Mercury Sourcing and Sequestration in Weathering Profiles at Six Critical Zone Observatories

Justin B. Richardson; Arnulfo A. Aguirre; Heather L. Buss; A. Toby O'Geen; Xin Gu; Daniella M. Rempe; Daniel de B. Richter

doi:10.1029/2018GB005974

Mercury Sourcing and Sequestration in Weathering Profiles at Six Critical Zone Observatories

Justin B. Richardson
, Arnulfo A. Aguirre
, Heather L. Buss
, A. Toby O'Geen
, Xin Gu
, Daniella M. Rempe
, Daniel de B. Richter

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

19 Scopus citations

Abstract

Mercury sequestration in regolith (soils + weathered bedrock) is an important ecosystem service of the critical zone. This has largely remained unexplored, due to the difficulty of sample collection and the assumption that Hg is predominantly sequestered within surface soils (here we define as 0–0.3 m). We measured Hg concentrations and inventories in weathering profiles at six Critical Zone Observatories (CZOs): Boulder Creek in the Front Range of Colorado, Calhoun in the South Carolina Piedmont, Eel River in coastal northern California, Luquillo in the tropical montane forest of Puerto Rico, Shale Hills of the valley and ridges of central Pennsylvania, and Southern Sierra in the Sierra Nevada range of California. Surface soils had higher Hg concentrations than the deepest regolith samples, except for Eel River, which had lower Hg concentrations in surface soils compared to regolith. Using Ti normalization, CZOs with <12% rock-derived Hg (Boulder Creek, Calhoun, and Southern Sierra) had Hg peaks between 1.5 and 8.0 m in depth. At CZOs with >50% rock-derived Hg, Eel River Hg concentrations and pools were greatest at >4.0 m in the weathering profile, while Luquillo and Shale Hills had peaks at the surface that diminished within 1.0 m of the surface. Hg and total organic C were only significantly correlated in regolith at Luquillo and Shale Hills CZOs, suggesting that Hg sorption to organic matter may be less dominant than clays or Fe(II) sulfides in deeper regolith. Our results demonstrate the importance of Hg sequestration in deep regolith, below typical soil sampling depths.

Original language	English
Pages (from-to)	1542-1555
Number of pages	14
Journal	Global Biogeochemical Cycles
Volume	32
Issue number	10
DOIs	https://doi.org/10.1029/2018GB005974
State	Published - Oct 2018
Externally published	Yes

Funding

This work was made possible by the National Science Foundation grant (NSF-1360760) to the Critical Zone Observatory Network National Office. Funding from the National Science Foundation for each CZO was also instrumental in this project: Boulder Creek (NSF-1331828), Calhoun (NSF-1331846), Eel River (NSF-1331940), Luquillo (NSF-1331841), Shale Hills (NSF-1331726), and Southern Sierra (NSF-1331939). The authors are thankful for the help with obtaining samples from Erin Stacy (UC Merced), Stephen Hart (UC Merced), Scott Hynek (Penn State), Sue Brantley (Penn State), and Andy Kurtz (Boston University). We are thankful for the UC Angelo Coast Range Reserve and the analytical help from Brian Jackson (Dartmouth College) and Mary Catherine Reinthal (Cornell). Mercury concentration and inventory data are available in the supporting information.

Keywords

critical zone
excess mercury
mercury cycling
mercury inventories
regolith
soil

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10.1029/2018GB005974

Cite this

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title = "Mercury Sourcing and Sequestration in Weathering Profiles at Six Critical Zone Observatories",

abstract = "Mercury sequestration in regolith (soils + weathered bedrock) is an important ecosystem service of the critical zone. This has largely remained unexplored, due to the difficulty of sample collection and the assumption that Hg is predominantly sequestered within surface soils (here we define as 0–0.3 m). We measured Hg concentrations and inventories in weathering profiles at six Critical Zone Observatories (CZOs): Boulder Creek in the Front Range of Colorado, Calhoun in the South Carolina Piedmont, Eel River in coastal northern California, Luquillo in the tropical montane forest of Puerto Rico, Shale Hills of the valley and ridges of central Pennsylvania, and Southern Sierra in the Sierra Nevada range of California. Surface soils had higher Hg concentrations than the deepest regolith samples, except for Eel River, which had lower Hg concentrations in surface soils compared to regolith. Using Ti normalization, CZOs with <12\% rock-derived Hg (Boulder Creek, Calhoun, and Southern Sierra) had Hg peaks between 1.5 and 8.0 m in depth. At CZOs with >50\% rock-derived Hg, Eel River Hg concentrations and pools were greatest at >4.0 m in the weathering profile, while Luquillo and Shale Hills had peaks at the surface that diminished within 1.0 m of the surface. Hg and total organic C were only significantly correlated in regolith at Luquillo and Shale Hills CZOs, suggesting that Hg sorption to organic matter may be less dominant than clays or Fe(II) sulfides in deeper regolith. Our results demonstrate the importance of Hg sequestration in deep regolith, below typical soil sampling depths.",

