Group 12 element
Group → | 12 | |||
---|---|---|---|---|
↓ Period | ||||
4 | title="Zn, Zinc" style="text-align:center; color:#000000; background-color:#ffc0c0; border:2px solid #6e6e8e; ;"| 30 Zn | |||
5 | title="Cd, Cadmium" style="text-align:center; color:#000000; background-color:#ffc0c0; border:2px solid #6e6e8e; ;"| 48 Cd | |||
6 | title="Hg, Mercury (element)" style="text-align:center; color:#000000; background-color:#ffc0c0; border:2px solid #6e6e8e; ;"| 80 Hg | |||
7 | title="Cn, Copernicium" style="text-align:center; color:#000000; background-color:#ffc0c0; border:2px dotted #6e6e8e; ;"| 112 Cn | |||
|
A group 12 element is one of the elements in group 12 (IUPAC style) in the periodic table. This includes zinc (Zn), cadmium (Cd) and mercury (Hg).[1][2][3] The further inclusion of copernicium (Cn) in group 12 is supported by recent experiments on individual copernicium atoms.[4] Although this group lies in the d-block of the periodic table it is not always considered to be a part of the transition metals as the elements in this group have a filled d-subshell.
The three group 12 elements that occur naturally are zinc, cadmium and mercury. They are all widely used in electric and electronic appications, as well as in various alloys. The first two members of the group share similar properties as they are solid metals under standard conditions. Mercury is the only metal that is a liquid at room temperature. While zinc is very important in the biochemistry of living organisms, cadmium and mercury are both highly toxic. As copernicium does not occur in nature, it has to be synthesized in the laboratory.
Physical and atomic properties
Like other groups of the periodic table, the members of group 12 show patterns in its electron configuration, especially the outermost shells, which result in trends in their chemical behavior:
Z | Element | No. of electrons/shell |
---|---|---|
30 | zinc | 2, 8, 18, 2 |
48 | cadmium | 2, 8, 18, 18, 2 |
80 | mercury | 2, 8, 18, 32, 18, 2 |
112 | copernicium | 2, 8, 18, 32, 32, 18, 2 (predicted) |
Group 12 elements are all soft, diamagnetic, divalent metals. They have the lowest melting points among all transition metals.[5] Zinc, also referred to in nonscientific contexts as spelter,[6] is bluish-white, lustrous[7] though most common commercial grades of the metal have a dull finish.[8] Cadmium is soft, malleable, ductile, and with a bluish-white color. Mercury is a liquid, heavy, silvery-white metal. It is the only common liquid metal at ordinary temperatures, and as compared to other metals, it is a poor conductor of heat, but a fair conductor of electricity.[9]
The table below is a summary of the key physical properties of the group 12 elements. Very little is known about copernicium, and none of its physical properties have been confirmed.
Name | Zinc | Cadmium | Mercury |
---|---|---|---|
Melting point | 693 K (420 °C) | 594 K (321 °C) | 234 K (−39 °C) |
Boiling point | 1180 K (907 °C) | 1040 K (767 °C) | 630 K (357 °C) |
Density | 7.14 g·cm−3 | 8.65 g·cm−3 | 13.534 g·cm−3 |
Appearance | silver-gray | silvery bluish-gray metallic | silvery |
Atomic radius | 135 pm | 155 pm | 150 pm |
Zinc is somewhat less dense than iron and has a hexagonal crystal structure.[10] The metal is hard and brittle at most temperatures but becomes malleable between 100 and 150 °C.[7][8] Above 210 °C, the metal becomes brittle again and can be pulverized by beating.[11] Zinc is a fair conductor of electricity.[7] For a metal, zinc has relatively low melting (419.5 °C, 787.1 F) and boiling points (907 °C).[5] Cadmium is similar in many respects to zinc but forms complex compounds.[12] Unlike other metals, cadmium is resistant to corrosion and as a result it is used as a protective layer when deposited on other metals. As a bulk metal, cadmium is insoluble in water and is not flammable; however, in its powdered form it may burn and release toxic fumes.