Release of mercury during contact metamorphism of shale: Implications for understanding the impacts of large igneous province volcanism

Henrik H. Svensen; Morgan T. Jones; Lawrence M.E. Percival; Stephen E. Grasby; Tamsin A. Mather

doi:10.1016/j.epsl.2023.118306

Release of mercury during contact metamorphism of shale: Implications for understanding the impacts of large igneous province volcanism

Henrik H. Svensen
, Morgan T. Jones
, Lawrence M.E. Percival
, Stephen E. Grasby
, Tamsin A. Mather

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

Elevated mercury (Hg) in sedimentary strata are a widely used tracer for assessing the relationship between large igneous province (LIP) activity and global environmental change. A key unknown in applying this proxy is the extent to which Hg was sourced from contact metamorphism of sedimentary rocks during sill intrusions versus gaseous emissions of the magmas themselves. Here, we investigate Hg behaviour during contact metamorphism of shales. We show loss of 80–99% of the sedimentary Hg in contact aureoles in four case studies covering the interactions around dykes, sills and plutons associated the High Arctic LIP (Sverdrup Basin, Canada), the Karoo LIP (South Africa) and the Skagerrak-centred LIP (Oslo Rift, Norway). A combination of geochemical data and thermal modelling around a dyke from the High Arctic LIP shows 33% Hg volatilization in the aureole at 265–300 °C. The other cases show similar behaviours with significant lowering of organic-bound Hg, more significantly in the innermost 60% of the contact aureoles. We hypothesize that gaseous Hg is transported out of aureoles during metamorphism, together with CH4 and CO2. Furthermore, we estimate the thermogenic Hg mobilization from Karoo LIP aureoles as 72–192 t per km3 of aureole, which is between 1–3 times the estimated volumetric Hg release from Karoo magmas. When scaling our results to the size of the shale portions of the Karoo Basin affected by the LIP and a timescale of 100 kyr of sill emplacement, the average Hg flux is calculated to have been 78–207 t/y with maximum values up to ∼300 t/y. The pulsed nature of intrusive volcanism suggests that this thermogenic Hg flux could have dominated LIP Hg emissions during periods of their life span. Our results demonstrate that the global Hg cycle can be significantly perturbed following LIP-scale sill emplacement into organic-rich sedimentary rocks and our quantification of the emissions based on source-rock analysis provides important information for independent interpretation of the sedimentary Hg record.

Original language	English
Article number	118306
Pages (from-to)	1-12
Number of pages	12
Journal	Earth and Planetary Science Letters
Volume	619
Early online date	26 Jul 2023
DOIs	https://doi.org/10.1016/j.epsl.2023.118306
Publication status	Published - 1 Oct 2023
Externally published	Yes

Funding

We gratefully acknowledge support from the Norwegian Research Council (grant number 263000 to M.T.J., and grant number 223272 to CEED). We also would like to thank the Council of Geoscience and the National Core Library in South Africa, for access to cores. T.A.M. acknowledges funding from ERC consolidator grant ( ERC-2018-COG-818717-V-ECHO ). LMEP thanks the Research Foundation – Flanders (FWO: grant 12P4522N ) for funding. We would also like to thank Sverre Planke and Øyvind Hammer for discussions, fieldwork, and lasting enthusiasm, and Michael Heeremans for providing the map in Fig. 1 A. We gratefully acknowledge support from the Norwegian Research Council (grant number 263000 to M.T.J. and grant number 223272 to CEED). We also would like to thank the Council of Geoscience and the National Core Library in South Africa, for access to cores. T.A.M. acknowledges funding from ERC consolidator grant (ERC-2018-COG-818717-V-ECHO). LMEP thanks the Research Foundation – Flanders (FWO: grant 12P4522N) for funding. We would also like to thank Sverre Planke and Øyvind Hammer for discussions, fieldwork, and lasting enthusiasm, and Michael Heeremans for providing the map in Fig. 1A.

Funders	Funder number
National Core Library in South Africa
Fonds Wetenschappelijk Onderzoek	12P4522N
Norges forskningsråd	223272, 263000, ERC-2018-COG-818717-V-ECHO

Access to Document

10.1016/j.epsl.2023.118306Licence: CC BY

Persistent URL (handle)

Persistent link

Cite this

@article{ccbd7166f0e94a6da3d9ab7da46a31ce,

title = "Release of mercury during contact metamorphism of shale: Implications for understanding the impacts of large igneous province volcanism",

abstract = "Elevated mercury (Hg) in sedimentary strata are a widely used tracer for assessing the relationship between large igneous province (LIP) activity and global environmental change. A key unknown in applying this proxy is the extent to which Hg was sourced from contact metamorphism of sedimentary rocks during sill intrusions versus gaseous emissions of the magmas themselves. Here, we investigate Hg behaviour during contact metamorphism of shales. We show loss of 80–99\% of the sedimentary Hg in contact aureoles in four case studies covering the interactions around dykes, sills and plutons associated the High Arctic LIP (Sverdrup Basin, Canada), the Karoo LIP (South Africa) and the Skagerrak-centred LIP (Oslo Rift, Norway). A combination of geochemical data and thermal modelling around a dyke from the High Arctic LIP shows 33\% Hg volatilization in the aureole at 265–300 °C. The other cases show similar behaviours with significant lowering of organic-bound Hg, more significantly in the innermost 60\% of the contact aureoles. We hypothesize that gaseous Hg is transported out of aureoles during metamorphism, together with CH4 and CO2. Furthermore, we estimate the thermogenic Hg mobilization from Karoo LIP aureoles as 72–192 t per km3 of aureole, which is between 1–3 times the estimated volumetric Hg release from Karoo magmas. When scaling our results to the size of the shale portions of the Karoo Basin affected by the LIP and a timescale of 100 kyr of sill emplacement, the average Hg flux is calculated to have been 78–207 t/y with maximum values up to ∼300 t/y. The pulsed nature of intrusive volcanism suggests that this thermogenic Hg flux could have dominated LIP Hg emissions during periods of their life span. Our results demonstrate that the global Hg cycle can be significantly perturbed following LIP-scale sill emplacement into organic-rich sedimentary rocks and our quantification of the emissions based on source-rock analysis provides important information for independent interpretation of the sedimentary Hg record.",

