A phosphate is an anion, salt, functional group or ester derived from a phosphoric acid. It most commonly means orthophosphate, a derivative of orthophosphoric acid, phosphoric acid .

The phosphate or orthophosphate ion is derived from phosphoric acid by the removal of three protons . Removal of one proton gives the dihydrogen phosphate ion while removal of two protons gives the hydrogen phosphate ion . These names are also used in chemistry for salts of those anions, such as ammonium dihydrogen phosphate and trisodium phosphate.

<gallery heights="110" mode="packed">

File:3-phosphoric-acid-3D-balls.png|<br />Phosphoric<br />acid

File:2-dihydrogenphosphate-3D-balls.png|<br />Dihydrogen<br />phosphate

File:1-hydrogenphosphate-3D-balls.png|<br />Hydrogen<br />phosphate

File:0-phosphate-3D-balls.png|<br />Phosphate or orthophosphate

</gallery>

In organic chemistry, phosphate or orthophosphate is an organophosphate, an ester of orthophosphoric acid of the form where one or more hydrogen atoms are replaced by organic groups. An example is trimethyl phosphate, . The term also refers to the trivalent functional group in such esters. Phosphates may contain sulfur in place of one or more oxygen atoms (thiophosphates and organothiophosphates).

Orthophosphates are especially important among the various phosphates because of their key roles in biochemistry, biogeochemistry, and ecology, and their economic importance for agriculture and industry. The addition and removal of phosphate groups (phosphorylation and dephosphorylation) are key steps in cell metabolism. Phosphates are a major component of agricultural fertilizers and play an important role in plant growth.

{| class="wikitable"

! Equilibrium

! Dissociation constant K<sub>a</sub>

Inorganic phosphate is generally denoted P<sub>i</sub> and at physiological (homeostatic) pH primarily consists of a mixture of and ions. At a neutral pH, as in the cytosol (pH = 7.0), the concentrations of the orthophosphoric acid and its three anions have the ratios

<math chem display=block>\begin{align}

\frac{[\ce{H2PO4-}]}{[\ce{H3PO4}]} &\approx 7.5 \times 10^4 \\[4pt]

\frac{[\ce{HPO4^2-}]}{[\ce{H2PO4-}]} &\approx 0.62 \\[4pt]

\frac{[\ce{PO4^3-}]}{[\ce{HPO4^2-}]} &\approx 2.14 \times 10^{-6}

\end{align}</math>

Thus, only the and ions are present in significant amounts in the cytosol (62% , 38% ). In extracellular fluid (pH = 7.4), this proportion is inverted (61% , 39% ).

Inorganic phosphate can also be present as pyrophosphate anions , which give orthophosphate by hydrolysis:

:

Organic phosphates are commonly found in the form of esters as nucleotides (e.g. AMP, ADP, and ATP) and in DNA and RNA. Free orthophosphate anions can be released by the hydrolysis of the phosphoanhydride bonds in ATP or ADP. These phosphorylation and dephosphorylation reactions are the immediate storage and source of energy for many metabolic processes. ATP and ADP are often referred to as high-energy phosphates, as are the phosphagens in muscle tissue. Similar reactions exist for the other nucleoside diphosphates and triphosphates.

Bones and teeth

An important occurrence of phosphates in biological systems is as the structural material of bone and teeth. These structures are made of crystalline calcium phosphate in the form of hydroxyapatite. The hard dense enamel of mammalian teeth may contain fluoroapatite, a hydroxy calcium phosphate where some of the hydroxyl groups have been replaced by fluoride ions.

Medical and biological research uses

Phosphates are medicinal salts of phosphorus. Some phosphates, which help cure many urinary tract infections, are used to make urine more acidic. To avoid the development of calcium stones in the urinary tract, some phosphates are used. For patients who are unable to get enough phosphorus in their daily diet, phosphates are used as dietary supplements, usually because of certain disorders or diseases.

Phosphates induce vascular calcification, and a high concentration of phosphates in blood was found to be a predictor of cardiovascular events.

