Phosphogypsum (PG) is thecalcium sulfate hydrate formed as aby-product of the production offertilizer, particularlyphosphoric acid, fromphosphate rock. It is mainly composed ofgypsum (CaSO4 · 2 H2O). Althoughgypsum is a widely used material in theconstruction industry, phosphogypsum is usually not used, but is stored indefinitely because of its weakradioactivity caused by the presence of naturally occurringuranium (U) andthorium (Th), and their daughter isotopesradium (Ra),radon (Rn) andpolonium (Po). On the other hand, it includes several valuable components—calcium sulphates and elements such assilicon,iron,titanium,magnesium,aluminum, andmanganese.[1] However, the long-term storage of phosphogypsum is controversial.[2] About five tons of phosphogypsum are generated per ton of phosphoric acid production. Annually, the estimated generation of phosphogypsum worldwide is 100 to 280 million metric tons.[3]
Phosphogypsum is a by-product from the production ofphosphoric acid by treating phosphate ore (apatite) withsulfuric acid according to the following reaction:
It is radioactive due to the presence of naturally occurringuranium (5–10ppm) andthorium, and theirdaughter nuclides radium, radon, polonium, etc. Marine-deposited phosphate typically has a higher level of radioactivity thanigneous phosphate deposits, because uranium is present inseawater at about 3ppb (roughly 85 ppb oftotal dissolved solids). Uranium is concentrated during the formation ofevaporite deposits as dissolved solids precipitate in order ofsolubility with easily dissolved materials such as sodium chloride remaining in solution longer than less soluble materials like uranium or sulfates. Other components of phosphogypsum includesilica (5–10%),fluoride (F, ~1%),phosphorus (P, ~0.5%),iron (Fe, ~0.1%),aluminum (Al, ~0.1%),barium (Ba, 50 ppm),lead (Pb, ~5 ppm),chromium (Cr, ~3 ppm),selenium (Se, ~1 ppm), andcadmium (Cd, ~0.3 ppm).[3][5] About 90% of Po and Ra from raw ore is retained into Phosphogypsum.[3] Thus it can be considered technologically enhanced naturally occurring radioactive material (TENORM).
Various applications have been proposed for using phosphogypsum, including using it as material for:[2]
According to Taylor (2009), "up to 15% of world PG production is used to make building materials, as a soil amendment and as a set controller in the manufacture ofPortland cement". The rest remains in stack.[3]
TheUnited States Environmental Protection Agency (EPA) has banned most applications of phosphogypsum having a226Ra concentration of greater than 10picocurie/gram (0.4 Bq/g)[7] in 1990.[3] As a result, phosphogypsum which exceeds this limit is stored in large stacks since extracting such low concentrations of radium is either not possible or not economical with current technology for either the use of the gypsum or the radium[citation needed]. Given the traditional definition of the Curie via thespecific activity of226
Ra, this limit is equivalent to 0.01 milligrams (0.00015 gr) of radium per metric ton or a concentration of 10 parts per trillion. (See§ Gyp stacks below.)
EPA approved the use of phosphogypsum for road construction during theTrump Administration in 2020, saying that the approval came at the request of The Fertilizer Institute, which advocates for the fertilizer industry.[8] Environmentalists opposed the decision, saying that using the radioactive material in this way can pose health risks.[9] In 2021, the EPA withdrew the rule authorizing the use of phosphogypsum in road construction.[10]
The state of Florida has approximately 80% of the world's phosphogypsum production capacity. In May 2023, the Florida legislature passed a bill requiring theFlorida Department of Transportation to study the use of phosphogypsum in road construction, including demonstration projects, though this would require federal approval.[11] The law, which requires the department to complete a study and make a recommendation by April 1, 2024, was signed into law by GovernorRon DeSantis on June 29, 2023.[12]
China's phosphate fertilizer production exceeded that of the US in 2005, and with it came the problem of excess phosphogypsum. By 2018, inappropriate storage has become a major problem in theYangtze River watershed, with phosphorus accounting for 56% of all breaches of water quality standards. Phosphorus, which still remains in phosphogypsum, can lead toeutrophication of bodies of water and hencealgal blooms or evenanoxic events ("dead zones") in the lower layers of a body of water. The total amount of phosphogypsum in storage by 2020 exceeds 600 Mt, with 75 Mt produced each year.[13]
The construction industry is the number one user of phosphogypsum in 2020, with 10.5 Mt used as concrete set retarder and 3.5 Mt used indrywall.[13] It is also used as a chemical feedstock for producingsulfates, and as asoil conditioner similar to regular gypsum.[14] The total consumption in 2020 was 31 Mt, much lower than the rate of accumulation.[13] There has been a significant push to expand the use of phosphogypsum on the national level since 2016, being part of two consecutivefive-year plans.[14]
Phosphogypsum may require pre-processing to remove contaminants before use. Phosphorus (P) significantly retards curing and reduces the strength of the material, an important concern in construction. Fluorine (F) may accumulate in crops. Although Chinese phosphogypsum generally contain lesstoxic heavy metals and radioactive elements[why?][citation needed], some nevertheless exceed acceptable radioactivity limits for building material, or produce crops with unacceptable amounts of arsenic (As), lead (Pb), cadmium (Cd), or mercury (Hg). Barriers to further use include cost of heavy metal removal and considerable variation among sources of phosphogypsum.[14]
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Phosphogypsum may pollute the environment by its phosphorus content causingeutrophication, by itstoxic heavy metal content, and by its radioactivity. PG releasesradon, which can accumulate indoors if used as a construction material. Open-air stores also release radon at a level potentially hazardous to workers.[3] Radon is anoble gas that is heavier than air and thus tends to accumulate in poorly ventilated underground spaces like mines or cellars. Naturally occurring radon is considered the second most common cause oflung cancer after smoking.[15] More substantial however is the leaching of the contents of phosphogypsum into the water table and consequently soil, exacerbated by the fact that PG is often transported as aslurry.[3] Accumulation of water inside of gypstacks can lead to weakening of the stack structure, a cause of several alarms in the United States.[6]
The main approach to reducing PG pollution is to act before it leaches into the environment. This can mean recycling purified materials from PG in a variety of applications (see above)[3] or converting it into a more stable form for storage.Cement paste backfill converts hazardous mining waste, such as PG, into a cement paste, and then uses the paste to fill in voids created by mining the rocks.[16]
Bioremediation may be used to clean up already contaminated water and soil. Microbials can remove heavy metals, radioactive material[citation needed], and any organic pollutants within, and reduce the sulfate material.[17] With suitable soil amendments and additives, PG can also support the growth of hardy plants, hopefully preventing further erosion.[18]
Often phosphogypsum reuse is uneconomical due to impurities[further explanation needed], mining companies commonly dump the waste into man-made hills called "phosphogypsum stacks" or waste ponds near the mine. Waste ponds[19] are open-air reservoirs that contain a variety of different types of industrial and agricultural waste. including at least 70 phosphogypsum stacks (from phosphate mines used for fertilizer production).[20] A leaking phosphogypsum waste pond that nearly collapsed, if waste was not allowed to flow intoTampa Bay in Florida in 2021, highlights the dangers and near-disasters associated with wastewater ponds throughout the country.[21]
CentralFlorida has a large quantity of phosphate deposits, particularly in theBone Valley region. The marine-deposited phosphate ore from central Florida is weakly radioactive, and as such, the phosphogypsum by-product (in which the radionuclides are somewhat concentrated) is too radioactive to be used for most applications. As a result, there are about a billion tons of phosphogypsum stacked in 25 stacks in Florida (22 are in central Florida) and about 30 million additional tons are generated each year.[22]