author = "Svensen, \{Henrik H.\} and Jones, \{Morgan T.\} and Percival, \{Lawrence M.E.\} and Grasby, \{Stephen E.\} and Mather, \{Tamsin A.\}",

year = "2023",

month = oct,

day = "1",

doi = "10.1016/j.epsl.2023.118306",

language = "English",

volume = "619",

pages = "1--12",

journal = "Earth and Planetary Science Letters",

issn = "0012-821X",

publisher = "Elsevier B.V.",

}

TY - JOUR

T1 - Release of mercury during contact metamorphism of shale

T2 - Implications for understanding the impacts of large igneous province volcanism

AU - Svensen, Henrik H.

AU - Jones, Morgan T.

AU - Percival, Lawrence M.E.

AU - Grasby, Stephen E.

AU - Mather, Tamsin A.

PY - 2023/10/1

Y1 - 2023/10/1

N2 - Elevated mercury (Hg) in sedimentary strata are a widely used tracer for assessing the relationship between large igneous province (LIP) activity and global environmental change. A key unknown in applying this proxy is the extent to which Hg was sourced from contact metamorphism of sedimentary rocks during sill intrusions versus gaseous emissions of the magmas themselves. Here, we investigate Hg behaviour during contact metamorphism of shales. We show loss of 80–99% of the sedimentary Hg in contact aureoles in four case studies covering the interactions around dykes, sills and plutons associated the High Arctic LIP (Sverdrup Basin, Canada), the Karoo LIP (South Africa) and the Skagerrak-centred LIP (Oslo Rift, Norway). A combination of geochemical data and thermal modelling around a dyke from the High Arctic LIP shows 33% Hg volatilization in the aureole at 265–300 °C. The other cases show similar behaviours with significant lowering of organic-bound Hg, more significantly in the innermost 60% of the contact aureoles. We hypothesize that gaseous Hg is transported out of aureoles during metamorphism, together with CH4 and CO2. Furthermore, we estimate the thermogenic Hg mobilization from Karoo LIP aureoles as 72–192 t per km3 of aureole, which is between 1–3 times the estimated volumetric Hg release from Karoo magmas. When scaling our results to the size of the shale portions of the Karoo Basin affected by the LIP and a timescale of 100 kyr of sill emplacement, the average Hg flux is calculated to have been 78–207 t/y with maximum values up to ∼300 t/y. The pulsed nature of intrusive volcanism suggests that this thermogenic Hg flux could have dominated LIP Hg emissions during periods of their life span. Our results demonstrate that the global Hg cycle can be significantly perturbed following LIP-scale sill emplacement into organic-rich sedimentary rocks and our quantification of the emissions based on source-rock analysis provides important information for independent interpretation of the sedimentary Hg record.

AB - Elevated mercury (Hg) in sedimentary strata are a widely used tracer for assessing the relationship between large igneous province (LIP) activity and global environmental change. A key unknown in applying this proxy is the extent to which Hg was sourced from contact metamorphism of sedimentary rocks during sill intrusions versus gaseous emissions of the magmas themselves. Here, we investigate Hg behaviour during contact metamorphism of shales. We show loss of 80–99% of the sedimentary Hg in contact aureoles in four case studies covering the interactions around dykes, sills and plutons associated the High Arctic LIP (Sverdrup Basin, Canada), the Karoo LIP (South Africa) and the Skagerrak-centred LIP (Oslo Rift, Norway). A combination of geochemical data and thermal modelling around a dyke from the High Arctic LIP shows 33% Hg volatilization in the aureole at 265–300 °C. The other cases show similar behaviours with significant lowering of organic-bound Hg, more significantly in the innermost 60% of the contact aureoles. We hypothesize that gaseous Hg is transported out of aureoles during metamorphism, together with CH4 and CO2. Furthermore, we estimate the thermogenic Hg mobilization from Karoo LIP aureoles as 72–192 t per km3 of aureole, which is between 1–3 times the estimated volumetric Hg release from Karoo magmas. When scaling our results to the size of the shale portions of the Karoo Basin affected by the LIP and a timescale of 100 kyr of sill emplacement, the average Hg flux is calculated to have been 78–207 t/y with maximum values up to ∼300 t/y. The pulsed nature of intrusive volcanism suggests that this thermogenic Hg flux could have dominated LIP Hg emissions during periods of their life span. Our results demonstrate that the global Hg cycle can be significantly perturbed following LIP-scale sill emplacement into organic-rich sedimentary rocks and our quantification of the emissions based on source-rock analysis provides important information for independent interpretation of the sedimentary Hg record.

UR - https://www.scopus.com/pages/publications/85165978615

U2 - 10.1016/j.epsl.2023.118306

DO - 10.1016/j.epsl.2023.118306

M3 - Article

SN - 0012-821X

VL - 619

SP - 1

EP - 12

JO - Earth and Planetary Science Letters

JF - Earth and Planetary Science Letters

M1 - 118306

ER -

Release of mercury during contact metamorphism of shale: Implications for understanding the impacts of large igneous province volcanism

Abstract

Funding

Access to Document

Persistent URL (handle)

Other files and links

Fingerprint

Cite this