Production

Geological occurrence

thumb|upright=1.7|Phosphate mine near [[Flaming Gorge, Utah, US, 2008]]

thumb|Train loaded with phosphate rock, [[Métlaoui, Tunisia, 2012]]

Phosphates are the naturally occurring form of the element phosphorus, found in many phosphate minerals. In mineralogy and geology, phosphate refers to a rock or ore containing phosphate ions. Inorganic phosphates are mined to obtain phosphorus for use in agriculture and industry.. Within North America, the largest deposits lie in the Bone Valley region of central Florida, the Soda Springs region of southeastern Idaho, and the coast of North Carolina. Smaller deposits are located in Montana, Tennessee, Georgia, and South Carolina. The small island nation of Nauru and its neighbor Banaba Island, which used to have massive phosphate deposits of the best quality, have been mined excessively. Rock phosphate can also be found in Egypt, Israel, Palestine, Western Sahara, Navassa Island, Tunisia, Togo, and Jordan, countries that have large phosphate-mining industries.

Phosphorite mines are primarily found in:

  • North America: United States, especially Florida, with lesser deposits in North Carolina, Idaho, and Tennessee
  • Africa: Morocco, Algeria, Egypt, Niger, Senegal, Togo, Tunisia, Mauritania
  • Middle East: Saudi Arabia, Jordan, Israel, Syria, Iran and Iraq, at the town of Akashat, near the Jordanian border.
  • Central Asia: Kazakhstan
  • Oceania: Australia, Makatea, Nauru, and Banaba Island

In 2007, at the current rate of consumption, the supply of phosphorus was estimated to run out in 345 years. However, some scientists thought that a "peak phosphorus" would occur in 30 years and Dana Cordell from Institute for Sustainable Futures said <!-- in Times --> that at "current rates, reserves will be depleted in the next 50 to 100 years". Reserves refer to the amount assumed recoverable at current market prices. In 2012 the USGS estimated world reserves at 71 billion tons, while 0.19 billion tons were mined globally in 2011. Phosphorus comprises 0.1% by mass of the average rock (while, for perspective, its typical concentration in vegetation is 0.03% to 0.2%), and consequently there are quadrillions of tons of phosphorus in Earth's 3×10<sup>19</sup>-ton crust, albeit at predominantly lower concentration than the deposits counted as reserves, which are inventoried and cheaper to extract. If it is assumed that the phosphate minerals in phosphate rock are mainly hydroxyapatite and fluoroapatite, phosphate minerals contain roughly 18.5% phosphorus by weight. If phosphate rock contains around 20% of these minerals, the average phosphate rock has roughly 3.7% phosphorus by weight.

Some phosphate rock deposits, such as Mulberry in Florida, from application of the resulting phosphate fertilizer.

In December 2012, Cominco Resources announced an updated JORC compliant resource of their Hinda project in Congo-Brazzaville of 531 million tons, making it the largest measured and indicated phosphate deposit in the world.

Around 2018, Norway discovered phosphate deposits almost equal to those in the rest of Earth combined.

In July 2022 China announced quotas on phosphate exportation.

The largest importers in millions of metric tons of phosphate are Brazil 3.2, India 2.9 and the USA 1.6.

Mining

thumb|right|Phosphate imports/exports in 1937

The three principal phosphate producer countries (China, Morocco and the United States) account for about 70% of world production.

{| class="wikitable centre sortable width=80%;"

|+ Production and global reserves of natural phosphate by country in 2019<br /><small>(USGS, 2021)</small>

! Country !! Production <br />(millions kg) !! Share of <br /> global <br /> production (%) !! Reserves<br />(millions kg)

|-

| Algeria || align="right" | || align="right" | 0.54 || align="right" |

|-

| Australia || align="right" | || align="right" | 1.17 || align="right" |

|-

| Brazil || align="right" | || align="right" | 3.00 || align="right" |

|-

| China || align="right" | || align="right" | 44.83 || align="right" |

|-

| Egypt || align="right" | || align="right" | 2.47 || align="right" |

|-

|Finland || align="right" | || align="right" | - || align="right" |

|-

| India || align="right" | || align="right" | 0.49 || align="right" |

|-

| Iraq || align="right" | || align="right" | 0.09 || align="right" |

|-

| Israel || align="right" | || align="right" | 1.48 || align="right" |

|-

| Jordan || align="right" | || align="right" | 3.36 || align="right" |

|-

| Kazakhstan || align="right" | || align="right" | 0.72 || align="right" |

|-

| Mexico || align="right" | || align="right" | 0.76 || align="right" |

|-

| Morocco (WS included) || align="right" | || align="right" | 13.45 || align="right" |

