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Nitrogen

January 31, 2023

Nitrogen is the chemical element with the symbol N and atomic number 7. Nitrogen is a nonmetal and the lightest member of group 15 of the periodic table, often called the pnictogens. It is a common element in the universe, estimated at seventh in total abundance in the Milky Way and the Solar System. At standard temperature and pressure, two atoms of the element bond to form N2, a colorless and odorless diatomic gas. N2 forms about 78% of Earth's atmosphere, making it the most abundant uncombined element. Nitrogen occurs in all organisms, primarily in amino acids (and thus proteins), in the nucleic acids (DNA and RNA) and in the energy transfer molecule adenosine triphosphate. The human body contains about 3% nitrogen by mass, the fourth most abundant element in the body after oxygen, carbon, and hydrogen. The nitrogen cycle describes the movement of the element from the air, into the biosphere and organic compounds, then back into the atmosphere.

Nitrogen, 7N
Liquid nitrogen (N2 at < −196 °C)
Nitrogen
Allotropessee § Allotropes
Appearancecolorless gas, liquid or solid
Standard atomic weight Ar°(N)
  • [14.0064314.00728]
  • 14.007±0.001 (abridged)[1]
Nitrogen in the periodic table
Hydrogen Helium
Lithium Beryllium Boron Carbon Nitrogen Oxygen Fluorine Neon
Sodium Magnesium Aluminium Silicon Phosphorus Sulfur Chlorine Argon
Potassium Calcium Scandium Titanium Vanadium Chromium Manganese Iron Cobalt Nickel Copper Zinc Gallium Germanium Arsenic Selenium Bromine Krypton
Rubidium Strontium Yttrium Zirconium Niobium Molybdenum Technetium Ruthenium Rhodium Palladium Silver Cadmium Indium Tin Antimony Tellurium Iodine Xenon
Caesium Barium Lanthanum Cerium Praseodymium Neodymium Promethium Samarium Europium Gadolinium Terbium Dysprosium Holmium Erbium Thulium Ytterbium Lutetium Hafnium Tantalum Tungsten Rhenium Osmium Iridium Platinum Gold Mercury (element) Thallium Lead Bismuth Polonium Astatine Radon
Francium Radium Actinium Thorium Protactinium Uranium Neptunium Plutonium Americium Curium Berkelium Californium Einsteinium Fermium Mendelevium Nobelium Lawrencium Rutherfordium Dubnium Seaborgium Bohrium Hassium Meitnerium Darmstadtium Roentgenium Copernicium Nihonium Flerovium Moscovium Livermorium Tennessine Oganesson


N

P
carbonnitrogenoxygen
Atomic number (Z)7
Groupgroup 15 (pnictogens)
Periodperiod 2
Block  p-block
Electron configuration[He] 2s2 2p3
Electrons per shell2, 5
Physical properties
Phase at STPgas
Melting point(N2) 63.23[2] K ​(−209.86[2] °C, ​−345.75[2] °F)
Boiling point(N2) 77.355 K ​(−195.795 °C, ​−320.431 °F)
Density (at STP)1.2506 g/L[3] at 0 °C, 1013 mbar
when liquid (at b.p.)0.808 g/cm3
Triple point63.151 K, ​12.52 kPa
Critical point126.21 K, 3.39 MPa
Heat of fusion(N2) 0.72 kJ/mol
Heat of vaporisation(N2) 5.57 kJ/mol
Molar heat capacity(N2) 29.124 J/(mol·K)
Vapour pressure
P (Pa) 1 10 100 1 k 10 k 100 k
at T (K) 37 41 46 53 62 77
Atomic properties
Oxidation states−3, −2, −1, 0,[4] +1, +2, +3, +4, +5 (a strongly acidic oxide)
ElectronegativityPauling scale: 3.04
Ionisation energies
  • 1st: 1402.3 kJ/mol
  • 2nd: 2856 kJ/mol
  • 3rd: 4578.1 kJ/mol
  • (more)
Covalent radius71±1 pm
Van der Waals radius155 pm
Spectral lines of nitrogen
Other properties
Natural occurrenceprimordial
Crystal structurehexagonal
Speed of sound353 m/s (gas, at 27 °C)
Thermal conductivity25.83×10−3 W/(m⋅K)
Magnetic orderingdiamagnetic
CAS Number17778-88-0
7727-37-9 (N2)
History
DiscoveryDaniel Rutherford (1772)
Named byJean-Antoine Chaptal (1790)
Main isotopes of nitrogen
Iso­tope Decay
abun­dance half-life (t1/2) mode pro­duct
13N syn 9.965 min β+ 13C
14N [99.578%99.663%] stable
15N [0.337%0.422%] stable
 Category: Nitrogen
| references

