Coulomb explosion during the early stages of the reaction of alkali metals with water

Philip E. Mason; Frank Uhlig; Václav Vaněk; Tillmann Buttersack; Sigurd Bauerecker; Pavel Jungwirth

doi:10.1038/nchem.2161

Coulomb explosion during the early stages of the reaction of alkali metals with water

Philip E. Mason, Frank Uhlig, Václav Vaněk, Tillmann Buttersack, Sigurd Bauerecker, Pavel Jungwirth

Research output: Contribution to journal › Article › Scientific › peer-review

90 Citations (Scopus)

Abstract

Alkali metals can react explosively with water and it is textbook knowledge that this vigorous behaviour results from heat release, steam formation and ignition of the hydrogen gas that is produced. Here we suggest that the initial process enabling the alkali metal explosion in water is, however, of a completely different nature. High-speed camera imaging of liquid drops of a sodium/potassium alloy in water reveals submillisecond formation of metal spikes that protrude from the surface of the drop. Molecular dynamics simulations demonstrate that on immersion in water there is an almost immediate release of electrons from the metal surface. The system thus quickly reaches the Rayleigh instability limit, which leads to a 'coulomb explosion' of the alkali metal drop. Consequently, a new metal surface in contact with water is formed, which explains why the reaction does not become self-quenched by its products, but can rather lead to explosive behaviour.

Original language	English
Pages (from-to)	250-254
Number of pages	5
Journal	Nature Chemistry
Volume	7
Issue number	3
DOIs	https://doi.org/10.1038/nchem.2161
Publication status	Published - 2015
Publication type	A1 Journal article-refereed

ASJC Scopus subject areas

General Chemistry
General Chemical Engineering

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abstract = "Alkali metals can react explosively with water and it is textbook knowledge that this vigorous behaviour results from heat release, steam formation and ignition of the hydrogen gas that is produced. Here we suggest that the initial process enabling the alkali metal explosion in water is, however, of a completely different nature. High-speed camera imaging of liquid drops of a sodium/potassium alloy in water reveals submillisecond formation of metal spikes that protrude from the surface of the drop. Molecular dynamics simulations demonstrate that on immersion in water there is an almost immediate release of electrons from the metal surface. The system thus quickly reaches the Rayleigh instability limit, which leads to a 'coulomb explosion' of the alkali metal drop. Consequently, a new metal surface in contact with water is formed, which explains why the reaction does not become self-quenched by its products, but can rather lead to explosive behaviour.",

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AU - Mason, Philip E.

AU - Uhlig, Frank

AU - Vaněk, Václav

AU - Buttersack, Tillmann

AU - Bauerecker, Sigurd

AU - Jungwirth, Pavel

PY - 2015

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AB - Alkali metals can react explosively with water and it is textbook knowledge that this vigorous behaviour results from heat release, steam formation and ignition of the hydrogen gas that is produced. Here we suggest that the initial process enabling the alkali metal explosion in water is, however, of a completely different nature. High-speed camera imaging of liquid drops of a sodium/potassium alloy in water reveals submillisecond formation of metal spikes that protrude from the surface of the drop. Molecular dynamics simulations demonstrate that on immersion in water there is an almost immediate release of electrons from the metal surface. The system thus quickly reaches the Rayleigh instability limit, which leads to a 'coulomb explosion' of the alkali metal drop. Consequently, a new metal surface in contact with water is formed, which explains why the reaction does not become self-quenched by its products, but can rather lead to explosive behaviour.

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Coulomb explosion during the early stages of the reaction of alkali metals with water

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