolved 4D imaging captures the transition from a fully liquid-saturated pore space to the appearance and growth of a distinct gas phase after an 8h induction period. Bubbles first nucleate near the top of the sample before becoming distributed throughout the imaged volume as a connected ganglia. The nucleating gas phase is most plausibly dominated by molecular hydrogen generated by low-temperature fluid-rock reaction, as indicated by independent hydrogen-presence detectors, although we cannot yet fully exclude minor contributions from other gases. SEM-BEX imaging reveals textural alteration and local changes in elemental signals between reacted and unreacted material. Taken together, these observations provide spatially and temporally resolved evidence for gas generation during low-temperature alteration of ultramafic grains and demonstrate that pore-scale imaging can directly link water-rock reaction kinetics, gas generation and multiphase flow behaviour in natural hydrogen systems.
format Preprint
id arxiv_https___arxiv_org_abs_2512_09466
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A First Look at Hydrogen Generation in an Ultramafic Rock with Micro-CT and SEM-BEX
Menke, Hannah P.
Jangda, Zaid Z.
Webb, Max
Buckman, Jim
Gough, Amy
Other Condensed Matter
Natural hydrogen generated by water-rock interaction in ultramafic rocks is increasingly recognised as a potentially important primary energy resource, but the pore-scale processes that control the initiation and early transport of a free gas phase remain poorly constrained. Here we present an in situ X-ray micro-tomography experiment in which an ultramafic granular pack of dunnite from West Papua, Indonesia, saturated with KI-doped brine, is heated to 100C with a pore pressure of 4bar under 10bar confining pressure inside a micro-CT scanner. Time-resolved 4D imaging captures the transition from a fully liquid-saturated pore space to the appearance and growth of a distinct gas phase after an 8h induction period. Bubbles first nucleate near the top of the sample before becoming distributed throughout the imaged volume as a connected ganglia. The nucleating gas phase is most plausibly dominated by molecular hydrogen generated by low-temperature fluid-rock reaction, as indicated by independent hydrogen-presence detectors, although we cannot yet fully exclude minor contributions from other gases. SEM-BEX imaging reveals textural alteration and local changes in elemental signals between reacted and unreacted material. Taken together, these observations provide spatially and temporally resolved evidence for gas generation during low-temperature alteration of ultramafic grains and demonstrate that pore-scale imaging can directly link water-rock reaction kinetics, gas generation and multiphase flow behaviour in natural hydrogen systems.
title A First Look at Hydrogen Generation in an Ultramafic Rock with Micro-CT and SEM-BEX
topic Other Condensed Matter
url https://arxiv.org/abs/2512.09466