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Arsenic contamination of groundwater

February 15, 2024

Arsenic contamination of groundwater is a form of groundwater pollution which is often due to naturally occurring high concentrations of arsenic in deeper levels of groundwater. It is a high-profile problem due to the use of deep tube wells for water supply in the Ganges Delta, causing serious arsenic poisoning to large numbers of people. A 2007 study found that over 137 million people in more than 70 countries are probably affected by arsenic poisoning of drinking water. The problem became a serious health concern after mass poisoning of water in Bangladesh.[1] Arsenic contamination of ground water is found in many countries throughout the world, including the US.[2]

Groundwater arsenic contamination areas

The World Health Organization recommends limiting arsenic concentrations in water to 10 μg/L, although this is often an unattainable goal for many problem areas due to the difficult nature of removing arsenic from water sources.[3]

Approximately 20 major incidents of groundwater arsenic contamination have been reported.[4] Of these, four major incidents occurred in Asia—in Bangladesh; West Bengal, India; Inner Mongolia, China; and Taiwan.[5] Locations of potentially hazardous wells have been mapped in China.[6]

Sources edit

Gold mining can contaminate groundwater with arsenic, because the element typically occurs in gold-containing ores. Gold processing releases arsenic from mine tailings, and contaminated groundwater may be unsafe to drink for decades.[7] Arsenic that is naturally occurring can contaminate the soil, just as it does the groundwater. This presents a possible arsenic exposure by use of products containing tobacco, because the tobacco plant grows from the soil and can become infiltrated with the arsenic.[3]

Speciation of arsenic compounds in water edit

Arsenic contaminated water typically contains arsenous acid and arsenic acid or their derivatives. Their names as "acids" is a formality; these species are not aggressive acids but are merely the soluble forms of arsenic near neutral pH. These compounds are extracted from the underlying rocks that surround the aquifer. Arsenic acid tends to exist as the ions [HAsO4]2− and [H2AsO4] in neutral water, whereas arsenous acid is not ionized.

 
 
Arsenic acid (H3AsO4), arsenous acid (H3AsO3) and their derivatives are typically encountered in arsenic contaminated ground water.

Contamination in specific nations and regions edit

 
This person displays some of the symptoms of arsenic poisoning through contaminated water.

South America edit

An analysis of water and food consumption in Socaire, a rural village in Chile, found that between November 2008 and September 2009, the total intake of arsenic by the villagers correlated with the amount of water and local produce consumed.[8]

The central portion of Argentina is affected by arsenic-contaminated groundwater. Specifically, the La Pampa produces water containing 4–5300 microgram per liter.[9]

South Asia edit

Bangladesh edit

This section is an excerpt from Water supply and sanitation in Bangladesh § Arsenic contamination of groundwater.[edit]

Arsenic contamination of the groundwater in Bangladesh is a serious problem. Prior to the 1970s, Bangladesh had one of the highest infant mortality rates in the world. Ineffective water purification and sewage systems as well as periodic monsoons and flooding exacerbated these problems. As a solution, UNICEF and the World Bank advocated the use of wells to tap into deeper groundwater. During the 1970s, UNICEF worked with the Department of Public Health Engineering to install tube-wells. The wells consist of tubes 5 cm in diameter inserted less than 200 m into the ground and capped with an iron or steel hand pump. At that time, standard water testing procedures did not include arsenic testing.[10] This lack of precaution led to one of the largest mass poisoning of a population because the ground water used for drinking was contaminated with arsenic.[11]

Tube-wells were supposed to draw water from underground aquifers to provide a safe source of water for the nation. Millions of wells were constructed as a result. In 1993 it was discovered that groundwater in large parts of Bangladesh was naturally contaminated with arsenic.[12][13]: 389  The issue came to international attention in 1995.[14][15]

In the Ganges Delta, the affected wells are typically more than 20 meters and less than 100 meters deep.[16] Groundwater closer to the surface typically has spent a shorter time in the ground, therefore likely absorbing a lower concentration of arsenic; water deeper than 100 meters is exposed to much older sediments which have already been depleted of arsenic.[17]

Criticism has been leveled at the aid agencies, who denied the problem during the 1990s while millions of tube wells were sunk. The aid agencies later hired foreign experts who recommended treatment plants that were inappropriate to the conditions, were regularly breaking down, or were not removing the arsenic.[18]

India edit

In Bihar, groundwater in 13 districts have been found to be contaminated with arsenic with quantities exceeding 0.05 mg/L. All these districts are situated close to large rivers like Ganga and Gandak.[19]

In West Bengal, India, water is mostly supplied from rivers, open wells, or ponds. These may be contaminated with communicable diseases such as dysentery, typhoid, cholera, and hepatitis. Since the 1970s, non-governmental organisations in India have focused on sinking tube wells to provide drinking water uncontaminated by diseases, with the unforeseen side effect of exposing some people to arsenic-contaminated groundwater.[20][21]

Nepal edit

Nepal is subject to a serious problem with arsenic contamination. The problem is most severe in the Terai region, the worst being near Nawalparasi District, where 26 percent of shallow wells failed to meet WHO standard of 10 ppb. A study by Japan International Cooperation Agency and the Environment in the Kathmandu Valley showed that 72% of deep wells failed to meet the WHO standard, and 12% failed to meet the Nepali standard of 50 ppb.[22]

