Geologic and hydrologic processes bring salts to Earth's surface over time, but human activities such as mining and land development are rapidly accelerating the natural "salt cycle." Agriculture, construction, water and road treatment, and other industrial activities can also intensify salinization, which harms biodiversity and makes drinking water unsafe in extreme cases.
"If you think of the planet as a living organism, when you accumulate so much salt it could affect the functioning of vital organs or ecosystems," said Kaushal, who holds a joint appointment in UMD's Earth System Science Interdisciplinary Center. "Removing salt from water is energy intensive and expensive, and the brine byproduct you end up with is saltier than ocean water and can't be easily disposed of."
Kaushal and his co-authors described these disturbances as an "anthropogenic salt cycle," establishing for the first time that humans affect the concentration and cycling of salt on a global, interconnected scale.
"Twenty years ago, all we had were case studies. We could say surface waters were salty here in New York or in Baltimore's drinking water supply," said study co-author Gene Likens, an ecologist at the University of Connecticut and the Cary Institute of Ecosystem Studies. "We now show that it's a cycle-from the deep Earth to the atmosphere-that's been significantly perturbed by human activities."
The new study considered a variety of salt ions that are found underground and in surface water. Salts are compounds with positively charged cations and negatively charged anions, with some of the most abundant ones being calcium, magnesium, potassium and sulfate ions.
"When people think of salt, they tend to think of sodium chloride, but our work over the years has shown that we've disturbed other types of salts, including ones related to limestone, gypsum and calcium sulfate," Kaushal said.
When dislodged in higher doses, these ions can cause environmental problems. Kaushal and his co-authors showed that human-caused salinization affected approximately 2.5 billion acres of soil around the world-an area about the size of the United States. Salt ions also increased in streams and rivers over the last 50 years, coinciding with an increase in the global use and production of salts.
Salt has even infiltrated the air. In some regions, lakes are drying up and sending plumes of saline dust into the atmosphere. In areas that experience snow, road salts can become aerosolized, creating sodium and chloride particulate matter.
Salinization is also associated with "cascading" effects. For example, saline dust can accelerate the melting of snow and harm communities-particularly in the western United States-that rely on snow for their water supply. Because of their structure, salt ions can bind to contaminants in soils and sediments, forming "chemical cocktails" that circulate in the environment and have detrimental effects.
"Salt has a small ionic radius and can wedge itself between soil particles very easily," Kaushal said. "In fact, that's how road salts prevent ice crystals from forming."
Road salts have an outsized impact in the U.S., which churns out 44 billion pounds of the deicing agent each year. Road salts represented 44% of U.S. salt consumption between 2013 and 2017, and they account for 13.9% of the total dissolved solids that enter streams across the country. This can cause a "substantial" concentration of salt in watersheds, according to Kaushal and his co-authors.
To prevent U.S. waterways from being inundated with salt in the coming years, Kaushal recommended policies that limit road salts or encourage alternatives. Washington, D.C., and several other U.S. cities have started treating frigid roads with beet juice, which has the same effect but contains significantly less salt.
Kaushal said it is becoming increasingly important to weigh the short- and long-term risks of road salts, which play an important role in public safety but can also diminish water quality.
"There's the short-term risk of injury, which is serious and something we certainly need to think about, but there's also the long-term risk of health issues associated with too much salt in our water," Kaushal said. "It's about finding the right balance."
The study's authors also called for the creation of a "planetary boundary for safe and sustainable salt use" in much the same way that carbon dioxide levels are associated with a planetary boundary to limit climate change. Kaushal said that while it's theoretically possible to regulate and control salt levels, it comes with unique challenges.
"This is a very complex issue because salt is not considered a primary drinking water contaminant in the U.S., so to regulate it would be a big undertaking," Kaushal said. "But do I think it's a substance that is increasing in the environment to harmful levels? Yes."
Research Report:The anthropogenic salt cycle
Relevance Scores:
1. Environment Industry Analyst: 9/10
2. Stock and Finance Market Analyst: 5/10
3. Government Policy Analyst: 8/10
Comprehensive Analyst Summary
Main Points:
The study led by University of Maryland Geology Professor Sujay Kaushal states that human activities are accelerating Earth's natural "salt cycle," making air, soil, and freshwater saltier. This salinization poses significant risks to biodiversity, water quality, and even human health. The report calls for policy measures to regulate salt usage, especially in industries like mining, agriculture, and road treatment.
Implications:
- Environment Industry Analyst: This article has substantial relevance. Salinization affects a wide range of environmental services, from water treatment to agriculture. Companies specializing in environmental remediation, desalination, and alternative salt products would be directly impacted. The highlighted existential threat raises the stakes for developing sustainable solutions.
- Stock and Finance Market Analyst: Firms in the environmental sector might experience increased investment as they innovate to solve salinization issues. Traditional industries contributing to the problem, such as mining, may face regulatory risks that can affect stock prices.
- Government Policy Analyst: The study presents an urgent call to action for policy measures. Governments may need to invest in R and D for desalination and remediation techniques and also consider regulations on industries contributing to the problem.
Comparison with Historical Trends:
Over the last 25 years, environmental consciousness has significantly grown, with increased focus on climate change, pollution, and resource depletion. However, the salt issue, despite being less publicized, follows a similar trajectory-human activity causing unanticipated global impacts. It parallels the narrative of other pollutants like CO2 and plastics, which have also seen regulation and industry response.
Investigative Questions:
1. What specific industries are the major contributors to the acceleration of the natural salt cycle?
2. How effective are existing desalination technologies in combating the issue of salinization?
3. What are the economic costs associated with mitigating the impacts of salinization on a large scale?
4. What are the public health impacts of increased salt levels in drinking water?
5. Are there any successful case studies where policies have effectively controlled or reversed the effects of salinization?
By addressing these questions, analysts can gain a more nuanced understanding of the problem and identify areas for targeted intervention.
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