Zinc

copperzincgallium
-

Zn

Cd
Appearance
silver-gray
General properties
Name, symbol, number zinc, Zn, 30
Pronunciation /ˈzɪŋk/ zingk
Element category transition metal
Category notes Alternatively considered a post-transition metal
Group, period, block 12, 4, d
Standard atomic weight 65.38(2)g·mol−1
Electron configuration [Ar] 3d10 4s2
Electrons per shell 2, 8, 18, 2 (Image)
Physical properties
Phase solid
Density (near r.t.) 7.14 g·cm−3
Liquid density at m.p. 6.57 g·cm−3
Melting point 692.68 K, 419.53 °C, 787.15 °F
Boiling point 1180 K, 907 °C, 1665 °F
Heat of fusion 7.32 kJ·mol−1
Heat of vaporization 123.6 kJ·mol−1
Specific heat capacity (25 °C) 25.470 J·mol−1·K−1
Vapor pressure
P (Pa) 1 10 100 1 k 10 k 100 k
at T (K) 610 670 750 852 990 1179
Atomic properties
Oxidation states +2, +1, 0
(amphoteric oxide)
Electronegativity 1.65 (Pauling scale)
Ionization energies
(more)
1st: 906.4 kJ·mol−1
2nd: 1733.3 kJ·mol−1
3rd: 3833 kJ·mol−1
Atomic radius 134 pm
Covalent radius 122±4 pm
Van der Waals radius 139 pm
Miscellanea
Crystal structure hexagonal
Magnetic ordering diamagnetic
Electrical resistivity (20 °C) 59.0 nΩ·m
Thermal conductivity (300 K) 116 W·m−1·K−1
Thermal expansion (25 °C) 30.2 µm·m−1·K−1
Speed of sound (thin rod) (r.t.) (rolled) 3850 m·s−1
Young's modulus 108 GPa
Shear modulus 43 GPa
Bulk modulus 70 GPa
Poisson ratio 0.25
Mohs hardness 2.5
Brinell hardness 412 MPa
CAS registry number 7440-66-6
Most stable isotopes
Main article: Isotopes of zinc
iso NA half-life DM DE (MeV) DP
64Zn 48.6% 64Zn is stable with 34 neutrons
65Zn syn 243.8 d ε 1.3519 65Cu
γ 1.1155 -
66Zn 27.9% 66Zn is stable with 36 neutrons
67Zn 4.1% 67Zn is stable with 37 neutrons
68Zn 18.8% 68Zn is stable with 38 neutrons
70Zn 0.6% 70Zn is stable with 40 neutrons
72Zn syn 46.5 h β 0.458 72Ga

Zinc (pronounced /ˈzɪŋk/ zingk, from German: Zink), also known as spelter, is a metallic chemical element; it has the symbol Zn and atomic number 30. It is the first element in group 12 of the periodic table. Zinc is, in some respects, chemically similar to magnesium, because its ion is of similar size and its only common oxidation state is +2. Zinc is the 24th most abundant element in the Earth's crust and has five stable isotopes. The most exploited zinc ore is sphalerite, a zinc sulfide. The largest exploitable deposits are found in Australia, Canada, and the United States. Zinc production includes froth flotation of the ore, roasting, and final extraction using electricity (electrowinning).

Brass, which is an alloy of copper and zinc, has been used since at least the 10th century BC. Impure zinc metal was not produced in large scale until the 13th century in India, while the metal was unknown to Europe until the end of the 16th century. Alchemists burned zinc in air to form what they called "philosopher's wool" or "white snow".

The element was probably named by the alchemist Paracelsus after the German word Zinke. German chemist Andreas Sigismund Marggraf is normally given credit for discovering pure metallic zinc in 1746. Work by Luigi Galvani and Alessandro Volta uncovered the electrochemical properties of zinc by 1800. Corrosion-resistant zinc plating of steel (hot-dip galvanizing) is the major application for zinc. Other applications are in batteries and alloys, such as brass. A variety of zinc compounds are commonly used, such as zinc carbonate and zinc gluconate (as dietary supplements), zinc chloride (in deodorants), zinc pyrithione (anti-dandruff shampoos), zinc sulfide (in luminescent paints), and zinc methyl or zinc diethyl in the organic laboratory.

Zinc is an essential mineral of "exceptional biologic and public health importance".[1] Zinc deficiency affects about two billion people in the developing world and is associated with many diseases.[2] In children it causes growth retardation, delayed sexual maturation, infection susceptibility, and diarrhea, contributing to the death of about 800,000 children worldwide per year.[1] Enzymes with a zinc atom in the reactive center are widespread in biochemistry, such as alcohol dehydrogenase in humans. Consumption of excess zinc can cause ataxia, lethargy and copper deficiency.

Contents

Characteristics

Physical properties

Zinc, also referred to in nonscientific contexts as spelter,[3] is a bluish-white, lustrous, diamagnetic metal,[4] though most common commercial grades of the metal have a dull finish.[5] It is somewhat less dense than iron and has a hexagonal crystal structure.[6]

The metal is hard and brittle at most temperatures but becomes malleable between 100 and 150 °C.[4][5] Above 210 °C, the metal becomes brittle again and can be pulverized by beating.[7] Zinc is a fair conductor of electricity.[4] For a metal, zinc has relatively low melting (420 °C) and boiling points (900 °C).[8] Its melting point is the lowest of all the transition metals aside from mercury and cadmium.[8]

Many alloys contain zinc, including brass, an alloy of zinc and copper. Other metals long known to form binary alloys with zinc are aluminium, antimony, bismuth, gold, iron, lead, mercury, silver, tin, magnesium, cobalt, nickel, tellurium and sodium.[9] While neither zinc nor zirconium are ferromagnetic, their alloy ZrZn2 exhibits ferromagnetism below 35 K.[4]

Occurrence

Zinc makes up about 75 ppm (0.0075%) of the Earth's crust, making it the 24th most abundant element there. Soil contains 5–770 ppm of zinc with an average of 64 ppm. Seawater has only 30 ppb zinc and the atmosphere contains 0.1–4 µg/m3.[10]

A black shiny lump of solid with uneven surface.
Sphalerite (ZnS)

The element is normally found in association with other base metals such as copper and lead in ores.[11] Zinc is a chalcophile , meaning the element has a low affinity for oxides and prefers to bond with sulfides. Chalcophiles formed as the crust solidified under the reducing conditions of the early Earth's atmosphere.[12] Sphalerite, which is a form of zinc sulfide, is the most heavily mined zinc-containing ore because its concentrate contains 60–62% zinc.[11]

Other minerals, from which zinc is extracted, include smithsonite (zinc carbonate), hemimorphite (zinc silicate), wurtzite (another zinc sulfide), and sometimes hydrozincite (basic zinc carbonate).[13] With the exception of wurtzite, all these other minerals were formed as a result of weathering processes on the primordial zinc sulfides.[12]

World zinc resources total about 1.8 gigatonnes.[14] Nearly 200 megatonnes were economically viable in 2008; adding marginally economic and subeconomic reserves to that number, a total reserve base of 500 megatonnes has been identified.[14] Large deposits are in Australia, Canada and the United States with the largest reserves in Iran.[12][15][16] At the current rate of consumption, these reserves are estimated to be depleted sometime between 2027 and 2055.[17][18] About 346 megatonnes have been extracted throughout history to 2002, and one estimate found that about 109 megatonnes of that remains in use.[19]

Isotopes

Five isotopes of zinc occur in nature. 64Zn is the most abundant isotope (48.63% natural abundance).[20] This isotope has such a long half-life, at 4.3×1018 a,[21] that its radioactivity can be ignored.[22] Similarly, 70Zn (0.6%), with a half life of 1.3×1016 a is not usually considered to be radioactive. The other isotopes found in nature are 66Zn (28%), 67Zn (4%) and 68Zn (19%).

Several dozen radioisotopes have been characterized. 65Zn, which has a half-life of 243.66 days, is the most long-lived isotope, followed by 72Zn with a half-life of 46.5 hours.[20] Zinc has 10 nuclear isomers. 69mZn has the longest half-life, 13.76 h.[20] The superscript m indicates a metastable isotope. The nucleus of a metastable isotope is in an excited state and will return to the ground state by emitting a photon in the form of a gamma ray. 61Zn has three excited states and 73Zn has two.[23] The isotopes 65Zn, 71Zn, 77Zn and 78Zn each have only one excited state.[20]

The most common decay mode of a radioisotope of zinc with a mass number lower than 66 is electron capture. The decay product resulting from electron capture is an isotope of copper.[20]

n30Zn + en29Cu

The most common decay mode of a radioisotope of zinc with mass number higher than 66 is beta decay), which produces an isotope of gallium.[20]

n30Znn31Ga + e + νe

Creation

Zinc is too large and heavy to form in stars using the silicon burning process. The stable form of zinc is created in supernovas via the r-process.

Compounds and chemistry

Reactivity

Zinc has an electron configuration of [Ar]3d104s2 and is a member of the group 12 of the periodic table. It is a moderately reactive metal and strong reducing agent.[24] The surface of the pure metal tarnishes quickly, eventually forming a protective passivating layer of the basic zinc carbonate, Zn5(OH)6CO3, by reaction with atmospheric carbon dioxide.[25] This layer helps prevent further reaction with air and water.

Zinc burns in air with a bright bluish-green flame, giving off fumes of zinc oxide.[26] Zinc reacts readily with acids, alkalis and other non-metals.[27] Extremely pure zinc reacts only slowly at room temperature with acids.[26] Strong acids, such as hydrochloric or sulfuric acid, can remove the passivating layer and subsequent reaction with water releases hydrogen gas.[26]

The chemistry of zinc is dominated by the +2 oxidation state. When compounds in this oxidation state are formed the outer shell s electrons are lost, which yields a bare zinc ion with the electronic configuration [Ar]3d10.[28] This allows for the formation of four covalent bonds by accepting four electron pairs and thus obeying the octet rule. The stereochemistry is therefore tetrahedral and the bonds may be described as being formed from sp3 hybrid orbitals on the zinc ion.[29] In aqueous solution an octahedral complex, [Zn(H2O)6]2+ is the predominant species.[30] The volatilization of zinc in combination with zinc chloride at temperatures above 285 °C indicates the formation of Zn2Cl2, a zinc compound with a +1 oxidation state.[26] No compounds of zinc in oxidation states other than +1 or +2 are known.[31] Calculations indicate that a zinc compound with the oxidation state of +4 is unlikely to exist.[32]

Zinc chemistry is similar to the chemistry of the late first-row transition metals, nickel and copper though it has a filled d-shell, so its compounds are diamagnetic and mostly colorless.[33] The ionic radii of zinc and magnesium happen to be nearly identical. Because of this some of their salts have the same crystal structure[34] and in circumstances where ionic radius is a determining factor zinc and magnesium chemistries have much in common.[26] Otherwise there is little similarity. Zinc tends to form bonds with a greater degree of covalency and it forms much more stable complexes with N- and S- donors.[33] Complexes of zinc are mostly 4- or 6- coordinate although 5-coordinate complexes are known.[26]

See also Clemmensen reduction.

