Relation between Road-Salt Application and Increasing Radium Concentrations in a Low-pH Aquifer, Southern New Jersey

Lindsey, Bruce D.; Cravotta, Charles A.; Szabó, Zoltán; Belitz, Kenneth; Stackelberg, Paul E.

doi:10.1021/acsestwater.1c00307

Cited by 11 publications

(12 citation statements)

References 39 publications

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“…However, as chloride is chemically conservative, continued deicer impact will increase salinity in the aquifer, as has been observed in some local water supply systems (Andres & McQuiggan 2019). Further, as several studies have noted the association between increased salinity and elevated Ra in groundwater in the region (Lindsey et al., 2021; Bolton, 2000; Andres & McQuiggan, 2019), we suspect that there will be increased incidence of Ra contamination of water supply wells. This may become a significant concern where new development constructs infiltration basins in and around agricultural areas, as phosphate‐based fertilizer may be a source material for Ra mobilization to groundwater (Szabo et al., 1997).…”

Section: Discussionmentioning

confidence: 83%

“…Given there is poor correlation between Ra and geologic unit at the site, there likely are Ra sources in both units. These correlations most likely reflect Ra desorption by competitive ion exchange with Na, and chloride complex formation (Lindsey et al., 2021). These processes would preferentially mobilize 228 Ra where it is enriched by alpha‐recoil in the adsorbed and mobile pool of Ra in shallow aquifers (Krishnaswami et al., 1982; Luo et al., 2000).…”

Section: Discussionmentioning

confidence: 99%

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Stormwater drives seasonal geochemical processes beneath an infiltration basin

et al. 2022

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Deicing salt is an important component of road safety during winter storms.Stormwater infiltration best management practices aim to prevent the salt from polluting streams and waterways, but this may shift pollutants to groundwater resources. In response to limited field studies investigating groundwater quality impacts caused by input of salt from stormwater infiltration best management practices, we monitored water levels and quality of groundwater at various depths in an unconfined aquifer around a stormwater infiltration basin using in situ sensors coupled with grab sampling. Our observations revealed differences in groundwater chemistry with depth in the aquifer and processes that were driven by the seasonal changes in the chemistry of stormwater (salt-impacted in winter and fresh in non-winter) recharging the aquifer. Water-matrix interactions in the vadose zone beneath the basin affected the transport of sodium (Na) into groundwater following non-winter recharge. Sodium movement through the aquifer was delayed relative to chloride (Cl), indicating a longer residence time of Na in the vadose zone. Radium (Ra) concentrations were correlated with Cl concentrations, suggesting salt-impacted recharge caused desorption of Ra into groundwater because of increased salinity. Stormwater-influenced groundwater followed a preferential flow path due to heterogeneity of the aquifer materials, and water chemistry varied with time and location along the flow path. These results highlight the importance of well screen length, placement and depth, and frequency of observations when designing a monitoring network.

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Section: Discussionmentioning

confidence: 83%

Section: Discussionmentioning

confidence: 99%

Stormwater drives seasonal geochemical processes beneath an infiltration basin

et al. 2022

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“…The long-term freshening effects remain the primary characteristic controlling the geochemistry of the Atlantic and Gulf coastal aquifers of the United States, although with rising sea levels as an effect of climate change, it is possible that an increasing percentage of coastal aquifers may be affected by saltwater intrusion in the near future . Increasing salinity may facilitate mobilization of 226 Ra in affected zones through reverse cation exchange combined with formation of aqueous Ra–Cl complexes . More sample collection and geochemical modeling of analytical results are needed to better define 226 Ra and 210 Po occurrence patterns in these vulnerable aquifer areas.…”

Section: Resultsmentioning

confidence: 99%

“…The forward models start with evaporated rainwater reacted with the smallest amount of minerals (Table SI.8) to produce dilute groundwater that is simulated to have a high concentration of 226 Ra (on the order of 1 pCi/L), derived from surficial aquifer sources, because of inefficient adsorption of Ra at low pH as detailed elsewhere. − Model 1 (black curves) reacts the dilute groundwater with a high concentration of NaCl to simulate the influence of road-deicing salt leachate (Figures , SI.2, and SI.3F). The Na:Cl of about 1.0 for slightly acidic or near-neutral samples (Figure A) indicates mixing of dilute rainwater with saltwater aerosols, road salt, and wastewater. − Models 2, 3, and 4 (red, blue, and green curves, respectively) react the “dilute” groundwater with approximately 10-fold of additional minerals. Model 2 (red curves), without cation exchange, generally explains the compositions of samples having high 226 Ra in “hard” water with considerable Ca and near-neutral pH (samples B–D; 226 Ra 0.97–1.08 pCi/L; Figures , SI.3A–D,G, SI.4, and Table SI.4B; PC2 in Table SI.6).…”