Many industrially important compounds, such as ammonia, nitric acid, organic nitrates (propellants and explosives), and cyanides, contain nitrogen. The extremely strong triple bond in elemental nitrogen (N≡N), the second strongest bond in any diatomic molecule after carbon monoxide (CO),[5] dominates nitrogen chemistry. This causes difficulty for both organisms and industry in converting N2 into useful compounds, but at the same time it means that burning, exploding, or decomposing nitrogen compounds to form nitrogen gas releases large amounts of often useful energy. Synthetically produced ammonia and nitrates are key industrial fertilisers, and fertiliser nitrates are key pollutants in the eutrophication of water systems.

It was first discovered and isolated by Scottish physician Daniel Rutherford in 1772. Although Carl Wilhelm Scheele and Henry Cavendish had independently done so at about the same time, Rutherford is generally accorded the credit because his work was published first. The name nitrogène was suggested by French chemist Jean-Antoine-Claude Chaptal in 1790 when it was found that nitrogen was present in nitric acid and nitrates. Antoine Lavoisier suggested instead the name azote, from the Ancient Greek: ἀζωτικός "no life", as it is an asphyxiant gas; this name is used in several languages, including French, Italian, Russian, Romanian, Portuguese and Turkish, and appears in the English names of some nitrogen compounds such as hydrazine, azides and azo compounds.

Apart from its use in fertilisers and energy stores, nitrogen is a constituent of organic compounds as diverse as Kevlar used in high-strength fabric and cyanoacrylate used in superglue. Nitrogen is a constituent of every major pharmacological drug class, including antibiotics. Many drugs are mimics or prodrugs of natural nitrogen-containing signal molecules: for example, the organic nitrates nitroglycerin and nitroprusside control blood pressure by metabolizing into nitric oxide. Many notable nitrogen-containing drugs, such as the natural caffeine and morphine or the synthetic amphetamines, act on receptors of animal neurotransmitters.

History

 
Daniel Rutherford, discoverer of nitrogen

Nitrogen compounds have a very long history, ammonium chloride having been known to Herodotus. They were well-known by the Middle Ages. Alchemists knew nitric acid as aqua fortis (strong water), as well as other nitrogen compounds such as ammonium salts and nitrate salts. The mixture of nitric and hydrochloric acids was known as aqua regia (royal water), celebrated for its ability to dissolve gold, the king of metals.[6]

The discovery of nitrogen is attributed to the Scottish physician Daniel Rutherford in 1772, who called it noxious air.[7][8] Though he did not recognise it as an entirely different chemical substance, he clearly distinguished it from Joseph Black's "fixed air", or carbon dioxide.[9] The fact that there was a component of air that does not support combustion was clear to Rutherford, although he was not aware that it was an element. Nitrogen was also studied at about the same time by Carl Wilhelm Scheele,[10] Henry Cavendish,[11] and Joseph Priestley,[12] who referred to it as burnt air or phlogisticated air. French chemist Antoine Lavoisier referred to nitrogen gas as "mephitic air" or azote, from the Greek word άζωτικός (azotikos), "no life", due to it being asphyxiant.[13][14] In an atmosphere of pure nitrogen, animals died and flames were extinguished. Though Lavoisier's name was not accepted in English since it was pointed out that all gases but oxygen are either asphyxiant or outright toxic, it is used in many languages (French, Italian, Portuguese, Polish, Russian, Albanian, Turkish, etc.; the German Stickstoff similarly refers to the same characteristic, viz. ersticken "to choke or suffocate") and still remains in English in the common names of many nitrogen compounds, such as hydrazine and compounds of the azide ion. Finally, it led to the name "pnictogens" for the group headed by nitrogen, from the Greek πνίγειν "to choke".[6]