Compounds

White lumped powder on a glass plate
Zinc chloride
Sheets of zinc acetate formed by slow evaporation
Zinc acetate

Binary compounds of zinc are known for most of the metalloids and all the nonmetals except the noble gases. The oxide ZnO is a white powder that is nearly insoluble in neutral aqueous solutions, but is amphoteric, dissolving in both strong basic and acidic solutions.[26] The other chalcogenides (ZnS, ZnSe, and ZnTe) have varied applications in electronics and optics.[35] Pnictogenides (Zn3N2, Zn3P2, Zn3As2 and Zn3Sb2),[36][37] the peroxide (ZnO2), the hydride (ZnH2), and the carbide (ZnC2) are also known.[38] Of the four halides, ZnF2 has the most ionic character, whereas the others (ZnCl2, ZnBr2, and ZnI2) have relatively low melting points and are considered to have more covalent character.[39]

Skeletal chemical formula of a three-dimensional compound, featuring oxygen atom in the center, bonded to four Zn atoms. The latter are interconnected through oxygens and O-C-O groups.
Basic zinc acetate

In weak basic solutions containing Zn2+ ions, the hydroxide Zn(OH)2 forms as a white precipitate. In stronger alkaline solutions, this hydroxide is dissolved to form zincates ([Zn(OH)4]2−).[26] The nitrate Zn(NO3)2, chlorate Zn(ClO3)2, sulfate ZnSO4, phosphate Zn3(PO4)2, molybdate ZnMoO4, cyanide Zn(CN)2, arsenite Zn(AsO2)2, arsenate Zn(AsO4)2·8H2O and the chromate ZnCrO4 (one of the few colored zinc compounds) are a few examples of other common inorganic compounds of zinc.[40][41] One of the simplest examples of an organic compound of zinc is the acetate (Zn(O2CCH3)2).

Organozinc compounds are those that contain zinc–carbon covalent bonds. Diethylzinc ((C2H5)2Zn) is a reagent in synthetic chemistry. It was first reported in 1848 from the reaction of zinc and ethyl iodide, and was the first compound known to contain a metal–carbon sigma bond.[42] Decamethyldizincocene contains a strong zinc–zinc bond at room temperature.[43]

History

Ancient use

Large black bowl-shaped bucket on a stand. The bucket has incrustation around its top.
Late Roman brass bucket – the Hemmoorer Eimer from Warstade, Germany second to third century AD

Various isolated examples of the use of impure zinc in ancient times have been discovered. A possibly prehistoric statuette containing 87.5% zinc was found in a Dacian archaeological site in Transylvania (modern Romania).[44] Ornaments made of alloys that contain 80–90% zinc with lead, iron, antimony, and other metals making up the remainder, have been found that are 2500 years old.[11] The Berne zinc tablet is a votive plaque dating to Roman Gaul made of an alloy that is mostly zinc.[45] Also, some ancient writings appear to mention zinc. The Greek historian Strabo, in a passage taken from an earlier writer of the 4th century BC, mentions "drops of false silver", which when mixed with copper make brass. This may refer to small quantities of zinc produced as a by-product of smelting sulfide ores.[46] The Charaka Samhita, thought to have been written in 500 BC or before, mentions a metal which, when oxidized, produces pushpanjan, thought to be zinc oxide.[47]

Zinc ores were used to make the zinc–copper alloy brass many centuries prior to the discovery of zinc as a separate element. Palestinian brass from the 14th to 10th centuries BC contains 23% zinc.[48] The Book of Genesis, written between the 10th and 5th centuries BC,[49] mentions (in the King James translation) Tubal-cain as an "instructor in every artificer in brass and iron" (Genesis 4:22), but since the word nechosheth, translated as "brass", also means "copper", the significance of this is not clear. Knowledge of how to produce brass spread to Ancient Greece by the 7th century BC but few varieties were made.[50]

The manufacture of brass was known to the Romans by about 30 BC.[51] They made brass by heating powdered calamine (zinc silicate or carbonate), charcoal and copper together in a crucible.[51] The resulting calamine brass was then either cast or hammered into shape and was used in weaponry.[52] Some coins struck by Romans in the Christian era are made of what is probably calamine brass.[53] In the West, impure zinc was known from antiquity to exist in the remnants in melting ovens, but it was usually discarded, as it was thought to be worthless.[54]

Zinc mines at Zawar, near Udaipur in India, have been active since the Mauryan period in the late 1st millennium BC. The smelting of metallic zinc here however appears to have begun around the 12th century AD.[55][56] One estimate is that this location produced an estimated million tonnes of metallic zinc and zinc oxide from the 12th to 16th centuries.[13] Another estimate gives a total production of 60,000 tons of metallic zinc over this period.[55] The Rasaratna Samuccaya, written in approximately the 14th century AD, mentions two types of zinc-containing ores; one used for metal extraction and another used for medicinal purposes.[56]

Early studies and naming

Zinc was distinctly recognized as a metal under the designation of Fasada in the medical Lexicon ascribed to the Hindu king Madanapala and written about the year 1374.[57] Smelting and extraction of impure zinc by reducing calamine with wool and other organic substances was accomplished in the 13th century in India.[4][58] The Chinese did not learn of the technique until the 17th century.[58]

Various alchemical symbols attributed to the element zinc

Alchemists burned zinc metal in air and collected the resulting zinc oxide on a condenser. Some alchemists called this zinc oxide lana philosophica, Latin for "philosopher's wool", because it collected in wooly tufts while others thought it looked like white snow and named it nix album.[59]

The name of the metal was probably first documented by Paracelsus, a Swiss-born German alchemist, who referred to the metal as "zincum" or "zinken" in his book Liber Mineralium II, in the 16th century.[58][60] The word is probably derived from the German zinke, and supposedly meant "tooth-like, pointed or jagged" (metallic zinc crystals have a needle-like appearance).[61] Zink could also imply "tin-like" because of its relation to German zinn meaning tin.[62] Yet another possibility is that the word is derived from the Persian word سنگ seng meaning stone.[63] The metal was also called Indian tin, tutanego, calamine, and spinter.[11]

German metallurgist Andreas Libavius received a quantity of what he called "calay" of Malabar from a cargo ship captured from the Portuguese in 1596.[64] Libavius described the properties of the sample, which may have been zinc. Zinc was regularly imported to Europe from the Orient in the 17th and early 18th centuries,[58] but was at times very expensive.[note 1]

Isolation of the pure element

Picture of an old man head (profile). The mand has long face, short hair and tall forehead.
Credit for first isolating pure zinc is usually given to Andreas Sigismund Marggraf.

The isolation of metallic zinc in the West may have been achieved independently by several people. Postlewayt's Universal Dictionary, a contemporary source giving technological information in Europe, did not mention zinc before 1751 but the element was studied before then.[56][65]

Flemish metallurgist P.M. de Respour reported that he extracted metallic zinc from zinc oxide in 1668.[13] By the turn of the century, Étienne François Geoffroy described how zinc oxide condenses as yellow crystals on bars of iron placed above zinc ore being smelted.[13] In Britain, John Lane is said to have carried out experiments to smelt zinc, probably at Landore, prior to his bankruptcy in 1726.[66]

In 1738, William Champion patented in Great Britain a process to extract zinc from calamine in a vertical retort style smelter.[67] His technology was somewhat similar to that used at Zawar zinc mines in Rajasthan but there is no evidence that he visited the Orient.[68] Champion's process was used through 1851.[58]

German chemist Andreas Marggraf normally gets credit for discovering pure metallic zinc even though Swedish chemist Anton von Swab distilled zinc from calamine four years before.[58] In his 1746 experiment, Marggraf heated a mixture of calamine and charcoal in a closed vessel without copper to obtain a metal.[54] This procedure became commercially practical by 1752.[69]

Later work

William Champion's brother, John, patented a process in 1758 for calcining zinc sulfide into an oxide usable in the retort process.[11] Prior to this only calamine could be used to produce zinc. In 1798, Johann Christian Ruberg improved on the smelting process by building the first horizontal retort smelter.[70] Jean-Jacques Daniel Dony built a different kind of horizontal zinc smelter in Belgium, which processed even more zinc.[58]

Painting of a middle-aged man sitting by the table, wearing a wig, black jacket, white shirt and white scarf.
Galvanization was named for Luigi Galvani.

Italian doctor Luigi Galvani discovered in 1780 that connecting the spinal cord of a freshly dissected frog to an iron rail attached by a brass hook caused the frog's leg to twitch.[71] He incorrectly thought he had discovered an ability of nerves and muscles to create electricity and called the effect "animal electricity".[72] The galvanic cell and the process of galvanization were both named for Luigi Galvani and these discoveries paved the way for electrical batteries, galvanization and cathodic protection.[72]

Galvani's friend, Alessandro Volta, continued researching this effect and invented the Voltaic pile in 1800.[71] The basic unit of Volta's pile was a simplified galvanic cell, which is made of a plate of copper and a plate of zinc connected to each other externally and separated by an electrolyte. These were stacked in series to make the Voltaic cell, which in turn produced electricity by directing electrons from the zinc to the copper and allowing the zinc to corrode.[71]

The non-magnetic character of zinc and its lack of color in solution delayed discovery of its importance to biochemistry and nutrition.[73] This changed in 1940 when carbonic anhydrase, an enzyme that scrubs carbon dioxide from blood, was shown to have zinc in its active site.[73] The digestive enzyme carboxypeptidase became the second known zinc-containing enzyme in 1955.[73]

Production

Mining and processing

Zinc is the fourth most common metal in use, trailing only iron, aluminium, and copper with an annual production of about 10 megatonnes.[74] The world's largest zinc producer is Nyrstar, a merger of the Australian OZ Minerals and the Belgian Umicore.[75] About 70% of the world's zinc originates from mining, while the remaining 30% comes from recycling secondary zinc.[76] Commercially pure zinc is known as Special High Grade, often abbreviated SHG, and is 99.995% pure.[77]

Worldmap reviealing that about 40% of zinc is produced in China, 20% in Australia, 20% in Peru, and 5% in US, Canada and Kazakhstan each.
Percentage of zinc output in 2006 by countries[78]