Pakistan edit

66% of 1200 samples tested contained arsenic above WHO recommended limit, threatening over 60 million residents. 50–60 million residents consume water with arsenic levels greater than 50 micrograms of arsenic per liter, levels far passing acceptable levels worldwide.[23]

United States edit

Regulation edit

A drinking water standard of 0.05 mg/L (equal to 50 parts per billion, or ppb) arsenic was originally established in the United States by the Public Health Service in 1942. After the passage of the Safe Drinking Water Act of 1974 (SDWA), the Environmental Protection Agency (EPA) was given the power to set the maximum containment levels (MCLs) of contaminants in public water supplies. In 1996 Congress amended the SDWA and created a Drinking Water State Revolving Fund to provide loans for water supply improvements, which increased the EPA's power to set mandates. This amendment created the "costs and benefits rule" to determine whether the cost of implementing new MCLs outweighs the health benefits. To maximize the costs and benefits of setting new MLCs, the EPA began allowing more affordable technology to be substituted that did not fully meet MLC standards because it was more affordable.

The EPA studied the pros and cons of lowering the arsenic MCL for years in the late 1980s and 1990s. No action was taken until January 2001, when the Clinton administration in its final weeks promulgated a new standard of 0.01 mg/L (10 ppb) to take effect January 2006.[24] The Bush administration suspended the midnight regulation, but after some months of study, the new EPA administrator Christine Todd Whitman approved the new 10 ppb arsenic standard and its original effective date of January 2006.[25] Many locations exceed this limit.[26] A 2017 Lancet Public Health study found that this rule change led to fewer cancer deaths.[27][28]

Many public water supply systems across the United States obtained their water supply from groundwater that had met the old 50 ppb arsenic standard but exceeded the new 10 ppb MCL. These utilities searched for either an alternative supply or an inexpensive treatment method to remove the arsenic from their water. In Arizona, an estimated 35 percent of water-supply wells were put out of compliance by the new regulation; in California, the percentage was 38 percent.[29]

The proper arsenic MCL continues to be debated. Some have argued that the 10 ppb federal standard is still too high, while others have argued that 10 ppb is needlessly strict. Individual states can establish lower arsenic limits; New Jersey has done so, setting a maximum of 0.005 mg/L (5 ppb) for arsenic in drinking water.[30]

A study of private water wells in the Appalachian mountains found that six percent of the wells had arsenic above the U.S. MCL of 0.010 mg/L.[31]

Case studies and incidents edit

Fallon, Nevada has long been known to have groundwater with relatively high arsenic concentrations (in excess of 0.08 mg/L).[32] Even some surface waters, such as the Verde River in Arizona, sometimes exceed 0.01 mg/L arsenic, especially during low-flow periods when the river flow is dominated by groundwater discharge.[33]

A study conducted in a contiguous six-county area of southeastern Michigan investigated the relationship between moderate arsenic levels and 23 disease outcomes. Disease outcomes included several types of cancer, diseases of the circulatory and respiratory system, diabetes mellitus, and kidney and liver diseases. Elevated mortality rates were observed for all diseases of the circulatory system. The researchers acknowledged a need to replicate their findings.[34]

Various studies have also shown that arsenic exposure during pregnancy can result in infant death, cancer, heart attacks, kidney failure, lung complications, as well as reduced intelligence, memory, and cognitive development in the child. [3]

Water purification solutions edit

Access to clean drinking water is fraught with political, socio-economic, and cultural inequities. In practice, many water treatment strategies tend to be temporary fixes to a larger problem, often prolonging the social issues while treating the scientific ones.[35] Scientific studies have shown that interdisciplinary approaches to water purification are especially important to consider, and long-lasting improvements involve larger perspectives than strict scientific approaches.[36]

Small-scale water treatment edit

A review of methods to remove arsenic from groundwater in Pakistan summarizes the most technically viable inexpensive methods.[37] Most small-scale treatments focus on water after it has left the distribution site, and are thus more focused on quick, temporary fixes.

A simpler and less expensive form of arsenic removal is known as the Sono arsenic filter, using three pitchers containing cast iron turnings and sand in the first pitcher and wood activated carbon and sand in the second.[38] Plastic buckets can also be used as filter containers.[39] It is claimed that thousands of these systems are in use and can last for years while avoiding the toxic waste disposal problem inherent to conventional arsenic removal plants. Although novel, this filter has not been certified by any sanitary standards such as NSF, ANSI, WQA and does not avoid toxic waste disposal similar to any other iron removal process.

In the United States small "under the sink" units have been used to remove arsenic from drinking water. This option is called "point of use" treatment. The most common types of domestic treatment use the technologies of adsorption (using media such as Bayoxide E33, GFH, activated alumina or titanium dioxide)[40] or reverse osmosis. Ion exchange and activated alumina have been considered but not commonly used.

Chaff-based filters have been reported to reduce the arsenic content of water to 3 μg/L (3 ppb). This is especially important in areas where the potable water is provided by filtering the water extracted from the underground aquifer.[41]

In iron electrocoagulation (Fe-EC), iron is dissolved nonstop using electricity, and the resulting ferric hydroxides, oxyhydroxides, and oxides form an absorbent readily attracted to arsenic. Current density, the amount of charge delivered per liter of water, of the process is often manipulated in order to achieve maximum arsenic depletion.[42] This treatment strategy has primarily been used in Bangladesh,[43] and has proven to be largely successful. In fact, using iron electrocoagulation to remove arsenic in water proved to be the most effective treatment option.[44]

Large-scale water treatment edit

In some places, such as the United States, all the water supplied to residences by utilities must meet primary (health-based) drinking water standards. Regulations may require large-scale treatment systems to remove arsenic from the water supply. The effectiveness of any method depends on the chemical makeup of a particular water supply. The aqueous chemistry of arsenic is complex, and may affect the removal rate that can be achieved by a particular process.

