Uranium-Thorium Series Geochemical Tracers

Radium

There are four naturally occurring isotopes of Ra: ²²⁶Ra (t_1/2 1600 years) present in the ²³⁸U series, ²²⁸Ra (5.75 years) and ²²⁴Ra (3.66 days) in the ²³²Th series, and ²²³Ra (11.4 days) in the ²³⁵U series. The differences in half-lives and unique parent-daughter relationships across different decay series have been utilized to study a variety of groundwater processes and water-rock interactions. For the two short-lived Ra isotopes, the principal input term to groundwater is recoil, rather than weathering processes. Steady-state activities of ²²³,²²⁴Ra are thus often achieved in groundwater. Under low-salinity conditions, Ra occurs as Ra²⁺, whereas sulfate, carbonate, and Cl- complexes will occur in saline groundwater with high respective ligand concentrations. Organic Ra complexes are generally not considered to be significant in fresh groundwater, yet colloid transport via clays and iron oxides may influence subsurface Ra transport. The solubility limit of Ra is generally not reached in fresh groundwater, but Ra can be precipitated in solid solution within Ca and Ba minerals.

Adsorption onto aquifer solids exerts a strong control on the behavior of Ra in coastal groundwater, and adsorption rate constants are dependent on substrate type and the chemical composition of the groundwater. Decreases in adsorption efficiency have been observed under conditions of increasing salinity due to such processes as cation competition and displacement, increases in mineral surface charge and increases in the stability of inorganic complexes. In a coastal aquifer, fluctuating groundwater salinities at the freshwater-saltwater interface may cause Ra to adsorb onto aquifer surfaces, thereby becoming a localized source of ²²²Rn.

Figure A. Uranium-Thorium Series decay chain for Radium. To view a larger image, click on the image above.

Figure B. A) Shown at left are two distance from shoreline (m) versus _ex ²²⁴Ra/²²³Ra activity ratios (AR) in two groundwater and five surface water samples. B) Apparent water mass ages versus distance from shore. Average observed velocity (0.06 cm s^-1) is bracketed by 0.01 cm s^-1 and 0.1 cm s^-1 lines.

Click on the images below to open a printable version of the USGS Report in Adobe Reader.

OFR 2004-1226 (808 KB PDF)

Submarine ground water discharge and its role in coastal processes and ecosystems http://sofia.usgs.gov/publications/ofr/2004-1226/

FS 2004-3117 (1.16 MB PDF)

Novel geophysical and geochemical techniques used to study submarine groundwater discharge in Biscayne Bay, Florida http://sofia.usgs.gov/publications/fs/2004-3117/

OFR 2004-1369 (1.03 MB PDF)

An autonomous, electromagnetic seepage meter to study coastal groundwater/ surface-water exchange http://sofia.usgs.gov/publications/ofr/2004-1369/

Accessibility FOIA Privacy Policies and Notices

U.S. Department of the Interior | U.S. Geological Survey
URL: http://coastal.er.usgs.gov/sgd/html/ra_quartet.html
Page Contact Information: Feedback
Page Last Modified: October 17, 2007 @ 05:07 PM (JSS)


Uranium-Thorium Series Geochemical Tracers Radium There are four naturally occurring isotopes of Ra: ²²⁶Ra (t_1/2 1600 years) present in the ²³⁸U series, ²²⁸Ra (5.75 years) and ²²⁴Ra (3.66 days) in the ²³²Th series, and ²²³Ra (11.4 days) in the ²³⁵U series. The differences in half-lives and unique parent-daughter relationships across different decay series have been utilized to study a variety of groundwater processes and water-rock interactions. For the two short-lived Ra isotopes, the principal input term to groundwater is recoil, rather than weathering processes. Steady-state activities of ²²³,²²⁴Ra are thus often achieved in groundwater. Under low-salinity conditions, Ra occurs as Ra²⁺, whereas sulfate, carbonate, and Cl- complexes will occur in saline groundwater with high respective ligand concentrations. Organic Ra complexes are generally not considered to be significant in fresh groundwater, yet colloid transport via clays and iron oxides may influence subsurface Ra transport. The solubility limit of Ra is generally not reached in fresh groundwater, but Ra can be precipitated in solid solution within Ca and Ba minerals. Adsorption onto aquifer solids exerts a strong control on the behavior of Ra in coastal groundwater, and adsorption rate constants are dependent on substrate type and the chemical composition of the groundwater. Decreases in adsorption efficiency have been observed under conditions of increasing salinity due to such processes as cation competition and displacement, increases in mineral surface charge and increases in the stability of inorganic complexes. In a coastal aquifer, fluctuating groundwater salinities at the freshwater-saltwater interface may cause Ra to adsorb onto aquifer surfaces, thereby becoming a localized source of ²²²Rn.

		Figure A. Uranium-Thorium Series decay chain for Radium. To view a larger image, click on the image above.
To view additional information about Uranium/Thorium series geochemical tracers, please click on the link below to view a HTML accessible version: Examining Freshwater-Saltwater Interface Processes with Four Radium Isotopes

	Figure B. A) Shown at left are two distance from shoreline (m) versus _ex ²²⁴Ra/²²³Ra activity ratios (AR) in two groundwater and five surface water samples. B) Apparent water mass ages versus distance from shore. Average observed velocity (0.06 cm s^-1) is bracketed by 0.01 cm s^-1 and 0.1 cm s^-1 lines.


Print Publications: Reports Click on the images below to open a printable version of the USGS Report in Adobe Reader. NOTE: PDF files may be viewed using Adobe Reader public domain software. If unable to access the PDF files, please contact aharrison@usgs.gov.


OFR 2004-1226 (808 KB PDF) Submarine ground water discharge and its role in coastal processes and ecosystems http://sofia.usgs.gov/publications/ofr/2004-1226/		FS 2004-3117 (1.16 MB PDF) Novel geophysical and geochemical techniques used to study submarine groundwater discharge in Biscayne Bay, Florida http://sofia.usgs.gov/publications/fs/2004-3117/
	OFR 2004-1369 (1.03 MB PDF) An autonomous, electromagnetic seepage meter to study coastal groundwater/ surface-water exchange http://sofia.usgs.gov/publications/ofr/2004-1369/

Uranium-Thorium Series Geochemical Tracers

Radium

Print Publications: Reports