Worldwide, 95% of the zinc is mined from sulfidic ore deposits, in which sphalerite ZnS is nearly always mixed with the sulfides of copper, lead and iron.[79] There are zinc mines throughout the world, with the main mining areas being China, Australia and Peru.[74] China produced over one-fourth of the global zinc output in 2006.[74]

Zinc metal is produced using extractive metallurgy.[80] After grinding the ore, froth flotation, which selectively separates minerals from gangue by taking advantage of differences in their hydrophobicity, is used to get an ore concentrate.[80] A final concentration of zinc of about 50% is reached by this process with the remainder of the concentrate being sulfur (32%), iron (13%), and SiO2 (5%).[80]

Roasting converts the zinc sulfide concentrate produced during processing to zinc oxide:[79]

2 ZnS + 3 O2 → 2 ZnO + 2 SO2
Top 5 zinc producing countries in 2009[81]
Rank Country tonnes
1 People's Republic of China China (PRC) 2,875,000
2 Peru Peru 1,439,000
3 Australia Australia 1,279,000
4 United States United States 735,000
5 Canada Canada 695,000

The sulfur dioxide is used for the production of sulfuric acid, which is necessary for the leaching process. If deposits of zinc carbonate, zinc silicate or zinc spinel, like the Skorpion Deposit in Namibia are used for zinc production the roasting can be omitted.[82]

For further processing two basic methods are used: pyrometallurgy or electrowinning. Pyrometallurgy processing reduces zinc oxide with carbon or carbon monoxide at 950 °C (1,740 °F) into the metal, which is distilled as zinc vapor.[83] The zinc vapor is collected in a condenser.[79] The below set of equations demonstrate this process:[79]

2 ZnO + C → 2 Zn + CO2
2 ZnO + 2 CO → 2 Zn + 2 CO2

Electrowinning processing leaches zinc from the ore concentrate by sulfuric acid:[84]

ZnO + H2SO4ZnSO4 + H2O

After this step electrolysis is used to produce zinc metal.[79]

2 ZnSO4 + 2 H2O → 2 Zn + 2 H2SO4 + O2

The sulfuric acid regenerated is recycled to the leaching step.

Environmental impact

The production for sulfidic zinc ores produces large amounts of sulfur dioxide and cadmium vapor. Smelter slag and other residues of process also contain significant amounts of heavy metals. About 1.1 megatonnes of metallic zinc and 130 kilotonnes of lead were mined and smelted in the Belgian towns of La Calamine and Plombières between 1806 and 1882.[85] The dumps of the past mining operations leach significant amounts of zinc and cadmium, and, as a result, the sediments of the Geul River contain significant amounts of heavy metals.[85] About two thousand years ago emissions of zinc from mining and smelting totaled 10 kilotonnes a year. After increasing 10-fold from 1850, zinc emissions peaked at 3.4 megatonnes per year in the 1980s and declined to 2.7 megatonnes in the 1990s, although a 2005 study of the Arctic troposphere found that the concentrations there did not reflect the decline. Anthropogenic and natural emissions occur at a ratio of 20 to 1.[86]

Levels of zinc in rivers flowing through industrial or mining areas can be as high as 20 ppm.[87] Effective sewage treatment greatly reduces this; treatment along the Rhine, for example, has decreased zinc levels to 50 ppb.[87] Concentrations of zinc as low as 2 ppm adversely affects the amount of oxygen that fish can carry in their blood.[88]

A panorama featuring a large industrial plant on a sea side, in front of mountains.
The zinc works at Lutana, is the largest exporter in Tasmania, generating 2.5% of the state's GDP. It produces over 250 kilotonnes of zinc per year.[89] The zinc works were historically responsible for high heavy metal levels in the Derwent River[90]

Soils contaminated with zinc through the mining of zinc-containing ores, refining, or where zinc-containing sludge is used as fertilizer, can contain several grams of zinc per kilogram of dry soil.[87] Levels of zinc in excess of 500 ppm in soil interfere with the ability of plants to absorb other essential metals, such as iron and manganese.[87] Zinc levels of 2000 ppm to 180,000 ppm (18%) have been recorded in some soil samples.[87]

Applications

The main end-uses for zinc are as follows[81]:

  1. Galvanizing: 59% - cars and construction
  2. Diecasting: 16% - motor housings, door furniture, toys
  3. Brass & Bronze: 10% - taps and pipes
  4. Rolled zinc: 6.5% - roofing and guttering in some parts of Europe, coffins in southern Europe, and batteries
  5. Chemicals: 6.0% - tyres and zinc cream
  6. Miscellaneous: 2.5% - includes dust in batteries

Anti-corrosion and batteries

Merged elongated crystals of various shades of gray.
Crystalline surface of a hot-dip galvanized handrail

The metal is most commonly used as an anti-corrosion agent.[91] Galvanization, which is the coating of iron or steel to protect the metals against corrosion, is the most familiar form of using zinc in this way. In 2006 in the United States, 56% or 773 kilotonnes of the zinc metal was used for galvanization,[92] while worldwide 47% was used for this purpose.[93]

Zinc is more reactive than iron or steel and thus will attract almost all local oxidation until it completely corrodes away.[94] A protective surface layer of oxide and carbonate (Zn5(OH)6(CO3)2) forms as the zinc corrodes.[95] This protection lasts even after the zinc layer is scratched but degrades through time as the zinc corrodes away.[95] The zinc is applied electrochemically or as molten zinc by hot-dip galvanizing or spraying.[10] Galvanization is used on chain-link fencing, guard rails, suspension bridges, lightposts, metal roofs, heat exchangers, and car bodies.[10]

The relative reactivity of zinc and its ability to attract oxidation to itself also makes it a good sacrificial anode in cathodic protection. Cathodically protecting (CP) buried pipelines requires a solid piece of zinc to be connected by a conductor to a steel pipe.[95] Zinc acts as the anode (negative terminus) by slowly corroding away as it passes electric current to the steel pipeline.[95][note 2] Zinc is also used to cathodically protect metals that are exposed to sea water from corrosion.[96] A zinc disc attached to a ship's iron rudder will slowly corrode while the rudder stays unattacked.[94] Other similar uses include a plug of zinc attached to a propeller or the metal protective guard for the keel of the ship.

With a standard electrode potential of −0.76 volts, zinc is used as an anode material for batteries. (More reactive lithium (SEP -3.04 V) is used for anodes in lithium batteries ). Powdered zinc is used in this way in alkaline batteries and sheets of zinc metal form the cases for and act as anodes in zinc–carbon batteries.[97][98] Zinc is used as the anode or fuel of the zinc-air battery/fuel cell.[99][100][101]

Alloys

A widely used alloy which contains zinc is brass, in which copper is alloyed with anywhere from 3% to 45% zinc, depending upon the type of brass.[95] Brass is generally more ductile and stronger than copper and has superior corrosion resistance.[95] These properties make it useful in communication equipment, hardware, musical instruments, and water valves.[95]

A mosaica pattern composed of components having various shapes and shades of brown .
Microstructure of cast brass at magnification 400x

Other widely used alloys that contain zinc include nickel silver, typewriter metal, soft and aluminium solder, and commercial bronze.[4] Zinc is also used in contemporary pipe organs as a substitute for the traditional lead/tin alloy in pipes.[102] Alloys of 85–88% zinc, 4–10% copper, and 2–8% aluminium find limited use in certain types of machine bearings. Zinc is the primary metal used in making American one cent coins since 1982.[103] The zinc core is coated with a thin layer of copper to give the impression of a copper coin. In 1994, 33,200 tonnes (36,600 short tons) of zinc were used to produce 13.6 billion pennies in the United States.[104]

Alloys of primarily zinc with small amounts of copper, aluminium, and magnesium are useful in die casting as well as spin casting, especially in the automotive, electrical, and hardware industries.[4] These alloys are marketed under the name Zamak.[105] An example of this is zinc aluminium. The low melting point together with the low viscosity of the alloy makes the production of small and intricate shapes possible. The low working temperature leads to rapid cooling of the cast products and therefore fast assembly is possible.[4][93][106] Another alloy, marketed under the name Prestal, contains 78% zinc and 22% aluminium and is reported to be nearly as strong as steel but as malleable as plastic.[4][107] This superplasticity of the alloy allows it to be molded using die casts made of ceramics and cement.[4]

Similar alloys with the addition of a small amount of lead can be cold-rolled into sheets. An alloy of 96% zinc and 4% aluminium is used to make stamping dies for low production run applications for which ferrous metal dies would be too expensive.[108] In building facades, roofs or other applications in which zinc is used as sheet metal and for methods such as deep drawing, roll forming or bending, zinc alloys with titanium and copper are used.[109] Unalloyed zinc is too brittle for these kinds of manufacturing processes.[109]

Cadmium zinc telluride (CZT) is a semiconductive alloy that can be divided into an array of small sensing devices.[110] These devices are similar to an integrated circuit and can detect the energy of incoming gamma ray photons.[110] When placed behind an absorbing mask, the CZT sensor array can also be used to determine the direction of the rays.[110]

Other industrial uses

White powder on a glass plate.
Zinc oxide is used as a white pigment in paints.

Roughly one quarter of all zinc output, in the United States (2006), is consumed in the form of zinc compounds;[92] a variety of which are used industrially. Zinc oxide is widely used as a white pigment in paints, and as a catalyst in the manufacture of rubber.[10] It is also used as a heat disperser for the rubber and acts to protect its polymers from ultraviolet radiation (the same UV protection is conferred to plastics containing zinc oxide).[10] The semiconductor properties of zinc oxide make it useful in varistors and photocopying products.[111] The zinc zinc-oxide cycle is a two step thermochemical process based on zinc and zinc oxide for hydrogen production.[112]

Zinc chloride is often added to lumber as a fire retardant[113] and can be used as a wood preservative.[114] It is also used to make other chemicals.[113] Zinc methyl (Zn(CH3)2) is used in a number of organic syntheses.[115] Zinc sulfide (ZnS) is used in luminescent pigments such as on the hands of clocks, X-ray and television screens, and luminous paints.[116] Crystals of ZnS are used in lasers that operate in the mid-infrared part of the spectrum.[117] Zinc sulfate is a chemical in dyes and pigments.[113] Zinc pyrithione is used in antifouling paints.[118]

Zinc powder is sometimes used as a propellant in model rockets.[119] When a compressed mixture of 70% zinc and 30% sulfur powder is ignited there is a violent chemical reaction.[119] This produces zinc sulfide, together with large amounts of hot gas, heat, and light.[119] Zinc sheet metal is used to make zinc bars.[120]