Some large utilities with multiple water supply wells could shut down those wells with high arsenic concentrations, and produce only from wells or surface water sources that meet the arsenic standard. Other utilities, however, especially small utilities with only a few wells, may have no available water supply that meets the arsenic standard.

Coagulation/filtration (also known as flocculation) removes arsenic by coprecipitation and adsorption using iron coagulants. Coagulation/filtration using alum is already used by some utilities to remove suspended solids and may be adjusted to remove arsenic.[45]

Iron oxide adsorption filters the water through a granular medium containing ferric oxide. Ferric oxide has a high affinity for adsorbing dissolved metals such as arsenic. The iron oxide medium eventually becomes saturated, and must be replaced. The sludge disposal is a problem here too.

Activated alumina is an adsorbent that effectively removes arsenic. Activated alumina columns connected to shallow tube wells in India and Bangladesh have removed both As(III) and As(V) from groundwater for decades. Long-term column performance has been possible through the efforts of community-elected water committees that collect a local water tax for funding operations and maintenance.[46] It has also been used to remove undesirably high concentrations of fluoride.

Ion exchange has long been used as a water softening process, although usually on a single-home basis. Traditional anion exchange resins are effective in removing As(V), but not As(III), or arsenic trioxide, which doesn't have a net charge. Effective long-term ion exchange removal of arsenic requires a trained operator to maintain the column.

Both reverse osmosis and electrodialysis (also called electrodialysis reversal) can remove arsenic with a net ionic charge. (Note that arsenic oxide, As2O3, is a common form of arsenic in groundwater that is soluble, but has no net charge.) Some utilities presently use one of these methods to reduce total dissolved solids and therefore improve taste. A problem with both methods is the production of high-salinity waste water, called brine, or concentrate, which then must be disposed of.

Subterranean arsenic removal (SAR) technology SAR Technology

In subterranean arsenic removal, aerated groundwater is recharged back into the aquifer to create an oxidation zone which can trap iron and arsenic on the soil particles through adsorption process. The oxidation zone created by aerated water boosts the activity of the arsenic-oxidizing microorganisms which can oxidize arsenic from +3 to +5 state SAR Technology. No chemicals are used and almost no sludge is produced during operational stage since iron and arsenic compounds are rendered inactive in the aquifer itself. Thus toxic waste disposal and the risk of its future mobilization is prevented. Also, it has very long operational life, similar to the long lasting tube wells drawing water from the shallow aquifers.

Six such SAR plants, funded by the World Bank and constructed by Ramakrishna Vivekananda Mission, Barrackpore & Queen's University Belfast, UK are operating in West Bengal. Each plant has been delivering more than 3,000 liters of arsenic and iron-free water daily to the rural community. The first community water treatment plant based on SAR technology was set up at Kashimpore near Kolkata in 2004 by a team of European and Indian engineers led by Bhaskar Sen Gupta of Queen's University Belfast for TiPOT.[47][48][49][50]

SAR technology had been awarded Dhirubhai Ambani Award, 2010 from IChemE UK for Chemical Innovation. Again, SAR was the winner of the St. Andrews Award for Environment, 2010. The SAR Project was selected by the Blacksmith Institute – New York & Green Cross- Switzerland as one of the "12 Cases of Cleanup & Success" in the World's Worst Polluted Places Report 2009. (Refer: www.worstpolluted.org).

Currently, large scale SAR plants are being installed in US, Malaysia, Cambodia, and Vietnam.

Nanotechnology based arsenic remediation edit

Using nanomaterials, it is possible to effectively destroy microorganisms, adsorb arsenic and fluoride, remove heavy metals and degrade pesticides usually found in water.[51][52] Researchers have looked at new methods to synthesize iron oxide/hydroxide/oxyhydroxide compositions in the laboratory and used them for water purification. A product called AMRIT, meaning elixir in Indian languages, developed by the Indian Institute of Technology Madras, is an affordable water purification technology based on advanced materials, which has been validated through research articles[53][54] and patents[55] and has been approved for national implementation in India. The technology can remove several anions, especially arsenate and arsenite (two common species present in arsenic-contaminated water) and fluoride from water. Currently, this technology is delivering arsenic-free water to about 10,00,000 people every day.[56]

Research edit

Mapping edit

In 2008, the Swiss Aquatic Research Institute, Eawag, presented a new method by which hazard maps could be produced for geogenic toxic substances in groundwater.[57][58][59][60] This provides an efficient way of determining which wells should be tested. In 2016, the research group made its knowledge freely available on the Groundwater Assessment Platform (GAP). This offers specialists worldwide the possibility of uploading their own measurement data, visually displaying them and producing risk maps for areas of their choice. GAP also serves as a knowledge-sharing forum for enabling further development of methods for removing toxic substances from water.