[13] Mercury has an exceptionally low melting temperature for a d-block metal. A complete explanation of this fact requires a deep excursion into quantum physics, but it can be summarized as follows: mercury has a unique electronic configuration where electrons fill up all the available 1s, 2s, 2p, 3s, 3p, 3d, 4s, 4p, 4d, 4f, 5s, 5p, 5d and 6s subshells. As such configuration strongly resists removal of an electron, mercury behaves similarly to noble gas elements, which form weak bonds and thus easily melting solids. The stability of the 6s shell is due to the presence of a filled 4f shell. An f shell poorly screens the nuclear charge that increases the attractive Coulomb interaction of the 6s shell and the nucleus (see lanthanide contraction). The absence of a filled inner f shell is the reason for the somewhat higher melting temperature ofcadmium and zinc, although both these metals still melt easily and, in addition, have unusually low boiling points. Metals such as gold have atoms with one less 6s electron than mercury. Those electrons are more easily removed and are shared between the gold atoms forming relatively strong metallic bonds.[14][15]
Zinc, cadmium and mercury for a large range of alloys. Among the zinc containing ones brass is 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.[16] While neither zinc nor zirconium are ferromagnetic, their alloy ZrZn
2 exhibits ferromagnetism below 35 K.[7] Cadmium is used in many kinds of solder and bearing alloys, due to a low coefficient of friction and fatigue resistance.[17] It is also found in some of the lowest-melting alloys, such as Wood's metal.[18] Because it is a liquid, mercury dissolves other metals and the alloys that are formed are called amalgams. For example, such amalgams are known with gold, zinc, sodium, and many other metals. Because iron is an exception, iron flasks have been traditionally used to trade mercury. Other metals that do not form amalgams with mercury include tantalum, tungsten and platinum. Sodium amalgam is a common reducing agent in organic synthesis, and is also used in high-pressure sodium lamps. Mercury readily combines with aluminium to form a mercury-aluminium amalgam when the two pure metals come into contact. Since the amalgam reacts with air to give aluminium oxide, small amounts of mercury corrode aluminium. For this reason, mercury is not allowed aboard an aircraft under most circumstances because of the risk of it forming an amalgam with exposed aluminium parts in the aircraft.[19]
Chemistry
H | He | |||||||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Li | Be | B | C | N | O | F | Ne | |||||||||||
Na | Mg | Al | Si | P | S | Cl | Ar | |||||||||||
K | Ca | Sc | Ti | V | Cr | Mn | Fe | Co | Ni | Cu | Zn | Ga | Ge | As | Se | Br | Kr | |
Rb | Sr | Y | Zr | Nb | Mo | Tc | Ru | Rh | Pd | Ag | Cd | In | Sn | Sb | Te | I | Xe | |
Cs | Ba | * | Hf | Ta | W | Re | Os | Ir | Pt | Au | Hg | Tl | Pb | Bi | Po | At | Rn | |
Fr | Ra | ** | Rf | Db | Sg | Bh | Hs | Mt | Ds | Rg | Cn | Uut | Uuq | Uup | Uuh | Uus | Uuo | |
* | La | Ce | Pr | Nd | Pm | Sm | Eu | Gd | Tb | Dy | Ho | Er | Tm | Yb | Lu | |||
** | Ac | Th | Pa | U | Np | Pu | Am | Cm | Bk | Cf | Es | Fm | Md | No | Lr |
Group 12 in the periodic table |
Most of the chemistry has been observed only for the first three members of the group. The chemistry of copernicium is not well established and therefore the rest of the section deals only with zinc, cadmium and mercury.
Periodic trends
All elements in this group are metals. The similarity of the metallic radii of cadmium and mercury is an effect of the lanthanide contraction. So, the trend in this group is unlike the trend in group 2, the alkaline earths, where metallic radius increases smoothly from top to bottom of the group. All three metals have relatively low melting and boiling points, indicating that the metallic bond is relatively weak, with relatively little overlap between the valence band and the conduction band.[20] Thus, zinc is close to the boundary between metallic and metalloidelements, which is usually placed between gallium and germanium, though gallium participates in semi-conductors such as gallium arsenide.