Section: Resultsmentioning

confidence: 99%

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Gross Alpha-Particle Activity and High ²²⁶Ra Concentrations Do Not Correspond with High ²¹⁰Po in the Atlantic and Gulf Coastal Plain Aquifers of the United States

et al. 2023

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210 Po, which is of human-health concern based on lifetime ingestion cancer risk, is indirectly regulated in drinking water through the U.S. Environmental Protection Agency's gross alphaparticle activity (GAPA) maximum contaminant level of 15 pCi/L (picocuries per liter). This regulation requires independent measurement of 226 Ra for samples exceeding the GAPA screening level of 5 pCi/L. There is no such requirement for 210 Po. Co-occurrence of 226 Ra and 210 Po, alpha-emitting 238 U-decay-series progeny, might be helpful in locating high-210 Po waters but is unverified. Relations among 210 Po, 226 Ra, and GAPA evaluated for samples from 257 public-supply wells from Coastal Plain aquifers showed that concentrations of 226 Ra correlated with GAPA but neither correlated with 210 Po concentrations. The highest concentrations of 226 Ra and 210 Po were found under differing geochemical conditions. The highest 226 Ra occurred in low-pH oxidizing waters and in neutral-pH reducing waters, where geochemical conditions render Fe−Mnhydroxide sorbents inefficient. 210 Po was highest (10.1 pCi/L) in reducing waters with high pH (>7.5, which results from progressive cation exchange), where 226 Ra was lowest�exchanged to clay minerals. Because 226 Ra and 210 Po did not co-occur, the GAPA screening might not be protective for 210 Po. Independent 210 Po analysis is prudent, especially where groundwater is reducing with high pH and low 226 Ra concentrations.

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Prioritizing US Geological Survey science on salinization and salinity in candidate and selected priority river basins

Conaway,

Baker,

Brown

et al. 2024

Environ Monit Assess

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The US Geological Survey (USGS) is selecting and prioritizing basins, known as Integrated Water Science basins, for monitoring and intensive study. Previous efforts to aid in this selection process include a scientifically defensible and quantitative assessment of basins facing human-caused water resource challenges (Van Metre et al. in Environmental Monitoring and Assessment, 192(7), 458 2020). In the present work, we explore this ranking process based on water quality considerations, specifically salinity and salinization. We selected top candidate basins to study salinity and salinization issues in 18 hydrologic regions that include 163 candidate basins. Our prioritization is based on quantitative assessment of sources of salinity, drivers of change, and receptors that must respond to those sources and drivers. Source terms represented in the prioritization include geology, depth to brackish groundwater, stream conductivity, chloride in precipitation, urban and agricultural land use, application of road salt as a deicer, and irrigation. Drivers represented in prioritization include changes in chemical weathering as a result of changes in rainwater chemistry. Receptors include measures of water stress, measurements of stream ecological health, and socioeconomic factors. In addition, we present research activities for the USGS on salinity and salinization that can be pursued in these basins including assessment of sources, pathways, and loadings; predicting and understanding changes in sources, peaks, and trends; understanding the components of salinity and mobilization of contaminants; understanding the relationship between salinization and changing ecosystems; and developing knowledge on the causes and distribution of groundwater salinity, brackish water resources, and challenges related to desalination.

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Relation between Road-Salt Application and Increasing Radium Concentrations in a Low-pH Aquifer, Southern New Jersey

Cited by 11 publications

References 39 publications

Stormwater drives seasonal geochemical processes beneath an infiltration basin

Stormwater drives seasonal geochemical processes beneath an infiltration basin

Gross Alpha-Particle Activity and High ²²⁶Ra Concentrations Do Not Correspond with High ²¹⁰Po in the Atlantic and Gulf Coastal Plain Aquifers of the United States

Prioritizing US Geological Survey science on salinization and salinity in candidate and selected priority river basins

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Relation between Road-Salt Application and Increasing Radium Concentrations in a Low-pH Aquifer, Southern New Jersey

Cited by 11 publications

References 39 publications

Stormwater drives seasonal geochemical processes beneath an infiltration basin

Stormwater drives seasonal geochemical processes beneath an infiltration basin

Gross Alpha-Particle Activity and High 226Ra Concentrations Do Not Correspond with High 210Po in the Atlantic and Gulf Coastal Plain Aquifers of the United States

Prioritizing US Geological Survey science on salinization and salinity in candidate and selected priority river basins

Contact Info

Product

Resources

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Gross Alpha-Particle Activity and High ²²⁶Ra Concentrations Do Not Correspond with High ²¹⁰Po in the Atlantic and Gulf Coastal Plain Aquifers of the United States