Dietary intake edit

Researchers from Bangladesh and the United Kingdom have claimed that dietary intake of arsenic adds a significant amount to total intake where contaminated water is used for irrigation.[61][62][63]

See also edit

References edit

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  58. ^ Amini, M.; Abbaspour, K.C.; Berg, M.; Winkel, L.; Hug, S.J.; Hoehn, E.; Yang, H.; Johnson, C.A. (2008). "Statistical modeling of global geogenic arsenic contamination in groundwater". Environmental Science and Technology 42 (10), 3669–75. doi:10.1021/es702859e
  59. ^ Winkel, L.; Berg, M.; Amini, M.; Hug, S.J.; Johnson, C.A. Predicting groundwater arsenic contamination in Southeast Asia from surface parameters. Nature Geoscience, 1, 536–42 (2008). doi:10.1038/ngeo254
  60. ^ Rodríguez-Lado, L.; Sun, G.; Berg, M.; Zhang, Q.; Xue, H.; Zheng, Q.; Johnson, C.A. (2013) Groundwater arsenic contamination throughout China. Science, 341(6148), 866–68, doi:10.1126/science.1237484
  61. ^ Mustak Hossain (2006-07-13). "Toxic rice harvested in southwestern Bangladesh". SciDev.Net.
  62. ^ Williams, P.N.; Islam, M. R.; Adomako, E. E.; Raab, A.; Hossain, S. A.; Zhu, Y. G.; Feldmann, J.; Meharg, A. A. (2006). "Increase in Rice Grain Arsenic for Regions of Bangladesh Irrigating Paddies with Elevated Arsenic in Groundwaters". Environ. Sci. Technol. 40 (16): 4903–4908. Bibcode:2006EnST...40.4903W. doi:10.1021/es060222i. PMID 16955884.
  63. ^ *Raghvan T. "Screening of Rice Cultivars for Grain Arsenic Concentration and Speciation". American Society of Agronomy Proceeding.

External links edit

  • ATSDR - Case Studies in Environmental Medicine: Arsenic Toxicity
  • IGRAC International Groundwater Resources Assessment Centre
  • Arsenic in Groundwater: A World Problem – IAH publication, Netherlands National Chapter, 2008
  • SOS-Arsenic.net – information and awareness raising site, focused on Bangladesh.
  • Contamination of drinking-water by arsenic in Bangladesh: a public health emergency – at SOS-Arsenic.net
  • Subterranean Arsenic Treatment Technology in West Bengal
  • 12 Cases of Cleanup & Success
  • – Arsenic Scenario of West Bengal
  • , ACDIS Occasional Paper by Mustafa Moinuddin