Zinc and cadmium are electropositive while mercury is not.[20] As a result, zinc metal and cadmium are good reducing agents. The elements of group group 12 have an oxidation state of +2 in which the ions have the rather stable d10 electronic configuration, with a full sub-shell. However, mercury can easily be reduced to the +1 oxidation state; usually, as in the ion Hg22+, two mercury(I) ions come together to form a metal-metal bond and a diamagnetic species.[21] Cadmium can also form species such as [Cd2Cl6]4− in which the metal's oxidation state is +1. Just as with mercury, the formation of a metal-metal bond results in a diamagnetic compound in which there are no unpaired electrons; thus, making the species very reactive. Zinc(I) is known only in the gas phase, in such compounds as linear Zn2Cl2, analogous to calomel.
Location in the periodic table
The elements in group 12 are usually considered to be d-block elements, but not transition elements as the d-shell is full. Some authors classify these elements as main-group elements because the valence electrons are in ns2 orbitals. Nevertheless, they share many characteristics with the neighboring group 11 elements on the periodic table, which are almost universally considered to be transition elements. For example, zinc shares many characteristics with the neighboring transition metal, copper. Zinc complexes merit inclusion in the Irving-Williams series as zinc forms many complexes with the same stoichiometry as complexes of copper(II), albeit with smaller stability constants.[22] There is little similarity between cadmium and silver as compounds of silver(II) are rare and those that do exist are very strong oxidizing agents. Likewise the common oxidation state for gold is +3, which precludes there being much common chemistry between mercury and gold, though there are similarities between mercury(I) and gold(I) such as the formation of linear dicyano complexes, [M(CN)2]−. According to IUPAC's definition of transition metal as an element whose atom has an incomplete d sub-shell, or which can give rise to cations with an incomplete d sub-shell,[23] zinc and cadmium are not transition metals, while mercury is. This is because only mercury is known to have a compound where its oxidation state is higher than +2, in mercury(IV) fluoride.[24][25]
Compounds
All three metal ions form many tetrahedral species, such as MCl42−. When a divalent ion of these elements forms a tetrahedral complex, it obeys the octet rule. Both zinc and cadmium can also form octahedral complexes such as the aqua ions [M(H2O)6]2+ which are present in aqueous solutions of salts of these metals.[26] Covalent character is achieved by using the 4d or 5d orbitals, respectively, forming sp3d2 hybrid orbitals. Mercury, however, rarely exceeds a coordination number of four; when it does so the 5f orbitals must be involved. Coordination numbers of 2, 3, 5, 7 and 8 are also known.
Organometallic compounds
This section needs expansion. You can help by adding to it. (March 2012) |
History
The elements of group 12 have been found throughout history, being used since ancient times to being discovered in laboratories. The group itself has not acquired a trivial name, but it has been called group IIB in the past.
Zinc
In ancient times zinc has been found being used in impure forms as well as in alloys such as brass that have been found to be over 2000 years old.[27][28] 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.[29] The metal was also of use to alchemists.[30] The name of the metal was first documented in the 16th century,[31][32] and is probably derived from the German [zinke] Error: {{Lang}}: text has italic markup (help) for the meedle-like appearance of metallic crystals.[33]
The isolation of metallic zinc in the West may have been achieved independently by several people in the 17th century.[34] German chemist Andreas Marggraf is usually given credit for discovering pure metallic zinc in a 1746 experiment by heating a mixture of calamine and charcoal in a closed vessel without copper to obtain a metal.[35] Experiments on frogs by the Italian doctor Luigi Galvani in 1780 with brass paved the way for the discovery of for electrical batteries, galvanization and cathodic protection.[36][37] In 1880, Galvani's friend, Alessandro Volta, invented the Voltaic pile.[36] The biological importance of zinc was not discovered until 1940 when carbonic anhydrase, an enzyme that scrubs carbon dioxide from blood, was shown to have zinc in its active site.[38]
Cadmium
In 1817 Cadmium was discovered in Germany as an impurity in zinc carbonate minerals (calamine) by Friedrich Stromeyer and Karl Samuel Leberecht Hermann.[39] It was named after the latin Latin cadmia for "calamine", a cadmium-bearing mixture of minerals, which was in turn named after the Greek mythological character, Κάδμος Cadmus, the founder of Thebes.[40] Stromeyer eventually isolated cadmium metal by roasting and reduction of the sulfide.[41][42][43]
In 1927, the International Conference on Weights and Measures redefined the meter in terms of a red cadmium spectral line (1 m = 1,553,164.13 wavelengths).[44] This definition has since been changed (see krypton).