The English word nitrogen (1794) entered the language from the French nitrogène, coined in 1790 by French chemist Jean-Antoine Chaptal (1756–1832),[15] from the French nitre (potassium nitrate, also called saltpeter) and the French suffix -gène, "producing", from the Greek -γενής (-genes, "begotten"). Chaptal's meaning was that nitrogen is the essential part of nitric acid, which in turn was produced from nitre. In earlier times, niter had been confused with Egyptian "natron" (sodium carbonate) – called νίτρον (nitron) in Greek – which, despite the name, contained no nitrate.[16]

The earliest military, industrial, and agricultural applications of nitrogen compounds used saltpeter (sodium nitrate or potassium nitrate), most notably in gunpowder, and later as fertiliser. In 1910, Lord Rayleigh discovered that an electrical discharge in nitrogen gas produced "active nitrogen", a monatomic allotrope of nitrogen.[17] The "whirling cloud of brilliant yellow light" produced by his apparatus reacted with mercury to produce explosive mercury nitride.[18]

For a long time, sources of nitrogen compounds were limited. Natural sources originated either from biology or deposits of nitrates produced by atmospheric reactions. Nitrogen fixation by industrial processes like the Frank–Caro process (1895–1899) and Haber–Bosch process (1908–1913) eased this shortage of nitrogen compounds, to the extent that half of global food production (see Applications) now relies on synthetic nitrogen fertilisers.[19] At the same time, use of the Ostwald process (1902) to produce nitrates from industrial nitrogen fixation allowed the large-scale industrial production of nitrates as feedstock in the manufacture of explosives in the World Wars of the 20th century.[20][21]

Properties

Atomic

 
The shapes of the five orbitals occupied in nitrogen. The two colours show the phase or sign of the wave function in each region. From left to right: 1s, 2s (cutaway to show internal structure), 2px, 2py, 2pz.


A nitrogen atom has seven electrons. In the ground state, they are arranged in the electron configuration 1s2
2s2
2p1
x2p1
y2p1
z. It, therefore, has five valence electrons in the 2s and 2p orbitals, three of which (the p-electrons) are unpaired. It has one of the highest electronegativities among the elements (3.04 on the Pauling scale), exceeded only by chlorine (3.16), oxygen (3.44), and fluorine (3.98). (The light noble gases, helium, neon, and argon, would presumably also be more electronegative, and in fact are on the Allen scale.)[22] Following periodic trends, its single-bond covalent radius of 71 pm is smaller than those of boron (84 pm) and carbon (76 pm), while it is larger than those of oxygen (66 pm) and fluorine (57 pm). The nitride anion, N3−, is much larger at 146 pm, similar to that of the oxide (O2−: 140 pm) and fluoride (F: 133 pm) anions.[22] The first three ionisation energies of nitrogen are 1.402, 2.856, and 4.577 MJ·mol−1, and the sum of the fourth and fifth is 16.920 MJ·mol−1. Due to these very high figures, nitrogen has no simple cationic chemistry.[23] The lack of radial nodes in the 2p subshell is directly responsible for many of the anomalous properties of the first row of the p-block, especially in nitrogen, oxygen, and fluorine. The 2p subshell is very small and has a very similar radius to the 2s shell, facilitating orbital hybridisation. It also results in very large electrostatic forces of attraction between the nucleus and the valence electrons in the 2s and 2p shells, resulting in very high electronegativities. Hypervalency is almost unknown in the 2p elements for the same reason, because the high electronegativity makes it difficult for a small nitrogen atom to be a central atom in an electron-rich three-center four-electron bond since it would tend to attract the electrons strongly to itself. Thus, despite nitrogen's position at the head of group 15 in the periodic table, its chemistry shows huge differences from that of its heavier congeners phosphorus, arsenic, antimony, and bismuth.[24]

Nitrogen may be usefully compared to its horizontal neighbours' carbon and oxygen as well as its vertical neighbours in the pnictogen column, phosphorus, arsenic, antimony, and bismuth. Although each period 2 element from lithium to oxygen shows some similarities to the period 3 element in the next group (from magnesium to chlorine; these are known as diagonal relationships), their degree drops off abruptly past the boron–silicon pair. The similarities of nitrogen to sulfur are mostly limited to sulfur nitride ring compounds when both elements are the only ones present.[25]