February 15, 2024
arsenic, contamination, groundwater, form, groundwater, pollution, which, often, naturally, occurring, high, concentrations, arsenic, deeper, levels, groundwater, high, profile, problem, deep, tube, wells, water, supply, ganges, delta, causing, serious, arseni. Arsenic contamination of groundwater is a form of groundwater pollution which is often due to naturally occurring high concentrations of arsenic in deeper levels of groundwater It is a high profile problem due to the use of deep tube wells for water supply in the Ganges Delta causing serious arsenic poisoning to large numbers of people A 2007 study found that over 137 million people in more than 70 countries are probably affected by arsenic poisoning of drinking water The problem became a serious health concern after mass poisoning of water in Bangladesh 1 Arsenic contamination of ground water is found in many countries throughout the world including the US 2 Groundwater arsenic contamination areasThe World Health Organization recommends limiting arsenic concentrations in water to 10 mg L although this is often an unattainable goal for many problem areas due to the difficult nature of removing arsenic from water sources 3 Approximately 20 major incidents of groundwater arsenic contamination have been reported 4 Of these four major incidents occurred in Asia in Bangladesh West Bengal India Inner Mongolia China and Taiwan 5 Locations of potentially hazardous wells have been mapped in China 6 Contents 1 Sources 2 Speciation of arsenic compounds in water 3 Contamination in specific nations and regions 3 1 South America 3 2 South Asia 3 2 1 Bangladesh 3 2 2 India 3 2 3 Nepal 3 2 4 Pakistan 3 3 United States 3 3 1 Regulation 3 3 2 Case studies and incidents 4 Water purification solutions 4 1 Small scale water treatment 4 2 Large scale water treatment 4 3 Nanotechnology based arsenic remediation 5 Research 5 1 Mapping 5 2 Dietary intake 6 See also 7 References 8 External linksSources editGold mining can contaminate groundwater with arsenic because the element typically occurs in gold containing ores Gold processing releases arsenic from mine tailings and contaminated groundwater may be unsafe to drink for decades 7 Arsenic that is naturally occurring can contaminate the soil just as it does the groundwater This presents a possible arsenic exposure by use of products containing tobacco because the tobacco plant grows from the soil and can become infiltrated with the arsenic 3 Speciation of arsenic compounds in water editArsenic contaminated water typically contains arsenous acid and arsenic acid or their derivatives Their names as acids is a formality these species are not aggressive acids but are merely the soluble forms of arsenic near neutral pH These compounds are extracted from the underlying rocks that surround the aquifer Arsenic acid tends to exist as the ions HAsO4 2 and H2AsO4 in neutral water whereas arsenous acid is not ionized nbsp nbsp Arsenic acid H3AsO4 arsenous acid H3AsO3 and their derivatives are typically encountered in arsenic contaminated ground water Contamination in specific nations and regions edit nbsp This person displays some of the symptoms of arsenic poisoning through contaminated water South America edit An analysis of water and food consumption in Socaire a rural village in Chile found that between November 2008 and September 2009 the total intake of arsenic by the villagers correlated with the amount of water and local produce consumed 8 The central portion of Argentina is affected by arsenic contaminated groundwater Specifically the La Pampa produces water containing 4 5300 microgram per liter 9 South Asia edit Bangladesh edit This section is an excerpt from Water supply and sanitation in Bangladesh Arsenic contamination of groundwater edit Arsenic contamination of the groundwater in Bangladesh is a serious problem Prior to the 1970s Bangladesh had one of the highest infant mortality rates in the world Ineffective water purification and sewage systems as well as periodic monsoons and flooding exacerbated these problems As a solution UNICEF and the World Bank advocated the use of wells to tap into deeper groundwater During the 1970s UNICEF worked with the Department of Public Health Engineering to install tube wells The wells consist of tubes 5 cm in diameter inserted less than 200 m into the ground and capped with an iron or steel hand pump At that time standard water testing procedures did not include arsenic testing 10 This lack of precaution led to one of the largest mass poisoning of a population because the ground water used for drinking was contaminated with arsenic 11 Tube wells were supposed to draw water from underground aquifers to provide a safe source of water for the nation Millions of wells were constructed as a result In 1993 it was discovered that groundwater in large parts of Bangladesh was naturally contaminated with arsenic 12 13 389 The issue came to international attention in 1995 14 15 In the Ganges Delta the affected wells are typically more than 20 meters and less than 100 meters deep 16 Groundwater closer to the surface typically has spent a shorter time in the ground therefore likely absorbing a lower concentration of arsenic water deeper than 100 meters is exposed to much older sediments which have already been depleted of arsenic 17 Criticism has been leveled at the aid agencies who denied the problem during the 1990s while millions of tube wells were sunk The aid agencies later hired foreign experts who recommended treatment plants that were inappropriate to the conditions were regularly breaking down or were not removing the arsenic 18 India edit In Bihar groundwater in 13 districts have been found to be contaminated with arsenic with quantities exceeding 0 05 mg L All these districts are situated close to large rivers like Ganga and Gandak 19 In West Bengal India water is mostly supplied from rivers open wells or ponds These may be contaminated with communicable diseases such as dysentery typhoid cholera and hepatitis Since the 1970s non governmental organisations in India have focused on sinking tube wells to provide drinking water uncontaminated by diseases with the unforeseen side effect of exposing some people to arsenic contaminated groundwater 20 21 Nepal edit Nepal is subject to a serious problem with arsenic contamination The problem is most severe in the Terai region the worst being near Nawalparasi District where 26 percent of shallow wells failed to meet WHO standard of 10 ppb A study by Japan International Cooperation Agency and the Environment in the Kathmandu Valley showed that 72 of deep wells failed to meet the WHO standard and 12 failed to meet the Nepali standard of 50 ppb 22 Pakistan edit 66 of 1200 samples tested contained arsenic above WHO recommended