Zinc has been proposed as a salting material for nuclear weapons (cobalt is another, better-known salting material).[121] A jacket of isotopically enriched 64Zn, irradiated by the intense high-energy neutron flux from an exploding thermonuclear weapon, would transmute into the radioactive isotope 65Zn with a half-life of 244 days and produce massive gamma radiation, significantly increasing the radioactivity of the weapon's fallout for several days.[121] Such a weapon is not known to have ever been built, tested, or used.[121] 65Zn is also used as a tracer to study how alloys that contain zinc wear out, or the path and the role of zinc in organisms.[122]

Zinc dithiocarbamate complexes are used as agricultural fungicides; these include Zineb, Metiram, Propineb and Ziram.[123] Zinc naphthenate is used as wood preservative.[124] Zinc, in the form of ZDDP, is also used as an anti-wear additive for metal parts in engine oil.[125]

Medicine

Zinc is included in most single tablet over-the-counter daily vitamin and mineral supplements.[126] It is believed to possess antioxidant properties, which protect against premature aging of the skin and muscles of the body, although studies differ as to its effectiveness.[127] Zinc also helps speed up the healing process after an injury.[127]

The efficacy of zinc compounds when used to reduce the duration or severity of cold symptoms is controversial.[128] Zinc gluconate glycine and zinc acetate are used in throat lozenges or tablets to reduce the duration and the severity of cold symptoms.[129] Preparations include zinc oxide, zinc acetate, and zinc gluconate.[126]

Skeletal chemical formula of a planar compound featuring a Zn atom in the center, symmetrically bonded to four oxygens. Those oxygens are further connected to linear COH chains.
Zinc gluconate is one compound used for the delivery of zinc as a dietary supplement

Zinc preparations can protect against sunburn in the summer and windburn in the winter.[51] Applied thinly to a baby's diaper area (perineum) with each diaper change, it can protect against diaper rash.[51]

The Age-Related Eye Disease Study determined that zinc can be part of an effective treatment for age-related macular degeneration.[130] Zinc supplementation is an effective treatment for acrodermatitis enteropathica, a genetic disorder affecting zinc absorption that was previously fatal to babies born with it.[51]

Zinc lactate is used in toothpaste to prevent halitosis.[131] Zinc pyrithione is widely applied in shampoos because of its anti-dandruff function.[132] Zinc ions are effective antimicrobial agents even at low concentrations.[133] Gastroenteritis is strongly attenuated by ingestion of zinc, and this effect could be due to direct antimicrobial action of the zinc ions in the gastrointestinal tract, or to the absorption of the zinc and re-release from immune cells (all granulocytes secrete zinc), or both.[134][135][note 3]

Biological role

Zinc is an essential trace element, necessary for plants,[86] animals,[136] and microorganisms.[137] Zinc is found in nearly 100 specific enzymes[138] (other sources say 300), serves as structural ions in transcription factors and is stored and transferred in metallothioneins.[139] It is "typically the second most abundant transition metal in organisms" after iron and it is the only metal which appears in all enzyme classes.[86]

In proteins, Zn ions are often coordinated to the amino acid side chains of aspartic acid, glutamic acid, cysteine and histidine.[140] The theoretical and computational description of this zinc binding in proteins (as well as that of other transition metals) is difficult.[140]

There are 2–4 grams of zinc[141] distributed throughout the human body. Most zinc is in the brain, muscle, bones, kidney, and liver, with the highest concentrations in the prostate and parts of the eye.[142] Semen is particularly rich in zinc, which is a key factor in prostate gland function and reproductive organ growth.[143]

In humans, zinc plays "ubiquitous biological roles".[1] It interacts with "a wide range of organic ligands",[1] and has roles in the metabolism of RNA and DNA, signal transduction, and gene expression. It also regulates apoptosis. A 2006 study estimated that about 10% of human proteins (2800) potentially bind zinc, in addition to hundreds which transport and traffic zinc; a similar in silico study in the plant Arabidopsis thaliana found 2367 zinc-related proteins.[86]

In the brain, zinc is stored in specific synaptic vesicles by glutamatergic neurons[144] and can "modulate brain excitability".[1] It plays a key role in synaptic plasticity and so in learning.[145] However it has been called "the brain's dark horse"[144] since it also can be a neurotoxin, suggesting zinc homeostasis plays a critical role in normal functioning of the brain and central nervous system.[144]

Enzymes

Interconnected stripes, mostly of yellow and blue color with a few red segments.
Ribbon diagram of human carbonic anhydrase II, with zinc atom visible in the center

Zinc is a good Lewis acid, making it a useful catalytic agent in hydroxylation and other enzymatic reactions.[138] The metal also has a flexible coordination geometry, which allows proteins using it to rapidly shift conformations to perform biological reactions.[146] Two examples of zinc-containing enzymes are carbonic anhydrase and carboxypeptidase, which are vital to the processes of carbon dioxide (CO2) regulation and digestion of proteins, respectively.[147]

In vertebrate blood, carbonic anhydrase converts CO2 into bicarbonate and the same enzyme transforms the bicarbonate back into CO2 for exhalation through the lungs.[148] Without this enzyme, this conversion would occur about one million times slower[149] at the normal blood pH of 7 or would require a pH of 10 or more.[150] The non-related β-carbonic anhydrase is required in plants for leaf formation, the synthesis of indole acetic acid (auxin) and anaerobic respiration (alcoholic fermentation).[151]

Carboxypeptidase cleaves peptide linkages during digestion of proteins. A coordinate covalent bond is formed between the terminal peptide and a C=O group attached to zinc, which gives the carbon a positive charge. This helps to create a hydrophobic pocket on the enzyme near the zinc, which attracts the non-polar part of the protein being digested.[147]

Other proteins

Zinc serves a purely structural role in zinc fingers, twists and clusters.[152] Zinc fingers form parts of some transcription factors, which are proteins that recognize DNA base sequences during the replication and transcription of DNA. Each of the nine or ten Zn2+ ions in a zinc finger helps maintain the finger's structure by coordinately binding to four amino acids in the transcription factor.[149] The transcription factor wraps around the DNA helix and uses its fingers to accurately bind to the DNA sequence.

A twisted band, with one side painted blue and another gray. Its two ends are connected through some chemical species to a green atom (zinc).
Zinc fingers help read DNA sequences

In blood plasma, zinc is bound to and transported by albumin (60%, low-affinity) and transferrin (10%).[141] Since transferrin also transports iron, excessive iron reduces zinc absorption, and vice-versa. A similar reaction occurs with copper.[153] The concentration of zinc in blood plasma stays relatively constant regardless of zinc intake.[154] Cells in the salivary gland, prostate, immune system and intestine use zinc signaling as one way to communicate with other cells.[155]

Zinc may be held in metallothionein reserves within microorganisms or in the intestines or liver of animals.[156] Metallothionein in intestinal cells is capable of adjusting absorption of zinc by 15–40%.[157] However, inadequate or excessive zinc intake can be harmful; excess zinc particularly impairs copper absorption because metallothionein absorbs both metals.[158]

Reference ranges for blood tests, showing zinc in purple at center-right.

Dietary intake

Several plates full of various sereals, fruits and vegetables on a table.
Foods and spices that contain zinc

In the U.S., the Recommended Dietary Allowance (RDA) is 8 mg/day for women and 11 mg/day for men.[159] Median intake in the U.S. around 2000 was 9 mg/day for women and 14 mg/day in men.[159] Red meats, especially beef, lamb and liver have some of the highest concentrations of zinc in food.[143]

The concentration of zinc in plants varies based on levels of the element in soil. When there is adequate zinc in the soil, the food plants that contain the most zinc are wheat (germ and bran) and various seeds (sesame, poppy, alfalfa, celery, mustard).[160] Zinc is also found in beans, nuts, almonds, whole grains, pumpkin seeds, sunflower seeds and blackcurrant.[161]

Other sources include fortified food and dietary supplements, which come in various forms. A 1998 review concluded that zinc oxide, one of the most common supplements in the United States, and zinc carbonate are nearly insoluble and poorly absorbed in the body.[162] This review cited studies which found low plasma zinc concentrations after zinc oxide and zinc carbonate were consumed compared with those seen after consumption of zinc acetate and sulfate salts.[162] However, harmful excessive supplementation is a problem among the relatively affluent, and should probably not exceed 20 mg/day in healthy people,[163] although the U.S. National Research Council set a Tolerable Upper Intake of 40 mg/day.[164]

For fortification, however, a 2003 review recommended zinc oxide in cereals as cheap, stable, and as easily absorbed as more expensive forms.[165] A 2005 study found that various compounds of zinc, including oxide and sulfate, did not show statistically significant differences in absorption when added as fortificants to maize tortillas.[166] A 1987 study found that zinc picolinate was better absorbed than zinc gluconate or zinc citrate.[167]

Deficiency

Zinc deficiency is usually due to insufficient dietary intake, but can be associated with malabsorption, acrodermatitis enteropathica, chronic liver disease, chronic renal disease, sickle cell disease, diabetes, malignancy, and other chronic illnesses.[2] Symptoms of mild zinc deficiency are diverse.[159] Clinical outcomes include depressed growth, diarrhea, impotence and delayed sexual maturation, alopecia, eye and skin lesions, impaired appetite, altered cognition, impaired host defense properties, defects in carbohydrate utilization, and reproductive teratogenesis.[154] Mild zinc deficiency depresses immunity,[168] although excessive zinc does also.[141] Animals with a diet deficient in zinc require twice as much food in order to attain the same weight gain as animals given sufficient zinc.[116]

Groups at risk for zinc deficiency include the elderly, vegetarians, and those with renal insufficiency. The zinc chelator phytate, found in seeds and cereal bran, can contribute to zinc malabsorption in those with heavily vegetarian diets.[2] There is a paucity of adequate zinc biomarkers, and the most widely used indicator, plasma zinc, has poor sensitivity and specificity.[169] Diagnosing zinc deficiency is a persistent challenge.[1]

Nearly two billion people in the developing world are deficient in zinc.[2] In children it causes an increase in infection and diarrhea, contributing to the death of about 800,000 children worldwide per year.[1] The World Health Organization advocates zinc supplementation for severe malnutrition and diarrhea.[170] Zinc supplements help prevent disease and reduce mortality, especially among children with low birth weight or stunted growth.[170] However, zinc supplements should not be administered alone, since many in the developing world have several deficiencies, and zinc interacts with other micronutrients.[171]

Zinc deficiency is crop plants' most common micronutrient deficiency; it is particularly common in high-pH soils. Zinc-deficient soil is cultivated in the cropland of about half of Turkey and India, a third of China, and most of Western Australia, and substantial responses to zinc fertilization have been reported in these areas.[86] Plants that grow in soils that are zinc-deficient are more susceptible to disease. Zinc is primarily added to the soil through the weathering of rocks, but humans have added zinc through fossil fuel combustion, mine waste, phosphate fertilizers, limestone, manure, sewage sludge, and particles from galvanized surfaces. Excess zinc is toxic to plants, although zinc toxicity is far less widespread.[86]