Nitrogen does not share the proclivity of carbon for catenation. Like carbon, nitrogen tends to form ionic or metallic compounds with metals. Nitrogen forms an extensive series of nitrides with carbon, including those with chain-, graphitic-, and fullerenic-like structures.[26]

It resembles oxygen with its high electronegativity and concomitant capability for hydrogen bonding and the ability to form coordination complexes by donating its lone pairs of electrons. There are some parallels between the chemistry of ammonia NH3 and water H2O. For example, the capacity of both compounds to be protonated to give NH4+ and H3O+ or deprotonated to give NH2 and OH, with all of these able to be isolated in solid compounds.[27]

Nitrogen shares with both its horizontal neighbours a preference for forming multiple bonds, typically with carbon, oxygen, or other nitrogen atoms, through pπ–pπ interactions.[25] Thus, for example, nitrogen occurs as diatomic molecules and therefore has very much lower melting (−210 °C) and boiling points (−196 °C) than the rest of its group, as the N2 molecules are only held together by weak van der Waals interactions and there are very few electrons available to create significant instantaneous dipoles. This is not possible for its vertical neighbours; thus, the nitrogen oxides, nitrites, nitrates, nitro-, nitroso-, azo-, and diazo-compounds, azides, cyanates, thiocyanates, and imino-derivatives find no echo with phosphorus, arsenic, antimony, or bismuth. By the same token, however, the complexity of the phosphorus oxoacids finds no echo with nitrogen.[25] Setting aside their differences, nitrogen and phosphorus form an extensive series of compounds with one another; these have chain, ring, and cage structures.[28]

Table of thermal and physical properties of nitrogen (N2) at atmospheric pressure:[29][30]

Temperature (K) Density (kg/m^3) Specific heat (kJ/kg °C) Dynamic viscosity (kg/m s) Kinematic viscosity (m^2/s) Thermal conductivity (W/m °C) Thermal diffusivity (m^2/s) Prandtl Number
100 3.4388 1.07 6.88E-06 2.00E-06 0.00958 2.60E-06 0.768
150 2.2594 1.05 1.01E-05 4.45E-06 0.0139 5.86E-06 0.759
200 1.7108 1.0429 1.29E-05 7.57E-06 0.01824 1.02E-05 0.747
300 1.1421 1.0408 1.78E-05 1.56E-05 0.0262 2.20E-05 0.713
400 0.8538 1.0459 2.20E-05 2.57E-05 0.03335 3.73E-05 0.691
500 0.6824 1.0555 2.57E-05 3.77E-05 0.03984 5.53E-05 0.684
600 0.5687 1.0756 2.91E-05 5.12E-05 0.0458 7.49E-05 0.686
700 0.4934 1.0969 3.21E-05 6.67E-05 0.05123 9.47E-05 0.691
800 0.4277 1.1225 3.48E-05 8.15E-05 0.05609 1.17E-04 0.7
900 0.3796 1.1464 3.75E-05 9.11E-05 0.0607 1.39E-04 0.711
1000 0.3412 1.1677 4.00E-05 1.19E-04 0.06475 1.63E-04 0.724
1100 0.3108 1.1857 4.23E-05 1.36E-04 0.0685 1.86E-04 0.736
1200 0.2851 1.2037 4.45E-05 1.56E-04 0.07184 2.09E-04 0.748
1300 0.2591 1.219 4.66E-05 1.80E-04 0.081 2.56E-04 0.701

Isotopes

Main article: Isotopes of nitrogen
 
Table of nuclides (Segrè chart) from carbon to fluorine (including nitrogen). Orange indicates proton emission (nuclides outside the proton drip line); pink for positron emission (inverse beta decay); black for stable nuclides; blue for electron emission (beta decay); and violet for neutron emission (nuclides outside the neutron drip line). Proton number increases going up the vertical axis and neutron number going to the right on the horizontal axis.