limit threatening over 60 million residents 50 60 million residents consume water with arsenic levels greater than 50 micrograms of arsenic per liter levels far passing acceptable levels worldwide 23 United States edit Regulation edit A drinking water standard of 0 05 mg L equal to 50 parts per billion or ppb arsenic was originally established in the United States by the Public Health Service in 1942 After the passage of the Safe Drinking Water Act of 1974 SDWA the Environmental Protection Agency EPA was given the power to set the maximum containment levels MCLs of contaminants in public water supplies In 1996 Congress amended the SDWA and created a Drinking Water State Revolving Fund to provide loans for water supply improvements which increased the EPA s power to set mandates This amendment created the costs and benefits rule to determine whether the cost of implementing new MCLs outweighs the health benefits To maximize the costs and benefits of setting new MLCs the EPA began allowing more affordable technology to be substituted that did not fully meet MLC standards because it was more affordable The EPA studied the pros and cons of lowering the arsenic MCL for years in the late 1980s and 1990s No action was taken until January 2001 when the Clinton administration in its final weeks promulgated a new standard of 0 01 mg L 10 ppb to take effect January 2006 24 The Bush administration suspended the midnight regulation but after some months of study the new EPA administrator Christine Todd Whitman approved the new 10 ppb arsenic standard and its original effective date of January 2006 25 Many locations exceed this limit 26 A 2017 Lancet Public Health study found that this rule change led to fewer cancer deaths 27 28 Many public water supply systems across the United States obtained their water supply from groundwater that had met the old 50 ppb arsenic standard but exceeded the new 10 ppb MCL These utilities searched for either an alternative supply or an inexpensive treatment method to remove the arsenic from their water In Arizona an estimated 35 percent of water supply wells were put out of compliance by the new regulation in California the percentage was 38 percent 29 The proper arsenic MCL continues to be debated Some have argued that the 10 ppb federal standard is still too high while others have argued that 10 ppb is needlessly strict Individual states can establish lower arsenic limits New Jersey has done so setting a maximum of 0 005 mg L 5 ppb for arsenic in drinking water 30 A study of private water wells in the Appalachian mountains found that six percent of the wells had arsenic above the U S MCL of 0 010 mg L 31 Case studies and incidents edit Fallon Nevada has long been known to have groundwater with relatively high arsenic concentrations in excess of 0 08 mg L 32 Even some surface waters such as the Verde River in Arizona sometimes exceed 0 01 mg L arsenic especially during low flow periods when the river flow is dominated by groundwater discharge 33 A study conducted in a contiguous six county area of southeastern Michigan investigated the relationship between moderate arsenic levels and 23 disease outcomes Disease outcomes included several types of cancer diseases of the circulatory and respiratory system diabetes mellitus and kidney and liver diseases Elevated mortality rates were observed for all diseases of the circulatory system The researchers acknowledged a need to replicate their findings 34 Various studies have also shown that arsenic exposure during pregnancy can result in infant death cancer heart attacks kidney failure lung complications as well as reduced intelligence memory and cognitive development in the child 3 Water purification solutions editAccess to clean drinking water is fraught with political socio economic and cultural inequities In practice many water treatment strategies tend to be temporary fixes to a larger problem often prolonging the social issues while treating the scientific ones 35 Scientific studies have shown that interdisciplinary approaches to water purification are especially important to consider and long lasting improvements involve larger perspectives than strict scientific approaches 36 Small scale water treatment edit A review of methods to remove arsenic from groundwater in Pakistan summarizes the most technically viable inexpensive methods 37 Most small scale treatments focus on water after it has left the distribution site and are thus more focused on quick temporary fixes A simpler and less expensive form of arsenic removal is known as the Sono arsenic filter using three pitchers containing cast iron turnings and sand in the first pitcher and wood activated carbon and sand in the second 38 Plastic buckets can also be used as filter containers 39 It is claimed that thousands of these systems are in use and can last for years while avoiding the toxic waste disposal problem inherent to conventional arsenic removal plants Although novel this filter has not been certified by any sanitary standards such as NSF ANSI WQA and does not avoid toxic waste disposal similar to any other iron removal process In the United States small under the sink units have been used to remove arsenic from drinking water This option is called point of use treatment The most common types of domestic treatment use the technologies of adsorption using media such as Bayoxide E33 GFH activated alumina or titanium dioxide 40 or reverse osmosis Ion exchange and activated alumina have been considered but not commonly used Chaff based filters have been reported to reduce the arsenic content of water to 3 mg L 3 ppb This is especially important in areas where the potable water is provided by filtering the water extracted from the underground aquifer 41 In iron electrocoagulation Fe EC iron is dissolved nonstop using electricity and the resulting ferric hydroxides oxyhydroxides and oxides form an absorbent readily attracted to arsenic Current density the amount of charge delivered per liter of water of the process is often manipulated in order to achieve maximum arsenic depletion 42 This treatment strategy has primarily been used in Bangladesh 43 and has proven to be largely successful In fact using iron electrocoagulation to remove arsenic in water proved to be the most effective treatment option 44 Large scale water treatment edit In some places such as the United States all the water supplied to residences by utilities must meet primary health based drinking water standards Regulations may require large scale treatment systems to remove arsenic from the water supply The effectiveness of any method depends on the chemical makeup of a particular water supply The aqueous chemistry of arsenic is complex and may affect the removal rate that can be achieved by a particular process