Mercury
Mercury has been found in Egyptian tombs which have been dated back to 1500 BC,[45] where mercury was used in cosmetics. It was also used by the ancient Chinese who believed it would improve and prolong health.[46] By 500 BC mercury was used to make amalgams (Medieval Latin amalgama, "alloy of mercury") with other metals.[47] Alchemists thought of mercury as the First Matter from which all metals were formed. They believed that different metals could be produced by varying the quality and quantity of sulfur contained within the mercury. The purest of these was gold, and mercury was called for in attempts at thetransmutation of base (or impure) metals into gold, which was the goal of many alchemists.[48]
Hg is the modern chemical symbol for mercury. It comes from hydrargyrum, a Latinized form of the Greek word Ύδραργυρος (hydrargyros), which is a compound word meaning "water-silver" (hydr- = water, argyros = silver) — since it is liquid like water and shiny like silver. The element was named after the Roman god Mercury, known for speed and mobility. It is associated with the planet Mercury; the astrological symbol for the planet is also one of the alchemical symbols for the metal.[49] Mercury is the only metal for which the alchemical planetary name became the common name.[48]
Copernicium
The heaviest known group 12 element, copernicium was first created on February 9, 1996, at the Gesellschaft für Schwerionenforschung (GSI) located in Darmstadt, Germany by Sigurd Hofmann, Victor Ninov et al.[50] It was then officially named by the International Union of Pure and Applied Chemistry after Nicolaus Copernicus on February 19, 2010, the 537th anniversary of Copernicus' birth.[51]
Eka-copernicium
The next element below copernicium is expected to be either the 162th element (unhexbium, Uhb)[52] or the 164th element (unhexquadium, Uhq).[53] There are no plans to attempt to synthesize either of these in the near future, since they are both late period 8 elements. Currently none of the period 8 elements have been discovered yet, and it is possible that due to drip instabilities, only the lower period 8 elements are physically possible.[53][54][55]
Occurrence
Like in most other d-block groups the abundance in Earth's crust decreases with higher atomic number, and so the zinc is with 65 parts per million (ppm) the most abundant in the group while cadmium with 0.1 ppm and mercury with 0.08 ppm are orders of magnitude less abundant.[56] Copernicium, as a synthetic element with a half-life of a few minutes, may only be present in the laboratories where it was produced.
Group 12 metals are chalcophiles, meaning the elements have low affinities for oxides and prefer to bond with sulfides. Chalcophiles formed as the crust solidified under the reducing conditions of the early Earth's atmosphere.[57] The commercially most important minerals of group 12 elements are sulfide minerals.[20] Sphalerite, which is a form of zinc sulfide, is the most heavily mined zinc-containing ore because its concentrate contains 60–62% zinc.[10] No significant deposits of cadmium-containing ores are known. Greenockite (CdS), the only cadmium mineral of importance, is nearly always associated with sphalerite (ZnS). This association is caused by the geochemical similarity between zinc and cadmium which makes geological separation unlikely. As a consequence, cadmium is produced mainly as a byproduct from mining, smelting, and refining sulfidic ores of zinc, and, to a lesser degree, lead and copper.[58][59] One place where metallic cadmium can be found is the Vilyuy River basin in Siberia.[60] Although mercury is an extremely rare element in the Earth's crust,[61] because it does not blend geochemically with those elements that constitute the majority of the crustal mass, mercury ores can be highly concentrated considering the element's abundance in ordinary rock. The richest mercury ores contain up to 2.5% mercury by mass, and even the leanest concentrated deposits are at least 0.1% mercury (12,000 times average crustal abundance). It is found either as a native metal (rare) or in cinnabar (HgS), corderoite, livingstonite and other minerals, with cinnabar being the most common ore.[62]