Nitrogen has two stable isotopes: 14N and 15N. The first is much more common, making up 99.634% of natural nitrogen, and the second (which is slightly heavier) makes up the remaining 0.366%. This leads to an atomic weight of around 14.007 u.[22] Both of these stable isotopes are produced in the CNO cycle in stars, but 14N is more common as its neutron capture is the rate-limiting step. 14N is one of the five stable odd–odd nuclides (a nuclide having an odd number of protons and neutrons); the other four are 2H, 6Li, 10B, and 180mTa.[31]

The relative abundance of 14N and 15N is practically constant in the atmosphere but can vary elsewhere, due to natural isotopic fractionation from biological redox reactions and the evaporation of natural ammonia or nitric acid.[32] Biologically mediated reactions (e.g., assimilation, nitrification, and denitrification) strongly control nitrogen dynamics in the soil. These reactions typically result in 15N enrichment of the substrate and depletion of the product.[33]

The heavy isotope 15N was first discovered by S. M. Naudé in 1929, and soon after heavy isotopes of the neighbouring elements oxygen and carbon were discovered.[34] It presents one of the lowest thermal neutron capture cross-sections of all isotopes.[35] It is frequently used in nuclear magnetic resonance (NMR) spectroscopy to determine the structures of nitrogen-containing molecules, due to its fractional nuclear spin of one-half, which offers advantages for NMR such as narrower line width. 14N, though also theoretically usable, has an integer nuclear spin of one and thus has a quadrupole moment that leads to wider and less useful spectra.[22] 15N NMR nevertheless has complications not encountered in the more common 1H and 13C NMR spectroscopy. The low natural abundance of 15N (0.36%) significantly reduces sensitivity, a problem which is only exacerbated by its low gyromagnetic ratio, (only 10.14% that of 1H). As a result, the signal-to-noise ratio for 1H is about 300 times as much as that for 15N at the same magnetic field strength.[36] This may be somewhat alleviated by isotopic enrichment of 15N by chemical exchange or fractional distillation. 15N-enriched compounds have the advantage that under standard conditions, they do not undergo chemical exchange of their nitrogen atoms with atmospheric nitrogen, unlike compounds with labelled hydrogen, carbon, and oxygen isotopes that must be kept away from the atmosphere.[22] The 15N:14N ratio is commonly used in stable isotope analysis in the fields of geochemistry, hydrology, paleoclimatology and paleoceanography, where it is called δ15N.[37]

Of the ten other isotopes produced synthetically, ranging from 12N to 23N, 13N has a half-life of ten minutes and the remaining isotopes have half-lives on the order of seconds (16N and 17N) or milliseconds. No other nitrogen isotopes are possible as they would fall outside the nuclear drip lines, leaking out a proton or neutron.[38] Given the half-life difference, 13N is the most important nitrogen radioisotope, being relatively long-lived enough to use in positron emission tomography (PET), although its half-life is still short and thus it must be produced at the venue of the PET, for example in a cyclotron via proton bombardment of 16O producing 13N and an alpha particle.[39]

The radioisotope 16N is the dominant radionuclide in the coolant of pressurised water reactors or boiling water reactors during normal operation. It is produced from 16O (in water) via an (n,p) reaction, in which the 16O atom captures a neutron and expels a proton. It has a short half-life of about 7.1 s,[38] but during its decay back to 16O produces high-energy gamma radiation (5 to 7 MeV).[38][40] Because of this, access to the primary coolant piping in a pressurised water reactor must be restricted during reactor power operation.[40] It is a sensitive and immediate indicator of leaks from the primary coolant system to the secondary steam cycle and is the primary means of detection for such leaks.[40]

Chemistry and compounds

Allotropes

See also: Solid nitrogen
 
Molecular orbital diagram of dinitrogen molecule, N2. There are five bonding orbitals and two antibonding orbitals (marked with an asterisk; orbitals involving the inner 1s electrons not shown), giving a total bond order of three.