Some large utilities with multiple water supply wells could shut down those wells with high arsenic concentrations and produce only from wells or surface water sources that meet the arsenic standard Other utilities however especially small utilities with only a few wells may have no available water supply that meets the arsenic standard Coagulation filtration also known as flocculation removes arsenic by coprecipitation and adsorption using iron coagulants Coagulation filtration using alum is already used by some utilities to remove suspended solids and may be adjusted to remove arsenic 45 Iron oxide adsorption filters the water through a granular medium containing ferric oxide Ferric oxide has a high affinity for adsorbing dissolved metals such as arsenic The iron oxide medium eventually becomes saturated and must be replaced The sludge disposal is a problem here too Activated alumina is an adsorbent that effectively removes arsenic Activated alumina columns connected to shallow tube wells in India and Bangladesh have removed both As III and As V from groundwater for decades Long term column performance has been possible through the efforts of community elected water committees that collect a local water tax for funding operations and maintenance 46 It has also been used to remove undesirably high concentrations of fluoride Ion exchange has long been used as a water softening process although usually on a single home basis Traditional anion exchange resins are effective in removing As V but not As III or arsenic trioxide which doesn t have a net charge Effective long term ion exchange removal of arsenic requires a trained operator to maintain the column Both reverse osmosis and electrodialysis also called electrodialysis reversal can remove arsenic with a net ionic charge Note that arsenic oxide As2O3 is a common form of arsenic in groundwater that is soluble but has no net charge Some utilities presently use one of these methods to reduce total dissolved solids and therefore improve taste A problem with both methods is the production of high salinity waste water called brine or concentrate which then must be disposed of Subterranean arsenic removal SAR technology SAR TechnologyIn subterranean arsenic removal aerated groundwater is recharged back into the aquifer to create an oxidation zone which can trap iron and arsenic on the soil particles through adsorption process The oxidation zone created by aerated water boosts the activity of the arsenic oxidizing microorganisms which can oxidize arsenic from 3 to 5 state SAR Technology No chemicals are used and almost no sludge is produced during operational stage since iron and arsenic compounds are rendered inactive in the aquifer itself Thus toxic waste disposal and the risk of its future mobilization is prevented Also it has very long operational life similar to the long lasting tube wells drawing water from the shallow aquifers Six such SAR plants funded by the World Bank and constructed by Ramakrishna Vivekananda Mission Barrackpore amp Queen s University Belfast UK are operating in West Bengal Each plant has been delivering more than 3 000 liters of arsenic and iron free water daily to the rural community The first community water treatment plant based on SAR technology was set up at Kashimpore near Kolkata in 2004 by a team of European and Indian engineers led by Bhaskar Sen Gupta of Queen s University Belfast for TiPOT 47 48 49 50 SAR technology had been awarded Dhirubhai Ambani Award 2010 from IChemE UK for Chemical Innovation Again SAR was the winner of the St Andrews Award for Environment 2010 The SAR Project was selected by the Blacksmith Institute New York amp Green Cross Switzerland as one of the 12 Cases of Cleanup amp Success in the World s Worst Polluted Places Report 2009 Refer www worstpolluted org Currently large scale SAR plants are being installed in US Malaysia Cambodia and Vietnam Nanotechnology based arsenic remediation edit Using nanomaterials it is possible to effectively destroy microorganisms adsorb arsenic and fluoride remove heavy metals and degrade pesticides usually found in water 51 52 Researchers have looked at new methods to synthesize iron oxide hydroxide oxyhydroxide compositions in the laboratory and used them for water purification A product called AMRIT meaning elixir in Indian languages developed by the Indian Institute of Technology Madras is an affordable water purification technology based on advanced materials which has been validated through research articles 53 54 and patents 55 and has been approved for national implementation in India The technology can remove several anions especially arsenate and arsenite two common species present in arsenic contaminated water and fluoride from water Currently this technology is delivering arsenic free water to about 10 00 000 people every day 56 Research editMapping edit In 2008 the Swiss Aquatic Research Institute Eawag presented a new method by which hazard maps could be produced for geogenic toxic substances in groundwater 57 58 59 60 This provides an efficient way of determining which wells should be tested In 2016 the research group made its knowledge freely available on the Groundwater Assessment Platform GAP This offers specialists worldwide the possibility of uploading their own measurement data visually displaying them and producing risk maps for areas of their choice GAP also serves as a knowledge sharing forum for enabling further development of methods for removing toxic substances from water Dietary intake edit Researchers from Bangladesh and the United Kingdom have claimed that dietary intake of arsenic adds a significant amount to total intake where contaminated water is used for irrigation 61 62 63 See also editArsenic poisoning Grainger challenge Toxic heavy metal ArsenicReferences edit See Arsenic in drinking water seen as threat USAToday com 30 August 2007 See page 6 of Peter Ravenscroft Predicting the global distribution of arsenic pollution in groundwater Paper presented at Arsenic The Geography of a Global Problem Royal Geographic Society Arsenic Conference held at Royal Geographic Society London England August 29 2007 This conference is part of The Cambridge Arsenic Project Smedley PL Kinniburgh DG 2002 A review of the source behaviour and distribution of arsenic in natural waters PDF Applied Geochemistry 17 5 517 568 Bibcode 2002ApGC 17 517S doi 10 1016 S0883 2927 02 00018 5 S2CID 55596829 a b c Arsenic www who int Retrieved 2020 11 28 Mukherjee A Sengupta M K Hossain M A 2006 Arsenic contamination 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2015 05 22 Estimation of Arsenic Intake from Drinking Water and Food Raw and Cooked in a Rural Village of Northern Chile Urine as a Biomarker of Recent Exposure International Journal of Environmental