Precautions

Toxicity

Although zinc is an essential requirement for good health, excess zinc can be harmful. Excessive absorption of zinc suppresses copper and iron absorption.[158] The free zinc ion in solution is highly toxic to plants, invertebrates, and even vertebrate fish.[172] The Free Ion Activity Model is well-established in the literature, and shows that just micromolar amounts of the free ion kills some organisms. A recent example showed 6 micromolar killing 93% of all Daphnia in water.[173]

The free zinc ion is a powerful Lewis acid up to the point of being corrosive. Stomach acid contains hydrochloric acid, in which metallic zinc dissolves readily to give corrosive zinc chloride. Swallowing a post-1982 American one cent piece (97.5% zinc) can cause damage to the stomach lining due to the high solubility of the zinc ion in the acidic stomach.[174]

There is evidence of induced copper deficiency at low intakes of 100–300 mg Zn/day; a recent trial had higher hospitalizations for urinary complications compared to placebo among elderly men taking 80 mg/day.[175] The USDA RDA is 15 mg Zn/day. Even lower levels, closer to the RDA, may interfere with the utilization of copper and iron or adversely affect cholesterol.[158] Levels of zinc in excess of 500 ppm in soil interfere with the ability of plants to absorb other essential metals, such as iron and manganese.[87] There is also a condition called the zinc shakes or "zinc chills" that can be induced by the inhalation of freshly formed zinc oxide formed during the welding of galvanized materials.[116]

The U.S. Food and Drug Administration (FDA) has stated that zinc damages nerve receptors in the nose, which can cause anosmia. Reports of anosmia were also observed in the 1930s when zinc preparations were used in a failed attempt to prevent polio infections.[176] On June 16, 2009, the FDA said that consumers should stop using zinc-based intranasal cold products and ordered their removal from store shelves. The FDA said the loss of smell can be life-threatening because people with impaired smell cannot detect leaking gas or smoke and cannot tell if food has spoiled before they eat it.[177] Recent research suggests that the topical antimicrobial zinc pyrithione is a potent heat shock response inducer that may impair genomic integrity with induction of PARP-dependent energy crisis in cultured human keratinocytes and melanocytes.[178]

Poisoning

In 1982, the United States Mint began minting pennies coated in copper but made primarily of zinc. With the new zinc pennies, there is the potential for zinc toxicosis, which can be fatal. One reported case of chronic ingestion of 425 pennies (over 1 kg of zinc) resulted in death due to gastrointestinal bacterial and fungal sepsis, while another patient, who ingested 12 grams of zinc, only showed lethargy and ataxia (gross lack of coordination of muscle movements).[179] Several other cases have been reported of humans suffering zinc intoxication by the ingestion of zinc coins.[180][181]

Pennies and other small coins are sometimes ingested by dogs, resulting in the need for medical treatment to remove the foreign body. The zinc content of some coins can cause zinc toxicity, which is commonly fatal in dogs, where it causes a severe hemolytic anemia, and also liver or kidney damage; vomiting and diarrhea are possible symptoms.[182] Zinc is highly toxic in parrots and poisoning can often be fatal.[183] The consumption of fruit juices stored in galvanized cans has resulted in mass parrot poisonings with zinc.[51]

See also

Notes

  1. An East India Company ship carrying a cargo of nearly pure zinc metal from the Orient sank off the coast Sweden in 1745.(Emsley 2001, p. 502)
  2. Electric current will naturally flow between zinc and steel but larger pipeline systems require a rectifier that adds an induced DC electric current to the CP system.
  3. In clinical trials, both zinc gluconate and zinc gluconate glycine (the formulation used in lozenges) have been shown to shorten the duration of symptoms of the common cold.
    Godfrey, J. C.; Godfrey, N. J.; Novick, S. G. (1996), "Zinc for treating the common cold: Review of all clinical trials since 1984", Alternative Therapies in Health and Medicine 2 (6): 63–72, PMID 8942045 
    The amount of glycine can vary from two to twenty moles per mole of zinc gluconate. One review of the research found that out of nine controlled experiments using zinc lozenges, the results were positive in four studies, and no better than placebo in five.
    Hulisz, Darrell T, "Zinc and the Common Cold: What Pharmacists Need to Know", US Pharmacist (uspharmacist.com), http://www.uspharmacist.com/oldformat.asp?url=newlook/files/alte/feat2.htm, retrieved 2008-11-28 
    This review also suggested that the research is characterized by methodological problems, including differences in the dosage amount used, and the use of self-report data. The evidence suggests that zinc supplements may be most effective if they are taken at the first sign of cold symptoms.