Atomic nitrogen, also known as active nitrogen, is highly reactive, being a triradical with three unpaired electrons. Free nitrogen atoms easily react with most elements to form nitrides, and even when two free nitrogen atoms collide to produce an excited N2 molecule, they may release so much energy on collision with even such stable molecules as carbon dioxide and water to cause homolytic fission into radicals such as CO and O or OH and H. Atomic nitrogen is prepared by passing an electric discharge through nitrogen gas at 0.1–2 mmHg, which produces atomic nitrogen along with a peach-yellow emission that fades slowly as an afterglow for several minutes even after the discharge terminates.[25]

Given the great reactivity of atomic nitrogen, elemental nitrogen usually occurs as molecular N2, dinitrogen. This molecule is a colourless, odourless, and tasteless diamagnetic gas at standard conditions: it melts at −210 °C and boils at −196 °C.[25] Dinitrogen is mostly unreactive at room temperature, but it will nevertheless react with lithium metal and some transition metal complexes. This is due to its bonding, which is unique among the diatomic elements at standard conditions in that it has an N≡N triple bond. Triple bonds have short bond lengths (in this case, 109.76 pm) and high dissociation energies (in this case, 945.41 kJ/mol), and are thus very strong, explaining dinitrogen's low level of chemical reactivity.[25][41]

Other nitrogen oligomers and polymers may be possible. If they could be synthesised, they may have potential applications as materials with a very high energy density, that could be used as powerful propellants or explosives.[42] Under extremely high pressures (1.1 million atm) and high temperatures (2000 K), as produced in a diamond anvil cell, nitrogen polymerises into the single-bonded cubic gauche crystal structure. This structure is similar to that of diamond, and both have extremely strong covalent bonds, resulting in its nickname "nitrogen diamond".[43]

 
Solid nitrogen on the plains of Sputnik Planitia (on the bottom-right side of the image) on Pluto next to water ice mountains (on the up-left side of the image)

At atmospheric pressure, molecular nitrogen condenses (liquefies) at 77 K (−195.79 °C) and freezes at 63 K (−210.01 °C)[44] into the beta hexagonal close-packed crystal allotropic form. Below 35.4 K (−237.6 °C) nitrogen assumes the cubic crystal allotropic form (called the alpha phase).[45] Liquid nitrogen, a colourless fluid resembling water in appearance, but with 80.8% of the density (the density of liquid nitrogen at its boiling point is 0.808 g/mL), is a common cryogen.[46] Solid nitrogen has many crystalline modifications. It forms a significant dynamic surface coverage on Pluto[47] and outer moons of the Solar System such as Triton.[48] Even at the low temperatures of solid nitrogen it is fairly volatile and can sublime to form an atmosphere, or condense back into nitrogen frost. It is very weak and flows in the form of glaciers and on Triton geysers of nitrogen gas come from the polar ice cap region.[49]

Dinitrogen complexes

Main article: Dinitrogen complex
 
Structure of [Ru(NH3)5(N2)]2+ (pentaamine(dinitrogen)ruthenium(II)), the first dinitrogen complex to be discovered

The first example of a dinitrogen complex to be discovered was [Ru(NH3)5(N2)]2+ (see figure at right), and soon many other such complexes were discovered. These complexes, in which a nitrogen molecule donates at least one lone pair of electrons to a central metal cation, illustrate how N2 might bind to the metal(s) in nitrogenase and the catalyst for the Haber process: these processes involving dinitrogen activation are vitally important in biology and in the production of fertilisers.[50][51]

Dinitrogen is able to coordinate to metals in five different ways. The more well-characterised ways are the end-on M←N≡N (η1) and M←N≡N→M (μ, bis-η1), in which the lone pairs on the nitrogen atoms are donated to the metal cation. The less well-characterised ways involve dinitrogen donating electron pairs from the triple bond, either as a bridging ligand to two metal cations (μ, bis-η2) or to just one (η2). The fifth and unique method involves triple-coordination as a bridging ligand, donating all three electron pairs from the triple bond (μ3-N2). A few complexes feature multiple N2 ligands and some feature N2 bonded in multiple ways. Since N2 is isoelectronic with carbon monoxide (CO) and acetylene (C2H2), the bonding in dinitrogen complexes is closely allied to that in carbonyl compounds, although N2 is a weaker σ-donor and π-acceptor than CO. Theoretical studies show that σ donation is a more important factor allowing the formation of the M–N bond than π back-donation, which mostly only weakens the N–N bond, and end-on (η1) donation is more readily accomplished than side-on (η2) donation.[25]

Today, dinitrogen complexes are known for almost all the transition metals, accounting for several hundred compounds. They are normally prepared by three methods:[25]

  1. Replacing labile ligands such as H2O, H, or CO directly by nitrogen: these are often reversible reactions that proceed at mild conditions.
  2. Reducing metal complexes in the presence of a suitable co-ligand in excess under nitrogen gas. A common choice includes replacing chloride ligands with dimethylphenylphosphine (PMe2Ph) to make up for the smaller number of nitrogen ligands attached to the original chlorine ligands.
  3. Converting a ligand with N–N bonds, such as hydrazine or azide, directly into a dinitrogen ligand.

