New dating method: Groundwater residence time estimated from the 4He accumulation rate calibrated by using cosmogenic and subsurface-produced 36Cl

Y. Mahara; T. Ohta; T. Kubota; K. Miyakawa; T. Hasegawa; M. A. Habermehl; L. K. Fifield

doi:10.1051/epjconf/20122403002

New dating method: Groundwater residence time estimated from the ⁴He accumulation rate calibrated by using cosmogenic and subsurface-produced ³⁶Cl

Y. Mahara^*, T. Ohta, T. Kubota, K. Miyakawa, T. Hasegawa, M. A. Habermehl, L. K. Fifield

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

2 Citations (Scopus)

Abstract

Groundwater contains dissolved He, and its concentration increases with the residence time of the groundwater. Thus, if the 4He accumulation rate is constant, the dissolved ⁴He concentration in groundwater is equivalent to the residence time. Since accumulation mechanisms are not easily separated in the field, we estimate the total He accumulation rate during the half-life of ³⁶Cl (3.01 × 10⁵ years). We estimated the ⁴He accumulation rate, calibrated using both cosmogenic and subsurface-produced ³⁶Cl, in the Great Artesian Basin (GAB), Australia, and the subsurface-produced ³⁶Cl increase at the Äspö Hard Rock Laboratory, Sweden. 4He accumulation rates range from (1.9±0.3)×10^-11 to (15±6)×10^-11 ccSTP·cm^-3·y^-1 in GAB and (1.8 ± 0.7) × 10^-8 ccSTP·cm^-3·y^-1 at ̈Asp̈o. We confirmed a groundwater flow with a residence time of 0.7-1.06 Ma in GAB and stagnant groundwater with the long residence time of 4.5Ma at Äsp̈o. Therefore, the groundwater residence time can be deduced from the dissolved ⁴He concentration and the ⁴He accumulation rate calibrated by ³⁶Cl, provided that ⁴He accumulation, groundwater flow, and other geoenvironmental conditions have remained unchanged for the required amount of geological time.

Original language	English
Title of host publication	Environmental Radioactivity 2010, ER 2010
DOIs	https://doi.org/10.1051/epjconf/20122403002
Publication status	Published - 2012
Event	International Conference on Environmental Radioactivity - New Frontiers and Developments, ER 2010 - Rome, Italy Duration: 25 Oct 2010 → 27 Oct 2010

Publication series

Name	EPJ Web of Conferences
Volume	24
ISSN (Print)	2101-6275
ISSN (Electronic)	2100-014X

Conference

Conference	International Conference on Environmental Radioactivity - New Frontiers and Developments, ER 2010
Country/Territory	Italy
City	Rome
Period	25/10/10 → 27/10/10

Access to Document

10.1051/epjconf/20122403002

Cite this

Mahara, Y., Ohta, T., Kubota, T., Miyakawa, K., Hasegawa, T., Habermehl, M. A., & Fifield, L. K. (2012). New dating method: Groundwater residence time estimated from the ⁴He accumulation rate calibrated by using cosmogenic and subsurface-produced ³⁶Cl. In Environmental Radioactivity 2010, ER 2010 Article 03002 (EPJ Web of Conferences; Vol. 24). https://doi.org/10.1051/epjconf/20122403002

@inproceedings{a93944a8c7e44e9fb6e87d098a8f2807,

title = "New dating method: Groundwater residence time estimated from the 4He accumulation rate calibrated by using cosmogenic and subsurface-produced 36Cl",

abstract = "Groundwater contains dissolved He, and its concentration increases with the residence time of the groundwater. Thus, if the 4He accumulation rate is constant, the dissolved 4He concentration in groundwater is equivalent to the residence time. Since accumulation mechanisms are not easily separated in the field, we estimate the total He accumulation rate during the half-life of 36Cl (3.01 × 105 years). We estimated the 4He accumulation rate, calibrated using both cosmogenic and subsurface-produced 36Cl, in the Great Artesian Basin (GAB), Australia, and the subsurface-produced 36Cl increase at the {\"A}sp{\"o} Hard Rock Laboratory, Sweden. 4He accumulation rates range from (1.9±0.3)×10-11 to (15±6)×10-11 ccSTP·cm-3·y-1 in GAB and (1.8 ± 0.7) × 10-8 ccSTP·cm-3·y-1 at{\" }As{\"p}o. We confirmed a groundwater flow with a residence time of 0.7-1.06 Ma in GAB and stagnant groundwater with the long residence time of 4.5Ma at {\"A}s{\"p}o. Therefore, the groundwater residence time can be deduced from the dissolved 4He concentration and the 4He accumulation rate calibrated by 36Cl, provided that 4He accumulation, groundwater flow, and other geoenvironmental conditions have remained unchanged for the required amount of geological time.",

author = "Y. Mahara and T. Ohta and T. Kubota and K. Miyakawa and T. Hasegawa and Habermehl, {M. A.} and Fifield, {L. K.}",

year = "2012",

doi = "10.1051/epjconf/20122403002",

language = "English",

isbn = "9788874380695",

series = "EPJ Web of Conferences",

booktitle = "Environmental Radioactivity 2010, ER 2010",

note = "International Conference on Environmental Radioactivity - New Frontiers and Developments, ER 2010 ; Conference date: 25-10-2010 Through 27-10-2010",