References

  1. 1.0 1.1 1.2 1.3 1.4 1.5 1.6 Hambidge, K. M. and Krebs, N. F. (2007), "Zinc deficiency: a special challenge", J. Nutr. 137 (4): 1101, PMID 17374687 
  2. 2.0 2.1 2.2 2.3 Prasad, A. S. (2003), "Zinc deficiency", British Medical Journal 326 (7386): 409, doi:10.1136/bmj.326.7386.409, PMID 12595353 
  3. Spelter, Encyclo, ISBN 0665822448, http://www.encyclo.co.uk/define/spelter, retrieved 2009-08-01 
  4. 4.0 4.1 4.2 4.3 4.4 4.5 4.6 4.7 4.8 4.9 CRC 2006, p. 4-41
  5. 5.0 5.1 Heiserman 1992, p. 123
  6. Lehto 1968, p. 826
  7. Scoffern, John (1861), The Useful Metals and Their Alloys, Houlston and Wright, pp. 591–603, http://books.google.com/?id=SSkKAAAAIAAJ, retrieved 2009-04-06 
  8. 8.0 8.1 Zinc Metal Properties, American Galvanizers Association, 2008, http://www.galvanizeit.org/aga/designing-fabricating/design-considerations/zinc-metal-properties, retrieved 2009-02-15 
  9. Ingalls, Walter Renton (1902), Production and Properties of Zinc: A Treatise on the Occurrence and Distribution of Zinc Ore, the Commercial and Technical Conditions Affecting the Production of the Spelter, Its Chemical and Physical Properties and Uses in the Arts, Together with a Historical and Statistical Review of the Industry, The Engineering and Mining Journal, pp. 142–6, http://books.google.com/?id=RhNDAAAAIAAJ&pg=PA133 
  10. 10.0 10.1 10.2 10.3 10.4 Emsley 2001, p. 503
  11. 11.0 11.1 11.2 11.3 11.4 Lehto 1968, p. 822
  12. 12.0 12.1 12.2 Greenwood 1997, p. 1202
  13. 13.0 13.1 13.2 13.3 Emsley 2001, p. 502
  14. 14.0 14.1 Tolcin, A. C. (2009) (PDF), Mineral Commodity Summaries 2009: Zinc, United States Geological Survey, http://minerals.er.usgs.gov/minerals/pubs/commodity/zinc/mcs-2009-zinc.pdf, retrieved 2008-11-25 
  15. Country Partnership Strategy—Iran: 2009-10, ECO Trade and development bank, http://www.etdb.org/StrategiesAndResearch/Countries/CSPReports/ReportsLibrary/IRAN.pdf, retrieved 2010-03-03 
  16. IRAN - a growing market with enormous potential, IMRG, July 5, 2010, http://www.iranconmin.de/en/leftnavigation/market, retrieved 2010-03-03 
  17. Cohen, David (2007), "Earth audit", New Scientist 194: 8, doi:10.1016/S0262-4079(07)61315-3 
  18. Augsberg University Calculate When Our Materials Run Out, IDTechEx, 2007-06-04, http://www.idtechex.com/products/en/articles/00000591.asp, retrieved 2008-12-09 
  19. Gordon, R. B.; Bertram, M.; Graedel, T. E. (2006), "Metal stocks and sustainability", Proceedings of the National Academy of Sciences 103 (5): 1209, doi:10.1073/pnas.0509498103, PMID 16432205 
  20. 20.0 20.1 20.2 20.3 20.4 20.5 NNDC contributors (2008), Alejandro A. Sonzogni (Database Manager), ed., Chart of Nuclides, Upton (NY): National Nuclear Data Center, Brookhaven National Laboratory, http://www.nndc.bnl.gov/chart/, retrieved 2008-09-13 
  21. CRC 2006, p. 11-70
  22. NASA contributors (PDF), Five-Year Wilkinson Microwave Anisotropy Probe (WMAP) Observations: Data Processing, Sky Maps, and Basic Results, NASA, http://lambda.gsfc.nasa.gov/product/map/dr3/pub_papers/fiveyear/basic_results/wmap5basic.pdf, retrieved 2008-03-06 
  23. Audi, Georges (2003), "The NUBASE Evaluation of Nuclear and Decay Properties", Nuclear Physics A (Atomic Mass Data Center) 729: 3–128, doi:10.1016/j.nuclphysa.2003.11.001 
  24. CRC 2006, pp. 8-29
  25. Porter, Frank C. (1994), Corrosion Resistance of Zinc and Zinc Alloys, CRC Press, p. 121, ISBN 0824792130 
  26. 26.0 26.1 26.2 26.3 26.4 26.5 26.6 26.7 Holleman, Arnold F.; Wiberg, Egon; Wiberg, Nils; (1985), "Zink" (in German), Lehrbuch der Anorganischen Chemie (91–100 ed.), Walter de Gruyter, pp. 1034–1041, ISBN 3110075113 
  27. Hinds, John Iredelle Dillard (1908), Inorganic Chemistry: With the Elements of Physical and Theoretical Chemistry (2nd ed.), New York: John Wiley & Sons, pp. 506–508, http://books.google.com/?id=xMUMAAAAYAAJ 
  28. Ritchie, Rob (2004), Chemistry (2nd ed.), Letts and Lonsdale, p. 71, ISBN 1843154382, http://books.google.com/?id=idT9j6406gsC 
  29. Jaffe, Howard W. (1996), Crystal Chemistry and Refractivity, Courier Dover Publications, p. 31, ISBN 048669173X, http://books.google.com/?id=lbxUYhC5YEEC 
  30. Burgess, John (1978), Metal ions in solution, New York: Ellis Horwood, p. 147, ISBN 0470262931 
  31. Brady, James E.; Humiston, Gerard E.; Heikkinen, Henry (1983), General Chemistry: Principles and Structure (3rd ed.), John Wiley & Sons, p. 671, ISBN 047186739X 
  32. Kaupp M.; Dolg M.; Stoll H.; Von Schnering H. G. (1994), "Oxidation state +IV in group 12 chemistry. Ab initio study of zinc(IV), cadmium(IV), and mercury(IV) fluorides", Inorganic chemistry 33: 2122, doi:10.1021/ic00088a012 
  33. 33.0 33.1 Greenwood 1997, p. 1206
  34. CRC 2006, pp. 12-11–12
  35. Zinc Sulfide, American Elements, http://www.americanelements.com/znsu.html, retrieved 2009-02-03 
  36. Grolier contributors (1994), Academic American Encyclopedia, Danbury, Connecticut: Grolier Inc, p. 202, ISBN 0717220532, http://books.google.com/?id=YgI4E7w5JI8C 
  37. Zinc Phosphide, American Elements, http://www.americanelements.com/znp.html, retrieved 2009-02-03 
  38. Shulzhenko, A. A.; Ignatyeva, I. Yu.; Osipov, A. S.; Smirnova, T. I. (2000), "Peculiarities of interaction in the Zn–C system under high pressures and temperatures", Diamond and Related Materials 9: 129, doi:10.1016/S0925-9635(99)00231-9 
  39. Greenwood 1997, p. 1211
  40. Rasmussen, J. K.; Heilmann, S. M. (1990), "In situ Cyanosilylation of Carbonyl Compounds: O-Trimethylsilyl-4-Methoxymandelonitrile", Organic Syntheses, Collected Volume 7: 521, http://www.orgsyn.org/orgsyn/prep.asp?prep=cv7p0521 
  41. Perry, D. L. (1995), Handbook of Inorganic Compounds, CRC Press, pp. 448–458, ISBN 0849386713 
  42. Frankland, E. (1850), "On the isolation of the organic radicals", Quarterly Journal of the Chemical Society 2: 263, doi:10.1039/QJ8500200263 
  43. Resa, I.; Carmona, E.; Gutierrez-Puebla, E.; Monge, A. (2004), "Decamethyldizincocene, a Stable Compound of Zn(I) with a Zn-Zn Bond", Science 304 (5687): 1136, doi:10.1126/science.1101356, PMID 15326350 
  44. Weeks 1933, p. 20
  45. Rehren, Th. (1996), S. Demirci et al, ed., A Roman zinc tablet from Bern, Switzerland: Reconstruction of the Manufacture, 94, Archaeometry, pp. 35–45 
  46. P. T. Craddock (1998), "Zinc in classical antiquity", in Craddock, P.T., 2000 years of zinc and brass (rev. ed.), London: British Museum, pp. 3–5, ISBN 0861591240 
  47. P. T. Craddock, I. C. Freestone, L. K. Gurjar, A. P. Middleton, and L. Willies (1998), "Zinc in India", in Craddock, P.T., 2000 years of zinc and brass (rev. ed.), London: British Museum, p. 27, ISBN 0861591240 
  48. Greenwood 1997, p. 1201
  49. Lerner, Gerda (2003), "Religion and the Creation of Feminist Consciousness", Harvard Divinity Bulletin 23 (1), http://www.hds.harvard.edu/news/bulletin/articles/lerner.html, retrieved 2009-04-06 
  50. Craddock, Paul T. (1978), "The composition of copper alloys used by the Greek, Etruscan and Roman civilizations. The origins and early use of brass", Journal of Archaeological Science 5: 1, doi:10.1016/0305-4403(78)90015-8 
  51. 51.0 51.1 51.2 51.3 51.4 51.5 Emsley 2001, p. 501
  52. "How is zinc made?", How Products are Made (The Gale Group), 2002, http://www.answers.com/zinc, retrieved 2009-02-21 
  53. Chambers 1901, p. 799
  54. 54.0 54.1 Weeks 1933, p. 21
  55. 55.0 55.1 p. 46, Ancient mining and metallurgy in Rajasthan, S. M. Gandhi, chapter 2 in Crustal Evolution and Metallogeny in the Northwestern Indian Shield: A Festschrift for Asoke Mookherjee, M. Deb, ed., Alpha Science Int'l Ltd., 2000, ISBN 1842650017.
  56. 56.0 56.1 56.2 Craddock, P. T.; Gurjar L. K.; Hegde K. T. M. (1983), "Zinc production in medieval India", World Archaeology (Taylor & Francis, Ltd.) 15 (2): 211, http://www.jstor.org/pss/124653 
  57. Ray, Prafulla Chandra (1903), A History of Hindu Chemistry from the Earliest Times to the Middle of the Sixteenth Century, A.D.: With Sanskrit Texts, Variants, Translation and Illustrations, 1 (2nd ed.), The Bengal Chemical & Pharmaceutical Works, Ltd, pp. 157–158, http://books.google.com/?id=DL1HAAAAIAAJ&printsec=titlepage  (public domain text)
  58. 58.0 58.1 58.2 58.3 58.4 58.5 58.6 Habashi, Fathi (PDF), Discovering the 8th Metal, International Zinc Association (IZA), http://www.iza.com/Documents/Communications/Publications/History.pdf, retrieved 2008-12-13 
  59. Arny, Henry Vinecome (1917), Principles of Pharmacy (2nd ed.), W. B. Saunders company, p. 483, http://books.google.com/?id=gRNKAAAAMAAJ 
  60. Hoover, Herbert Clark (2003), Georgius Agricola de Re Metallica, Kessinger Publishing, p. 409, ISBN 0766131971 
  61. Gerhartz, Wolfgang; et al. (1996), Ullmann's Encyclopedia of Industrial Chemistry (5th ed.), VHC, p. 509, ISBN 3527201009 
  62. Skeat, W. W (2005), Concise Etymological Dictionary of the English Language, Cosimo, Inc., p. 622, ISBN 1596050926, http://books.google.com/?id=ls_XijT33IUC&pg=PA622 
  63. Fathi Habashi (1997), Handbook of Extractive Metallurgy, Wiley-VHC, p. 642, ISBN 3527287922 
  64. Lach, Donald F. (1994), "Technology and the Natural Sciences", Asia in the Making of Europe, University of Chicago Press, p. 426, ISBN 0226467341, http://books.google.com/?id=N0xD7BYXv_YC&pg=PA426 
  65. Lynn Willies, P. T. Craddock, L. J. Gurjar and K. T. M. Hedge World Archaeology (1984), "Ancient Lead and Zinc Mining in Rajasthan, India", World Archaeology (Taylor & Francis, Ltd.) 16 (2, Mines and Quarries): 222, http://www.jstor.org/stable/124574 
  66. Roberts, R. O. (1951), "Dr John Lane and the foundation of the non-ferrous metal industry in the Swansea valley", Gower (Gower Society) (4): 19 
  67. Comyns, Alan E. (2007), Encyclopedic Dictionary of Named Processes in Chemical Technology (3rd ed.), CRC Press, p. 71, ISBN 0849391636, http://books.google.com/?id=Jlq-ckWvQSQC 
  68. Jenkins, Rhys (1945–7), "The Zinc Industry in England: the early years up to 1850", Transactions of the Newcomen Society 25: 41–52 