Occasionally the N≡N bond may be formed directly within a metal complex, for example by directly reacting coordinated ammonia (NH3) with nitrous acid (HNO2), but this is not generally applicable. Most dinitrogen complexes have colours within the range white-yellow-orange-red-brown; a few exceptions are known, such as the blue [{Ti(η5-C5H5)2}2-(N2)].[25]

Nitrides, azides, and nitrido complexes

Nitrogen bonds to almost all the elements in the periodic table except the first three noble gases, helium, neon, and argon, and some of the very short-lived elements after bismuth, creating an immense variety of binary compounds with varying properties and applications in which pentazenium tetraazidoborate has the highest nitrogen content.[25] Many binary compounds are known: with the exception of the nitrogen hydrides, oxides, and fluorides, these are typically called nitrides. Many stoichiometric phases are usually present for most elements (e.g. MnN, Mn6N5, Mn3N2, Mn2N, Mn4N, and MnxN for 9.2 < x < 25.3). They may be classified as "salt-like" (mostly ionic), covalent, "diamond-like", and metallic (or interstitial), although this classification has limitations generally stemming from the continuity of bonding types instead of the discrete and separate types that it implies. They are normally prepared by directly reacting a metal with nitrogen or ammonia (sometimes after heating), or by thermal decomposition of metal amides:[52]

3 Ca + N2 → Ca3N2
3 Mg + 2 NH3 → Mg3N2 + 3 H2 (at 900 °C)
3 Zn(NH2)2 → Zn3N2 + 4 NH3

Many variants on these processes are possible. The most ionic of these nitrides are those of the alkali metals and alkaline earth metals, Li3N (Na, K, Rb, and Cs do not form stable nitrides for steric reasons) and M3N2 (M = Be, Mg, Ca, Sr, Ba). These can formally be thought of as salts of the N3− anion, although charge separation is not actually complete even for these highly electropositive elements. However, the alkali metal azides NaN3 and KN3, featuring the linear N
3 anion, are well-known, as are Sr(N3)2 and Ba(N3)2. Azides of the B-subgroup metals (those in groups 11 through 16) are much less ionic, have more complicated structures, and detonate readily when shocked.[52]

 
Mesomeric structures of borazine, (–BH–NH–)3

Many covalent binary nitrides are known. Examples include cyanogen ((CN)2), triphosphorus pentanitride (P3N5), disulfur dinitride (S2N2), and tetrasulfur tetranitride (S4N4). The essentially covalent silicon nitride (Si3N4) and germanium nitride (Ge3N4) are also known: silicon nitride, in particular, would make a promising ceramic if not for the difficulty of working with and sintering it. In particular, the group 13 nitrides, most of which are promising semiconductors, are isoelectronic with graphite, diamond, and silicon carbide and have similar structures: their bonding changes from covalent to partially ionic to metallic as the group is descended. In particular, since the B–N unit is isoelectronic to C–C, and carbon is essentially intermediate in size between boron and nitrogen, much of organic chemistry finds an echo in boron–nitrogen chemistry, such as in borazine ("inorganic benzene"). Nevertheless, the analogy is not exact due to the ease of nucleophilic attack at boron due to its deficiency in electrons, which is not possible in a wholly carbon-containing ring.[52]

The largest category of nitrides are the interstitial nitrides of formulae MN, M2N, and M4N (although variable composition is perfectly possible), where the small nitrogen atoms are positioned in the gaps in a metallic cubic or hexagonal close-packed lattice. They are opaque, very hard, and chemically inert, melting only at very high temperatures (generally over 2500 °C). They have a metallic lustre and conduct electricity as do metals. They hydrolyse only very slowly to give ammonia or nitrogen.[52]