keywords = "critical zone, excess mercury, mercury cycling, mercury inventories, regolith, soil",

author = "Richardson, \{Justin B.\} and Aguirre, \{Arnulfo A.\} and Buss, \{Heather L.\} and \{Toby O'Geen\}, A. and Xin Gu and Rempe, \{Daniella M.\} and Richter, \{Daniel de B.\}",

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AU - Aguirre, Arnulfo A.

AU - Buss, Heather L.

AU - Toby O'Geen, A.

AU - Gu, Xin

AU - Rempe, Daniella M.

AU - Richter, Daniel de B.

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N2 - Mercury sequestration in regolith (soils + weathered bedrock) is an important ecosystem service of the critical zone. This has largely remained unexplored, due to the difficulty of sample collection and the assumption that Hg is predominantly sequestered within surface soils (here we define as 0–0.3 m). We measured Hg concentrations and inventories in weathering profiles at six Critical Zone Observatories (CZOs): Boulder Creek in the Front Range of Colorado, Calhoun in the South Carolina Piedmont, Eel River in coastal northern California, Luquillo in the tropical montane forest of Puerto Rico, Shale Hills of the valley and ridges of central Pennsylvania, and Southern Sierra in the Sierra Nevada range of California. Surface soils had higher Hg concentrations than the deepest regolith samples, except for Eel River, which had lower Hg concentrations in surface soils compared to regolith. Using Ti normalization, CZOs with <12% rock-derived Hg (Boulder Creek, Calhoun, and Southern Sierra) had Hg peaks between 1.5 and 8.0 m in depth. At CZOs with >50% rock-derived Hg, Eel River Hg concentrations and pools were greatest at >4.0 m in the weathering profile, while Luquillo and Shale Hills had peaks at the surface that diminished within 1.0 m of the surface. Hg and total organic C were only significantly correlated in regolith at Luquillo and Shale Hills CZOs, suggesting that Hg sorption to organic matter may be less dominant than clays or Fe(II) sulfides in deeper regolith. Our results demonstrate the importance of Hg sequestration in deep regolith, below typical soil sampling depths.

AB - Mercury sequestration in regolith (soils + weathered bedrock) is an important ecosystem service of the critical zone. This has largely remained unexplored, due to the difficulty of sample collection and the assumption that Hg is predominantly sequestered within surface soils (here we define as 0–0.3 m). We measured Hg concentrations and inventories in weathering profiles at six Critical Zone Observatories (CZOs): Boulder Creek in the Front Range of Colorado, Calhoun in the South Carolina Piedmont, Eel River in coastal northern California, Luquillo in the tropical montane forest of Puerto Rico, Shale Hills of the valley and ridges of central Pennsylvania, and Southern Sierra in the Sierra Nevada range of California. Surface soils had higher Hg concentrations than the deepest regolith samples, except for Eel River, which had lower Hg concentrations in surface soils compared to regolith. Using Ti normalization, CZOs with <12% rock-derived Hg (Boulder Creek, Calhoun, and Southern Sierra) had Hg peaks between 1.5 and 8.0 m in depth. At CZOs with >50% rock-derived Hg, Eel River Hg concentrations and pools were greatest at >4.0 m in the weathering profile, while Luquillo and Shale Hills had peaks at the surface that diminished within 1.0 m of the surface. Hg and total organic C were only significantly correlated in regolith at Luquillo and Shale Hills CZOs, suggesting that Hg sorption to organic matter may be less dominant than clays or Fe(II) sulfides in deeper regolith. Our results demonstrate the importance of Hg sequestration in deep regolith, below typical soil sampling depths.

KW - critical zone

KW - excess mercury

KW - mercury cycling

KW - mercury inventories

KW - regolith

KW - soil

UR - https://www.scopus.com/pages/publications/85055523253

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DO - 10.1029/2018GB005974

M3 - Article

AN - SCOPUS:85055523253

SN - 0886-6236

VL - 32

SP - 1542

EP - 1555

JO - Global Biogeochemical Cycles

JF - Global Biogeochemical Cycles

IS - 10

ER -

Mercury Sourcing and Sequestration in Weathering Profiles at Six Critical Zone Observatories

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Keywords

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