  69. Heiserman 1992, p. 122
  70. Gray, Leon (2005), Zinc, Marshall Cavendish, p. 8, ISBN 0761419225 
  71. 71.0 71.1 71.2 Warren, Neville G. (2000), Excel Preliminary Physics, Pascal Press, p. 47, ISBN 1740200853, http://books.google.com/?id=eL9Xn6nQ6XQC&printsec=frontcover 
  72. 72.0 72.1 "Galvanic Cell", The New International Encyclopaedia, Dodd, Mead and Company, 1903, p. 80, http://books.google.com/?id=gV1MAAAAMAAJ&pg=PA80 
  73. 73.0 73.1 73.2 Cotton 1999, p. 626
  74. 74.0 74.1 74.2 "Zinc: World Mine Production (zinc content of concentrate) by Country", 2006 Minerals Yearbook: Zinc (Washington, D.C.: United States Geological Survey): p. Table 15, February 2008, http://minerals.usgs.gov/minerals/pubs/commodity/zinc/myb1-2006-zinc.pdf, retrieved 2009-01-19 
  75. Pearson, Madelene; Ann, Tan Hwee (December 12, 2006), "Zinifex and Umicore to create largest zinc producer", Bloomberg News (International Herald Tribune), http://www.iht.com/articles/2006/12/12/bloomberg/sxzini.php, retrieved 2008-11-24 
  76. Zinc Recycling, International Zinc Association, http://www.zincworld.org/recycling.html, retrieved 2008-11-28 
  77. (PDF) Special High Grade Zinc (SHG) 99.995%, Nyrstar, 2008, http://nyrstar.com/nyrstar/en/products/zinccongalvanising/techdownloads/shg_budel.pdf, retrieved 2008-12-01 
  78. Jasinski, Stephen M (PDF), Mineral Commodity Summaries 2007: Zinc, United States Geological Survey, http://minerals.er.usgs.gov/minerals/pubs/commodity/zinc/mcs-2008-zinc.pdf, retrieved 2008-11-25 
  79. 79.0 79.1 79.2 79.3 79.4 Porter, Frank C. (1991), Zinc Handbook, CRC Press, ISBN 9780824783402, http://books.google.com/?id=laACw9i0D_wC 
  80. 80.0 80.1 80.2 Rosenqvist, Terkel (1922), Principles of Extractive Metallurgy (2 ed.), Tapir Academic Press, pp. 7, 16, 186, ISBN 8251919223 
  81. 81.0 81.1 FACTBOX-The vital statistics of zinc, London: CRU Group, March 2010, http://communities.thomsonreuters.com/BaseMetals/500327, retrieved 2010-03-10 
  82. Borg, Gregor; Kärner, Katrin; Buxton, Mike; Armstrong, Richard; van der Merwe, Schalk W. (2003), "Geology of the Skorpion Supergene Zinc Deposit, Southern Namibia", Economic Geology 98: 749, doi:10.2113/98.4.749 
  83. Bodsworth, Colin (1994), The Extraction and Refining of Metals, CRC Press, p. 148, ISBN 0849344336 
  84. Gupta, C. K.; Mukherjee, T. K. (1990), Hydrometallurgy in Extraction Processes, CRC Press, p. 62, ISBN 0849368049 
  85. 85.0 85.1 Kucha, H.; Martens, A.; Ottenburgs, R.; De Vos, W.; Viaene, W. (1996), "Primary minerals of Zn-Pb mining and metallurgical dumps and their environmental behavior at Plombières, Belgium", Environmental Geology 27: 1, doi:10.1007/BF00770598 
  86. 86.0 86.1 86.2 86.3 86.4 86.5 Broadley, M. R.; White, P. J.; Hammond, J. P.; Zelko I.; Lux A. (2007), "Zinc in plants", New Phytologist 173 (4): 677, doi:10.1111/j.1469-8137.2007.01996.x, PMID 17286818 
  87. 87.0 87.1 87.2 87.3 87.4 87.5 Emsley 2001, p. 504
  88. Heath, Alan G. (1995), Water pollution and fish physiology, Boca Raton, Florida: CRC Press, p. 57, ISBN 0873716329, http://books.google.com/?id=5NPVTuBtGF4C 
  89. "The Zinc Works", TChange, http://www.tchange.com.au/resources/zinifex_smelter.html, retrieved 2009-07-11 
  90. Derwent Estuary - Water Quality Improvement Plan for Heavy Metals, Derwent Estuary Program, June 2007, http://www.derwentestuary.org.au/file.php?id=193, retrieved 2009-07-11 
  91. Greenwood 1997, p. 1203
  92. 92.0 92.1 Tolcin, Amy C (PDF), Mineral Yearbook 2006: Zinc, United States Geological Survey, http://minerals.usgs.gov/minerals/pubs/commodity/zinc/zinc_mcs06.pdf, retrieved 2009-04-06 
  93. 93.0 93.1 Panagapko, Doug (2006), Zinc, Natural Resources Canada, http://info.wlu.ca/~wwwgeog/special/vgt/English/can_mod2/unit7.htm, retrieved 2008-12-12 
  94. 94.0 94.1 Stwertka 1998, p. 99
  95. 95.0 95.1 95.2 95.3 95.4 95.5 95.6 Lehto 1968, p. 829
  96. Bounoughaz, M.; Salhi, E.; Benzine, K.; Ghali E.; Dalard F. (2003), "A comparative study of the electrochemical behaviour of Algerian zinc and a zinc from a commercial sacrificial anode", Journal of Materials Science 38: 1139, doi:10.1023/A:1022824813564 
  97. Besenhard, Jürgen O. (1999) (PDF), Handbook of Battery Materials, Wiley-VCH, ISBN 3527294694, http://www.ulb.tu-darmstadt.de/tocs/60178752.pdf, retrieved 2008-10-08 
  98. Wiaux, J. -P.; Waefler, J. -P. (1995), "Recycling zinc batteries: an economical challenge in consumer waste management", Journal of Power Sources 57: 61, doi:10.1016/0378-7753(95)02242-2 
  99. Culter, T. (1996), "A design guide for rechargeable zinc-air battery technology", Southcon/96. Conference Record: 616, doi:10.1109/SOUTHC.1996.535134 
  100. Whartman, Jonathan; Brown, Ian (PDF), Zinc Air Battery-Battery Hybrid for Powering Electric Scooters and Electric Buses, The 15th International Electric Vehicle Symposium, http://www.electric-fuel.com/evtech/papers/paper11-1-98.pdf, retrieved 2008-10-08 
  101. Cooper, J. F; Fleming, D.; Hargrove, D.; Koopman, R.; Peterman, K, A refuelable zinc/air battery for fleet electric vehicle propulsion, Society of Automotive Engineers future transportation technology conference and exposition, http://www.osti.gov/energycitations/product.biblio.jsp?osti_id=82465, retrieved 2008-10-08 
  102. Bush, Douglas Earl; Kassel, Richard (2006), The Organ: An Encyclopedia, Routledge, p. 679, ISBN 9780415941747, http://books.google.com/?id=cgDJaeFFUPoC 
  103. Coin Specifications, United States Mint, http://www.usmint.gov/about_the_mint/?action=coin_specifications, retrieved 2008-10-08 
  104. Jasinski, Stephen M (PDF), Mineral Yearbook 1994: Zinc, United States Geological Survey, http://minerals.usgs.gov/minerals/pubs/commodity/zinc/720494.pdf, retrieved 2008-11-13 
  105. Eastern Alloys contributors, Diecasting Alloys, Maybrook, NY: Eastern Alloys, http://www.eazall.com/diecastalloys.aspx, retrieved 2009-01-19 
  106. Apelian, D.; Paliwal, M.; Herrschaft, D. C. (1981), "Casting with Zinc Alloys", Journal of Metals 33: 12–19 
  107. Davies, Geoff (2003), Materials for automobile bodies, Butterworth-Heinemann, p. 157, ISBN 0750656921, http://books.google.com/?id=s0i32LSfrJ4C&pg=PA157 
  108. Samans, Carl Hubert (1949), Engineering Metals and Their Alloys, Macmillan Co 
  109. 109.0 109.1 Porter, Frank (1994), "Wrought Zinc", Corrosion Resistance of Zinc and Zinc Alloys, CRC Press, pp. 6–7, ISBN 9780824792138, http://books.google.com/?id=C-pAiedmqp8C 
  110. 110.0 110.1 110.2 Katz, Johnathan I. (2002), The Biggest Bangs, Oxford University Press, p. 18, ISBN 0195145704 
  111. Zhang, Xiaoge Gregory (1996), Corrosion and Electrochemistry of Zinc, Springer, p. 93, ISBN 0306453347, http://books.google.com/?id=Qmf4VsriAtMC 
  112. Weimer, Al (2006-05-17) (PDF), Development of Solar-powered Thermochemical Production of Hydrogen from Water, U.S. Department of Energy, http://www.hydrogen.energy.gov/pdfs/review06/pd_10_weimer.pdf, retrieved 2009-01-10 
  113. 113.0 113.1 113.2 Heiserman 1992, p. 124
  114. Blew, Joseph Oscar (1953), Wood preservatives, Department of Agriculture, Forest Service, Forest Products Laboratory, http://hdl.handle.net/1957/816 
  115. Frankland, Edward (1849), "Notiz über eine neue Reihe organischer Körper, welche Metalle, Phosphor u. s. w. enthalten" (in German), Liebig's Annalen der Chemie und Pharmacie 71: 213, doi:10.1002/jlac.18490710206 
  116. 116.0 116.1 116.2 CRC 2006, p. 4-42
  117. Paschotta, Rüdiger (2008), Encyclopedia of Laser Physics and Technology, Wiley-VCH, p. 798, ISBN 3527408282, http://books.google.com/?id=BN026ye2fJAC 
  118. Konstantinou, I. K.; Albanis, T. A. (2004), "Worldwide occurrence and effects of antifouling paint booster biocides in the aquatic environment: a review", Environment International 30: 235, doi:10.1016/S0160-4120(03)00176-4 
  119. 119.0 119.1 119.2 Boudreaux, Kevin A, Zinc + Sulfur, Angelo State University, http://www.angelo.edu/faculty/kboudrea/demos/zinc_sulfur/zinc_sulfur.htm, retrieved 2008-10-08 
  120. Technical Information, Zinc Counters, 2008, http://www.zinccounters.co.uk/html/tech/tech.htm, retrieved 2008-11-29 
  121. 121.0 121.1 121.2 Win, David Tin; Masum, Al (2003), "Weapons of Mass Destruction" (PDF), Assumption University Journal of Technology (Assumption University) 6 (4): 199, http://www.journal.au.edu/au_techno/2003/apr2003/aujt6-4_article07.pdf, retrieved 2009-04-06 
  122. David E. Newton (1999), Chemical Elements: From Carbon to Krypton, U. X. L. /Gale, ISBN 0787628468, http://www.encyclopedia.com/doc/1G2-3427000114.html, retrieved 2009-04-06 
  123. Ullmann's Agrochemicals, Wiley-Vch (COR), 2007, pp. 591–592, ISBN 3527316043, http://books.google.com/?id=cItuoO9zSjkC&pg=PA591 
  124. Walker, J. C. F. (2006), Primary Wood Processing: Principles and Practice, Springer, p. 317, ISBN 1402043929 
  125. ZDDP Engine Oil - The Zinc Factor, Mustang Monthly, http://www.mustangmonthly.com/techarticles/mump_0907_zddp_zinc_additive_engine_oil/index.html, retrieved 2009-09-19 
  126. 126.0 126.1 DiSilvestro, Robert A. (2004), Handbook of Minerals as Nutritional Supplements, CRC Press, pp. 135, 155, ISBN 0849316529 
  127. 127.0 127.1 Milbury, Paul E.; Richer, Alice C. (2008), Understanding the Antioxidant Controversy: Scrutinizing the "fountain of Youth", Greenwood Publishing Group, p. 99, ISBN 0275993760 
  128. "Zinc and Health : The Common Cold". Office of Dietary Supplements, National Institutes of Health. http://ods.od.nih.gov/factsheets/zinc.asp#h7. Retrieved 2010-05-01. 
  129. Ananda S., Prasad; Fitzgerald, James T.; Bao, Bin; Beck, Frances W.J.; Chandrasekar, Pranatharthi H. (2000), "Duration of Symptoms and Plasma Cytokine Levels in Patients with the Common Cold Treated with Zinc Acetate: A Randomized, Double-Blind, Placebo-Controlled Trial" (PDF), Annals of Internal Medicine 133 (4): 245, http://www.annals.org/cgi/reprint/133/4/245.pdf 