While mercury and zinc minerals are found in large enough quantities to be mined, cadmium is too similar to zinc and therefore is always present in small quantities in zinc ores from where it is recovered. Identified world zinc resources total about 1.9 billion tonnes.[63] Large deposits are in Australia, Canada and the United States with the largest reserves in Iran.[57][64][65] At the current rate of consumption, these reserves are estimated to be depleted sometime between 2027 and 2055.[66][67] About 346 million tonnes have been extracted throughout history to 2002, and one estimate found that about 109 million tonnes of that remains in use.[68] In 2005, China was the top producer of mercury with almost two-thirds global share followed by Kyrgyzstan.[69] Several other countries are believed to have unrecorded production of mercury from copper electrowinning processes and by recovery from effluents. Because of the high toxicity of mercury, both the mining of cinnabar and refining for mercury are hazardous and historic causes of mercury poisoning.[70]
Production
Zinc is the fourth most common metal in use, trailing only iron, aluminium, and copper with an annual production of about 10 million tonnes.[71] 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. Zinc metal is produced using extractive metallurgy.[72] Roasting converts the zinc sulfide concentrate produced during processing to zinc oxide:[73] 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.[74] The zinc vapor is collected in a condenser.[73] Electrowinning processing leaches zinc from the ore concentrate by sulfuric acid:[75] After this step electrolysis is used to produce zinc metal.[73]
Cadmium is a common impurity in zinc ores, and it is most isolated during the production of zinc. Some zinc ores concentrates from sulfidic zinc ores contain up to 1.4% of cadmium.[76] Cadmium is isolated from the zinc produced from the flue dust by vacuum distillation if the zinc is smelted, or cadmium sulfate is precipitated out of the electrolysis solution.[77]
The richest mercury ores contain up to 2.5% mercury by mass, and even the leanest concentrated deposits are at least 0.1% mercury, with cinnabar (HgS) being the most common ore in the deposits.[78] Mercury is extracted by heating cinnabar in a current of air and condensing the vapor.[79]
Super-heavy elements such as copernicium are produced by bombarding lighter elements in particle accelerators that induces fusion reactions. Whereas most of the isotopes of rutherfordium can be synthesized directly this way, some heavier ones have only been observed as decay products of elements with higher atomic numbers.[80] The first fusion reaction to produce copernicium was performed by GSI in 1996, who reported the detection of two decay chains of copernicium-277.[50]
- The element Link does not exist. + The element Link does not exist. → 277
112Cn
+
n
In total, approximately 75 atoms of copernicium have been prepared using various nuclear reactions.
Applications
Due to the physical similarities which they share, the group 12 elements can be found in many common situations. Zinc and cadmium are commonly used as anti-corrosion(galvanization) agents[1] as they will attract all local oxidation until they completely corrode.[81] These protective coatings can be applied to other metals through by hot-dip galvanizing a substance into the molten form of the metal,[82] or through the process of electroplating which may be passivated by the use of chromate salts.[83] Group 12 elements are also used in electrochemistry as they may act as an alternative to the standard hydrogen electrode in addition to being a secondary reference electrode.[84]
In the US, zinc is used predominantly for galvanizing (55%) and for brass, bronze and other alloys (37%).[85] The relative reactivity of zinc and its ability to attract oxidation to itself makes it an efficient sacrificial anode in cathodic protection (CP). For example, cathodic protection of a buried pipeline can be achieved by connecting anodes made from zinc to the pipe.[86] Zinc acts as the anode (negative terminus) by slowly corroding away as it passes electric current to the steel pipeline.[86][note 1] Zinc is also used to cathodically protect metals that are exposed to sea water from corrosion.[87][88] Zinc is also used as an anode material for batteries such as in zinc–carbon batteries[89][90] or zinc-air battery/fuel cells.[91][92][93] 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.[86] Brass is generally more ductile and stronger than copper and has superior corrosion resistance.[86] These properties make it useful in communication equipment, hardware, musical instruments, and water valves.[86] Other widely used alloys that contain zinc include nickel silver, typewriter metal, soft and aluminium solder, and commercial bronze.[7] 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.[7] These alloys are marketed under the name Zamak.[94] Roughly one quarter of all zinc output, in the United States (2009), is consumed in the form of zinc compounds, a variety of which are used industrially.[85]