Research and Public Health 12 5 5614 5633 doi 10 3390 ijerph120505614 PMC 4454988 PMID 26006131 Smedley P L Kinniburgh D G Macdonald D M J Nicolli H B Barros A J Tullio J O Pearce J M Alonso M S 2005 Arsenic associations in sediments from the loess aquifer of La Pampa Argentina Applied Geochemistry 20 5 989 1016 Bibcode 2005ApGC 20 989S doi 10 1016 j apgeochem 2004 10 005 Smith AH Lingas EO Rahman M Contamination of drinking water by arsenic in Bangladesh a public health emergency Bulletin of the World Health Organization 2000 78 87 Khan AW et al Arsenic contamination in groundwater and its effect on human health with particular reference to Bangladesh Journal of Preventive and Social Medicine 1997 16 65 73 The World Bank December 2005 Bangladesh Country Water Resources Assistance Strategy PDF Report The World Bank Retrieved 21 April 2008 Das Gupta Ashim Babel Mukund Singh Albert Xavier Mark Ole June 2005 Water Sector of Bangladesh in the Context of Integrated Water Resources Management A Review International Journal of Water Resources Development Routledge 21 2 385 398 doi 10 1080 07900620500037818 S2CID 154569673 Amit Chatterjee Dipankar Das Badal K Mandal Tarit Roy Chowdhury Gautam Samanta Dipankar Chakraborti 1995 Arsenic in ground water in six districts of West Bengal India the biggest arsenic calamity in the world Part I Arsenic species in drinking water and urine of the affected people Analyst 120 3 643 651 Bibcode 1995Ana 120 643C doi 10 1039 AN9952000643 Dipankar Das Amit Chatterjee Badal K Mandal Gautam Samanta Dipankar Chakraborti Bhabatosh Chanda 1995 Arsenic in ground water in six districts of West Bengal India the biggest arsenic calamity in the world Part 2 Arsenic concentration in drinking water hair nails urine skin scale and liver tissue biopsy of the 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02 06 Retrieved 2006 12 04 102 KiB pictures with descriptions Jing Chuanyong Liu Suqin Meng Xiaoguang 2008 01 15 Arsenic remobilization in water treatment adsorbents under reducing conditions Part I Incubation study Science of the Total Environment 389 1 188 194 Bibcode 2008ScTEn 389 188J doi 10 1016 j scitotenv 2007 08 030 ISSN 0048 9697 PMID 17897702 Newspaper article Archived 2012 04 17 at the Wayback Machine in Hungarian published by Magyar Nemzet on 15 April 2012 Addy Susan E A Gadgil Ashok J Kowolik Kristin Kostecki Robert 2009 ElectroChemical Arsenic Removal ECAR for Rural Bangladesh Merging Technology with Sustainable Implementation doi 10 2172 982898 S2CID 15020139 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help van Genuchten Case M Addy Susan E A Pena Jasquelin Gadgil Ashok J 2012 01 17 Removing Arsenic from Synthetic Groundwater with Iron Electrocoagulation An Fe and As K Edge EXAFS Study Environmental Science 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the World s Most Polluted Places Ever Be Cleaned Scientific American Archived from the original on 2012 10 10 Reuters Breaking International News amp Views Reuters Mukherjee Sritama Gupte Tanvi Jenifer S Thomas Tiju Pradeep Thalappil December 2019 Arsenic in Water Speciation Sources Distribution and Toxicology Copyright c 2019 John Wiley amp Sons Inc doi 10 1002 9781119300762 wsts0053 ISBN 9781119300762 S2CID 214108659 Mukherjee Sritama Gupte Tanvi Jenifer S Thomas Tiju Pradeep Thalappil 29 December 2019 Arsenic in Water Fundamentals of Measurement and Remediation Copyright c 2019 John Wiley amp Sons Inc doi 10 1002 9781119300762 wsts0054 ISBN 9781119300762 S2CID 212834619 Sankar M Udhaya Aigal Sahaja Chaudhary Amrita S Anshup M Maliyekkal Shihabudheen Kumar A Anil Chaudhari Kamalesh Pradeep T 2013 Biopolymer reinforced synthetic granular nanocomposites for affordable point of use water purification Proc Natl Acad Sci 110 21 8459 64 Bibcode 2013PNAS 110 8459S doi 10 1073 pnas 1220222110 PMC 3666696 PMID 23650396 Kumar A Anil Som Anirban Longo Paolo Sudhakar Chennu Bhuin Radha Gobinda Sen Gupta Soujit S Anshup Sankar Mohan Udhaya Chaudhary Amrita Kumar Ramesh Pradeep T 2016 Confined metastable 2 line ferrihydrite for affordable point of use arsenic free drinking water Adv Mater 29 7 1604260 doi 10 1002 adma 201604260 PMID 27918114 S2CID 205273753 Pradeep Thalappil Mukherjee Sritama Kumar A Anil A method for preparing cellulose microstructures templated nanocomposites with enhanced arsenic removal capacity 201641044817 December 26 2016 granted as patent no IN337979 on June 4 2020 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Jeevajalam Arsenic free drinking water Documentary Youtube Archived from the original on 2021 12 14 Amini M Mueller K Abbaspour K C Rosenberg T Afyuni M Moller M Sarr M Johnson C A 2008 Statistical modeling of global geogenic fluoride contamination in groundwaters Environmental Science and Technology 42 10 3662 68 doi 10 1021 es071958y Amini M Abbaspour K C Berg M Winkel L Hug S J Hoehn E Yang H Johnson C A 2008 Statistical modeling of global geogenic arsenic contamination in groundwater Environmental Science and Technology 42 10 3669 75 doi 10 1021 es702859e Winkel L Berg M Amini M Hug S J Johnson C A Predicting groundwater arsenic contamination in Southeast Asia from surface parameters Nature Geoscience 1 536 42 2008 doi 10 1038 ngeo254 Rodriguez Lado L Sun G Berg M Zhang Q Xue H Zheng Q Johnson C A 2013 Groundwater arsenic contamination throughout China Science 341 6148 866 68 doi 10 1126 science 1237484 Mustak Hossain 2006 07 13 Toxic rice harvested in southwestern Bangladesh SciDev Net Williams P N Islam M R Adomako E E Raab A Hossain S A Zhu Y G Feldmann J Meharg A A 2006 Increase in Rice Grain Arsenic for Regions of Bangladesh Irrigating Paddies with Elevated Arsenic in Groundwaters Environ Sci Technol 40 16 4903 4908 Bibcode 2006EnST 40 4903W doi 10 1021 es060222i PMID 16955884 Raghvan T Screening of Rice Cultivars for Grain Arsenic Concentration and Speciation American Society of Agronomy Proceeding External links editATSDR Case Studies in Environmental Medicine Arsenic Toxicity Arsenic in groundwater IGRAC International Groundwater Resources Assessment Centre Arsenic in Groundwater A World Problem IAH publication Netherlands National Chapter 2008 SOS Arsenic net information and awareness raising site focused on Bangladesh Contamination of drinking water by arsenic in Bangladesh a public health emergency at SOS Arsenic net Subterranean Arsenic Treatment Technology in West Bengal 12 Cases of Cleanup amp Success www wbphed gov in Arsenic Scenario of West Bengal Drinking Death in Groundwater Arsenic Contamination as a Threat to Water Security for Bangladesh ACDIS Occasional Paper by Mustafa Moinuddin St Andrews Prize for Environment 2010 Retrieved from https en wikipedia org w index php title Arsenic contamination of 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