  130. Age-Related Eye Disease Study Research Group (2001), "A Randomized, Placebo-Controlled, Clinical Trial of High-Dose Supplementation With Vitamins C and E, Beta Carotene, and Zinc for Age-Related Macular Degeneration and Vision Loss", Arch Ophthalmology 119 (10): 1417, PMID 11594942, PMC 1462955, http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=11594942 
  131. Roldán, S.; Winkel, E. G.; Herrera, D.; Sanz, M.; Van Winkelhoff, A. J. (2003), "The effects of a new mouthrinse containing chlorhexidine, cetylpyridinium chloride and zinc lactate on the microflora of oral halitosis patients: a dual-centre, double-blind placebo-controlled study", Journal of Clinical Periodontology 30: 427, doi:10.1034/j.1600-051X.2003.20004.x 
  132. Marks, R.; Pearse, A. D.; Walker, A. P. (1985), "The effects of a shampoo containing zinc pyrithione on the control of dandruff", British Journal of Dermatology 112: 415, doi:10.1111/j.1365-2133.1985.tb02314.x 
  133. McCarthy, T J; Zeelie, J J: Krause, D J (1992 Feb), "The antimicrobial action of zinc ion/antioxidant combinations.", Clinical Pharmacology & Therapeutics (American Society for Clinical Pharmacology and Therapeutics) 17 (1): 5 
  134. Aydemir, T. B.; Blanchard, R. K.; Cousins, R. J. (2006), "Zinc Supplementation of Young Men Alters Metallothionein, Zinc Transporter, and Cytokine Gene Expression in Leucocyte Populations", PNAS 103 (6): 1699, doi:10.1073/pnas.0510407103, PMID 16434472 
  135. Valko, M.; Morris, H.; Cronin, M. T. D. (2005), "Metals, Toxicity and Oxidative stress", Current Medicinal Chemistry 12: 1161, doi:10.2174/0929867053764635 
  136. Prasad A. S. (2008), "Zinc in human health: effect of zinc on immune cells", Mol. Med. 14 (5-6): 353, doi:10.2119/2008-00033.Prasad, PMID 18385818 
  137. Zinc's role in microorganisms is particularly reviewed in: Sugarman B (1983), "Zinc and infection", Review of Infectious Diseases 5 (1): 137, PMID 6338570 
  138. 138.0 138.1 NRC 2000, p. 443
  139. Cotton 1999, pp. 625–629
  140. 140.0 140.1 Erik G. Brandt, Mikko Hellgren, Tore Brinck, Tomas Bergman and Olle Edholm (2009), "Molecular dynamics study of zinc binding to cysteines in a peptide mimic of the alcohol dehydrogenase structural zinc site", Phys. Chem. Chem. Phys. (PCCP) 11 (6): 975–83, doi:10.1039/b815482a, PMID 19177216 
  141. 141.0 141.1 141.2 Rink, L.; Gabriel P. (2000), "Zinc and the immune system", Proc Nutr Soc 59 (4): 541, doi:10.1017/S0029665100000781, PMID 11115789 
  142. Wapnir, Raul A. (1990), Protein Nutrition and Mineral Absorption, Boca Raton, Florida: CRC Press, ISBN 0849352274, http://books.google.com/?id=qfKdaCoZS18C 
  143. 143.0 143.1 Berdanier, Carolyn D.; Dwyer, Johanna T.; Feldman, Elaine B. (2007), Handbook of Nutrition and Food, Boca Raton, Florida: CRC Press, ISBN 0849392187, http://books.google.com/?id=PJpieIePsmUC 
  144. 144.0 144.1 144.2 Bitanihirwe BK, Cunningham MG (2009), "Zinc: The brain's dark horse", Synapse 63 (11): 1029, doi:10.1002/syn.20683, PMID 19623531 
  145. Nakashima AS, Dyck RH (2009), "Zinc and cortical plasticity", Brain Res Rev 59 (2): 347, doi:10.1016/j.brainresrev.2008.10.003, PMID 19026685 
  146. Stipanuk, Martha H. (2006), Biochemical, Physiological & Molecular Aspects of Human Nutrition, W. B. Saunders Company, pp. 1043–1067, ISBN 9780721644523 
  147. 147.0 147.1 Greenwood 1997, pp. 1224–1225
  148. Kohen, Amnon; Limbach, Hans-Heinrich (2006), Isotope Effects in Chemistry and Biology, Boca Raton, Florida: CRC Press, p. 850, ISBN 0824724496, http://books.google.com/?id=7EiIqrRBBQgC 
  149. 149.0 149.1 Greenwood 1997, p. 1225
  150. Cotton 1999, p. 627
  151. Gadallah, M. A. A. (2000), "Effects of indole-3-acetic acid and zinc on the growth, osmotic potential and soluble carbon and nitrogen components of soybean plants growing under water deficit", Journal of Arid Environments 44: 451, doi:10.1006/jare.1999.0610 
  152. Cotton 1997, p. 628
  153. Whitney, Eleanor Noss; Rolfes, Sharon Rady (2005), Understanding Nutrition (10th ed.), Thomson Learning, pp. 447–450, ISBN 9781428818934 
  154. 154.0 154.1 NRC 2000, p. 447
  155. Hershfinkel, Michal; Silverman, William F.; Sekler, Israel (2007), "The Zinc Sensing Receptor, a Link Between Zinc and Cell Signaling", Molecular Medicine 13 (7-8): 331, doi:10.1007/s10653-009-9255-4, PMID 17728842 
  156. Cotton 1999, p. 629
  157. Blake, Steve (2007), Vitamins and Minerals Demystified, McGraw-Hill Professional, p. 242, ISBN 0071489010 
  158. 158.0 158.1 158.2 Fosmire, G. J. (1990), "Zinc toxicity", American Journal of Clinical Nutrition 51 (2): 225, PMID 2407097, http://www.ajcn.org/cgi/content/abstract/51/2/225 
  159. 159.0 159.1 159.2 NRC 2000, p. 442
  160. Ensminger, Audrey H.; Konlande, James E. (1993), Foods & Nutrition Encyclopedia (2nd ed.), Boca Raton, Florida: CRC Press, pp. 2368–2369, ISBN 0849389801, http://books.google.com/?id=XMA9gYIj-C4C 
  161. "Zinc content of selected foods per common measure" (PDF), USDA National Nutrient Database for Standard Reference, Release 20 (United States Department of Agriculture), http://www.nal.usda.gov/fnic/foodcomp/Data/SR20/nutrlist/sr20w309.pdf, retrieved 2007-12-06 
  162. 162.0 162.1 Allen, Lindsay H. (1998), "Zinc and micronutrient supplements for children", American Journal of Clinical Nutrition 68 (2 Suppl): 495S, PMID 9701167, http://www.ajcn.org/cgi/reprint/68/2/495S 
  163. Maret, W.; Sandstead H. H. (2006), "Zinc requirements and the risks and benefits of zinc supplementation", Journal of Trace Elements in Medicine and Biology 20 (1): 3, doi:10.1016/j.jtemb.2006.01.006, PMID 16632171 
  164. "Zinc - Summary", Dietary Reference Intakes for Vitamin A, Vitamin K, Arsenic, Boron, Chromium, Copper, Iodine, Iron, Manganese, Molybdenum, Nickel, Silicon, Vanadium, and Zinc (2001) (Institute of Medicine, Food and Nutrition Board), http://books.nap.edu/openbook.php?record_id=10026&page=442, retrieved 2010-03-30 
  165. Rosado, J. L. (2003), "Zinc and copper: proposed fortification levels and recommended zinc compounds", Journal of Nutrition 133 (9): 2985S, PMID 12949397 
  166. Hotz, C.; DeHaene, J.; Woodhouse, L. R.; Villalpando, S.; Rivera, J. A.; King, J. C. (2005), "Zinc absorption from zinc oxide, zinc sulfate, zinc oxide + EDTA, or sodium-zinc EDTA does not differ when added as fortificants to maize tortillas", Journal of Nutrition 135 (5): 1102, PMID 15867288 
  167. Barrie, SA.; Wright JV, Pizzorno JE, Kutter E, Barron PC. (1987), "Comparative absorption of zinc picolinate, zinc citrate and zinc gluconate in humans", Agents Actions 21 (1-2): 223–8, doi:10.1007/BF01974946, PMID 3630857 
  168. Ibs, K. H.; Rink, L.; (2003), "Zinc-altered immune function", Journal of Nutrition 133 (5 Suppl 1): 1452S, PMID 12730441, http://jn.nutrition.org/cgi/pmidlookup?view=long&pmid=12730441 
  169. Hambidge, M. (2003), "Biomarkers of trace mineral intake and status", Journal of Nutrition 133 Suppl 3 (3): 948S, PMID 12612181, http://jn.nutrition.org/cgi/pmidlookup?view=long&pmid=12612181 
  170. 170.0 170.1 WHO contributors (2007) (PDF), The impact of zinc supplementation on childhood mortality and severe morbidity, World Health Organization, http://www.who.int/child_adolescent_health/documents/zinc_mortality/en/index.html, retrieved 2009-03-01 
  171. Shrimpton, R.; Gross, R.; Darnton-Hill, I.; Young, M. (2005), "Zinc deficiency: what are the most appropriate interventions?", British Medical Journal 330 (7487): 347, doi:10.1136/bmj.330.7487.347, PMID 15705693 
  172. Eisler, Ronald (1993), "Zinc Hazard to Fish, Wildlife, and Invertebrates: A Synoptic Review" (PDF), Contaminant Hazard Reviews (Laurel, Maryland: U.S. Department of the Interior, Fish and Wildlife Service) (10), http://www.pwrc.usgs.gov/infobase/eisler/chr_26_zinc.pdf 
  173. Muyssen, Brita, T. A.; De Schamphelaere, Karel A. C.; Janssen, Colin R. (2006), "Mechanisms of chronic waterborne Zn toxicity in Daphnia magna", Aquatic Toxicology 77 (4): 393, doi:10.1016/j.aquatox.2006.01.006, PMID 16472524 
  174. Bothwell, Dawn N.; Mair, Eric A.; Cable, Benjamin B. (2003), "Chronic Ingestion of a Zinc-Based Penny", Pediatrics 111 (3): 689, doi:10.1542/peds.111.3.689, PMID 12612262 
  175. Johnson AR, Munoz A, Gottlieb JL, Jarrard DF (2007), "High dose zinc increases hospital admissions due to genitourinary complications", J. Urol. 177 (2): 639, doi:10.1016/j.juro.2006.09.047, PMID 17222649 
  176. Oxford, J. S.; Öberg, Bo (1985), Conquest of viral diseases: a topical review of drugs and vaccines, Elsevier, p. 142, ISBN 0444805664, http://books.google.com/?id=n24Pju7kHIYC&pg=PA142 
  177. FDA says Zicam nasal products harm sense of smell, Los Angeles Times, June 17, 2009
  178. Lamore SD, Cabello CM, Wondrak GT (May 2010), "The topical antimicrobial zinc pyrithione is a heat shock response inducer that causes DNA damage and PARP-dependent energy crisis in human skin cells", Cell Stress Chaperones 15 (3): 309–22, doi:10.1007/s12192-009-0145-6, PMID 19809895. 
  179. Barceloux, Donald G.; Barceloux, Donald (1999), "Zinc", Clinical Toxicology 37: 279, doi:10.1081/CLT-100102426 
  180. Bennett, Daniel R. M.D.; Baird, Curtis J. M.D.; Chan, Kwok-Ming; Crookes, Peter F.; Bremner, Cedric G.; Gottlieb, Michael M.; Naritoku, Wesley Y. M.D. (1997), "Zinc Toxicity Following Massive Coin Ingestion.", American Journal of Forensic Medicine & Pathology 18: 148, doi:10.1097/00000433-199706000-00008 
  181. Fernbach, S. K.; Tucker G. F. (1986), "Coin ingestion: unusual appearance of the penny in a child", Radiology 158 (2): 512, PMID 3941880, http://radiology.rsnajnls.org/cgi/content/abstract/158/2/512 
  182. Stowe, C. M.; Nelson, R.; Werdin, R.; et al. (1978), "Zinc phosphide poisoning in dogs", Journal of the American Veterinary Medical Association 173 (3): 270, PMID 689968 
  183. Reece, R. L.; Dickson, D. B.; Burrowes, P. J. (1986), "Zinc toxicity (new wire disease) in aviary birds", Australian Veterinary Journal 63: 199, doi:10.1111/j.1751-0813.1986.tb02979.x 

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