}

Mahara, Y, Ohta, T, Kubota, T, Miyakawa, K, Hasegawa, T, Habermehl, MA & Fifield, LK 2012, New dating method: Groundwater residence time estimated from the ⁴He accumulation rate calibrated by using cosmogenic and subsurface-produced ³⁶Cl. in Environmental Radioactivity 2010, ER 2010., 03002, EPJ Web of Conferences, vol. 24, International Conference on Environmental Radioactivity - New Frontiers and Developments, ER 2010, Rome, Italy, 25/10/10. https://doi.org/10.1051/epjconf/20122403002

New dating method: Groundwater residence time estimated from the ⁴He accumulation rate calibrated by using cosmogenic and subsurface-produced ³⁶Cl. / Mahara, Y.; Ohta, T.; Kubota, T. et al.
Environmental Radioactivity 2010, ER 2010. 2012. 03002 (EPJ Web of Conferences; Vol. 24).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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T1 - New dating method

T2 - International Conference on Environmental Radioactivity - New Frontiers and Developments, ER 2010

AU - Mahara, Y.

AU - Ohta, T.

AU - Kubota, T.

AU - Miyakawa, K.

AU - Hasegawa, T.

AU - Habermehl, M. A.

AU - Fifield, L. K.

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N2 - Groundwater contains dissolved He, and its concentration increases with the residence time of the groundwater. Thus, if the 4He accumulation rate is constant, the dissolved 4He concentration in groundwater is equivalent to the residence time. Since accumulation mechanisms are not easily separated in the field, we estimate the total He accumulation rate during the half-life of 36Cl (3.01 × 105 years). We estimated the 4He accumulation rate, calibrated using both cosmogenic and subsurface-produced 36Cl, in the Great Artesian Basin (GAB), Australia, and the subsurface-produced 36Cl increase at the Äspö Hard Rock Laboratory, Sweden. 4He accumulation rates range from (1.9±0.3)×10-11 to (15±6)×10-11 ccSTP·cm-3·y-1 in GAB and (1.8 ± 0.7) × 10-8 ccSTP·cm-3·y-1 at ̈Asp̈o. We confirmed a groundwater flow with a residence time of 0.7-1.06 Ma in GAB and stagnant groundwater with the long residence time of 4.5Ma at Äsp̈o. Therefore, the groundwater residence time can be deduced from the dissolved 4He concentration and the 4He accumulation rate calibrated by 36Cl, provided that 4He accumulation, groundwater flow, and other geoenvironmental conditions have remained unchanged for the required amount of geological time.

AB - Groundwater contains dissolved He, and its concentration increases with the residence time of the groundwater. Thus, if the 4He accumulation rate is constant, the dissolved 4He concentration in groundwater is equivalent to the residence time. Since accumulation mechanisms are not easily separated in the field, we estimate the total He accumulation rate during the half-life of 36Cl (3.01 × 105 years). We estimated the 4He accumulation rate, calibrated using both cosmogenic and subsurface-produced 36Cl, in the Great Artesian Basin (GAB), Australia, and the subsurface-produced 36Cl increase at the Äspö Hard Rock Laboratory, Sweden. 4He accumulation rates range from (1.9±0.3)×10-11 to (15±6)×10-11 ccSTP·cm-3·y-1 in GAB and (1.8 ± 0.7) × 10-8 ccSTP·cm-3·y-1 at ̈Asp̈o. We confirmed a groundwater flow with a residence time of 0.7-1.06 Ma in GAB and stagnant groundwater with the long residence time of 4.5Ma at Äsp̈o. Therefore, the groundwater residence time can be deduced from the dissolved 4He concentration and the 4He accumulation rate calibrated by 36Cl, provided that 4He accumulation, groundwater flow, and other geoenvironmental conditions have remained unchanged for the required amount of geological time.

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U2 - 10.1051/epjconf/20122403002

DO - 10.1051/epjconf/20122403002

M3 - Conference contribution

AN - SCOPUS:84882976285

SN - 9788874380695

T3 - EPJ Web of Conferences

BT - Environmental Radioactivity 2010, ER 2010

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