|-

| Peru || align="right" | || align="right" | 1.79 || align="right" |

|-

| Russia || align="right" | || align="right" | 5.60 || align="right" |

|-

| Saudi Arabia || align="right" | || align="right" | 1.48 || align="right" |

|-

| Senegal || align="right" | || align="right" | 0.45 || align="right" |

|-

| South Africa || align="right" | || align="right" | 0.99 || align="right" |

|-

| Syria || align="right" | || align="right" | 0.34 || align="right" |

|-

| Togo || align="right" | || align="right" | 0.45 || align="right" |

|-

| Tunisia || align="right" | || align="right" | 1.79 || align="right" |

|-

|Uzbekistan || align="right" | || align="right" | - || align="right" |

|-

| United States || align="right" | || align="right" | 12.37 || align="right" |

|-

| Vietnam || align="right" | || align="right" | 1.21 || align="right" |

|- class="sortbottom"

| Other countries || align="right" | || align="right" | 1.17 || align="right" |

|- class="sortbottom" style="background: #EFEFEF"

| Total || align="right" | || align="right" | 100 || align="right" |

|}

Environmental Impacts of Mining

Phosphate deposits can contain significant amounts of naturally occurring heavy metals. Mining operations processing phosphate rock can leave tailings piles containing elevated levels of cadmium, lead, nickel, copper, chromium, and uranium. Unless carefully managed, these waste products can leach heavy metals into groundwater or nearby estuaries. Uptake of these substances by plants and marine life can lead to concentration of toxic heavy metals in food products.

== Ecology ==<!-- Other articles link here -->

left|thumb|Sea surface phosphate from the [[World Ocean Atlas]]

thumb|upright=1.25|Relationship of phosphate to nitrate uptake for [[photosynthesis in various regions of the ocean. Note that nitrate is more often limiting than phosphate. See the Redfield ratio.]]Phosphorus is a limiting nutrient in many freshwater bodies. Oceans tend to have lower concentrations of phosphorus than freshwaters, but have more factors governing the limiting nutrient. Often, in marine ecosystems, the limiting nutrient is nitrogen rather than phosphorus. Phosphate is the most common form of phosphorus in the environment and is the only form of phosphorus that plants can use.

Plant metabolism

Phosphorus abundance plays a role in regulating plant growth because phosphorus is part of important molecules including nucleic acids, phospholipids, and ATP. Orthophosphate is the type of phosphorus that is easiest for plants to use, but orthophosphate concentrations in soils are usually low. In the direct uptake pathway, plants take up phosphate through root hairs, which can decrease phosphate concentrations in the rhizosphere because phosphate does not renew as quickly as plants take it up. Up to 80% of the cellular phosphate is stored in vacuoles, where plants can access it to maintain phosphorus supply for important functions. As clay minerals promote biomineralization, the presence of bacteria and clay minerals resulted in calcium hydroxyapatite and calcite precipitates. Goethite is one particularly common and important form of iron for these bonds. Phosphate may also adsorb to the edges of clay minerals including koalinite, montmorillonite, and illite. Demand for phosphate fertilizers is increasing, likely increasing the impact on water bodies. Other sources of phosphate to the environment include detergent, sewage, and residential fertilizer use. Some countries have created laws regulating phosphate in detergents to reduce the phosphate pollution from detergents (see Phosphates in detergent).

Addition of high levels of phosphate to environments can have significant ecological consequences such as excessive plant growth. In the context of pollution, phosphates are one component of total dissolved solids, a major indicator of water quality, but not all phosphorus is in a molecular form that algae can break down and consume.

See also

  • Diammonium phosphate –
  • Disodium phosphate –
  • Metaphosphate –
  • Monosodium phosphate –
  • Organophosphorus compounds
  • Ouled Abdoun Basin
  • Phosphate conversion coating

References

  • US Minerals Databrowser provides data graphics covering consumption, production, imports, exports and price for phosphate and 86 other minerals
  • Phosphate: analyte monograph – The Association for Clinical Biochemistry and Laboratory Medicine