Cadmium has many common industrial uses as it is a key component in battery production, is present in cadmium pigments,[95] coatings,[83] and is commonly used in electroplating.[17] In 2009, 86% of cadmium was used in batteries, predominantly in rechargeable nickel-cadmium batteries. The European Union banned the use of cadmium in electronics in 2004 with several exceptions but reduced the allowed content of cadmium in electronics to 0.002%.[96] Cadmium electroplating, consuming 6% of the global production, can be found in the aircraft industry due to the ability to resist corrosion when applied to steel components.[17]
Mercury is used primarily for the manufacture of industrial chemicals or for electrical and electronic applications. It is used in some thermometers, especially ones which are used to measure high temperatures. A still increasing amount is used as gaseous mercury in fluorescent lamps,[97] while most of the other applications are slowly phased out due to health and safety regulations,[98] and is in some applications replaced with less toxic but considerably more expensive Galinstan alloy.[99] Mercury and its compounds have been used in medicine, although they are much less common today than they once were, now that the toxic effects of mercury and its compounds are more widely understood.[100] It is still used as an ingredient in dental amalgams. In the late 20th century the largest use of mercury[101][102] was in the mercury cell process (also called the Castner-Kellner process) in the production of chlorine and caustic soda.[103]
Biological role and toxicity
The group 12 elements have multiple effects on biological organisms as cadmium and mercury are toxic while zinc is required by most plants and animals in trace amounts. Zinc is required by most organisms in trace amounts as it is present in enzymes where it is often present as a catalytic agent for enzyme-directed reactions.[104] In large amounts zinc may be toxic to biological organisms as it prevents cells from absorbing copper and iron.[105]
Mercury and cadmium are toxic and may cause environmental damage if they enter rivers or rain water. This may result in contaminated crops[106] as well as the bioaccumulation of mercury in a food chain leading to an increase in illnesses caused by mercury and cadmium poisoning.[107]
Copernicium has no biological role[108] and does not occur in nature,[109] but it is most likely to be toxic due to its radioactivity.[110][111]
Notes
- ^ Electric current will naturally flow between zinc and steel but in some circumstances inert anodes are used with an external DC source.
References
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{{cite journal}}
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{{cite book}}
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- ^ Norrby, L.J. (1991). "Why is mercury liquid? Or, why do relativistic effects not get into chemistry textbooks?". Journal of Chemical Education. 68 (2): 110. Bibcode:1991JChEd..68..110N. doi:10.1021/ed068p110.
- ^ "Why is mercury a liquid at STP?". Retrieved 2009-07-07.
- ^ 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.
- ^ a b c Scoullos, Michael J. (2001). Mercury, Cadmium, Lead: Handbook for Sustainable Heavy Metals Policy and Regulation. Springer. ISBN 9781402002243.
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- ^ Vargel, C.; Jacques, M.; Schmidt, M. P. (2004). Corrosion of Aluminium. Elsevier. p. 158. ISBN 20049780080444956.
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value: length (help)CS1 maint: multiple names: authors list (link) - ^ a b c Moss, Alex (2003). "Descriptive P-block Notes" (PDF). Alchemyst Online. Retrieved June 2, 2011.
- ^ Lindberg, S.E.; Stratton, W.J. (1998). "Atmospheric Mercury Speciation: Concentrations and Behavior of Reactive Gaseous Mercury in Ambient Air". Environmental Science and Technology. 32 (1). American Chemical Society: 49–57. doi:10.1021/es970546u.
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- ^ Greenwood 1997, p. 1201
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- ^ Arny, Henry Vinecome (1917). Principles of Pharmacy (2nd ed.). W. B. Saunders company. p. 483.
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