The nitride anion (N3−) is the strongest π donor known among ligands (the second-strongest is O2−). Nitrido complexes are generally made by the thermal decomposition of azides or by deprotonating ammonia, and they usually involve a terminal {≡N}3− group. The linear azide anion (N
3), being isoelectronic with nitrous oxide, carbon dioxide, and cyanate, forms many coordination complexes. Further catenation is rare, although N4−
4 (isoelectronic with carbonate and nitrate) is known.[52]

Hydrides

 
Standard reduction potentials for nitrogen-containing species. Top diagram shows potentials at pH 0; bottom diagram shows potentials at pH 14.[53]

Industrially, ammonia (NH3) is the most important compound of nitrogen and is prepared in larger amounts than any other compound because it contributes significantly to the nutritional needs of terrestrial organisms by serving as a precursor to food and fertilisers. It is a colourless alkaline gas with a characteristic pungent smell. The presence of hydrogen bonding has very significant effects on ammonia, conferring on it its high melting (−78 °C) and boiling (−33 °C) points. As a liquid, it is a very good solvent with a high heat of vaporisation (enabling it to be used in vacuum flasks), that also has a low viscosity and electrical conductivity and high dielectric constant, and is less dense than water. However, the hydrogen bonding in NH3 is weaker than that in H2O due to the lower electronegativity of nitrogen compared to oxygen and the presence of only one lone pair in NH3 rather than two in H2O. It is a weak base in aqueous solution (pKb 4.74); its conjugate acid is ammonium, NH+
4. It can also act as an extremely weak acid, losing a proton to produce the amide anion, NH
2. It thus undergoes self-dissociation, similar to water, to produce ammonium and amide. Ammonia burns in air or oxygen, though not readily, to produce nitrogen gas; it burns in fluorine with a greenish-yellow flame to give nitrogen trifluoride. Reactions with the other nonmetals are very complex and tend to lead to a mixture of products. Ammonia reacts on heating with metals to give nitrides.[54]

Many other binary nitrogen hydrides are known, but the most important are hydrazine (N2H4) and hydrogen azide (HN3). Although it is not a nitrogen hydride, hydroxylamine (NH2OH) is similar in properties and structure to ammonia and hydrazine as well. Hydrazine is a fuming, colourless liquid that smells similar to ammonia. Its physical properties are very similar to those of water (melting point 2.0 °C, boiling point 113.5 °C, density 1.00 g/cm3). Despite it being an endothermic compound, it is kinetically stable. It burns quickly and completely in air very exothermically to give nitrogen and water vapour. It is a very useful and versatile reducing agent and is a weaker base than ammonia.[55] It is also commonly used as a rocket fuel.[56]

Hydrazine is generally made by reaction of ammonia with alkaline sodium hypochlorite in the presence of gelatin or glue:[55]

NH3 + OCl → NH2Cl + OH
NH2Cl + NH3N
2H+
5 + Cl (slow)
N
2H+
5 + OH → N2H4 + H2O (fast)

(The attacks by hydroxide and ammonia may be reversed, thus passing through the intermediate NHCl instead.) The reason for adding gelatin is that it removes metal ions such as Cu2+ that catalyses the destruction of hydrazine by reaction with monochloramine (NH2Cl) to produce ammonium chloride and nitrogen.[55]

Hydrogen azide (HN3) was first produced in 1890 by the oxidation of aqueous hydrazine by nitrous acid. It is very explosive and even dilute solutions can be dangerous. It has a disagreeable and irritating smell and is a potentially lethal (but not cumulative) poison. It may be considered the conjugate acid of the azide anion, and is similarly analogous to the hydrohalic acids.[55]

Halides and oxohalides

All four simple nitrogen trihalides are known. A few mixed halides and hydrohalides are known, but are mostly unstable; examples include NClF2, NCl2F, NBrF2, NF2H, NFH2, NCl2H, and NClH2.[57]

Nitrogen trifluoride (NF3, first prepared in 1928) is a colourless and odourless gas that is thermodynamically stable, and most readily produced by the electrolysis of molten ammonium fluoride dissolved in anhydrous hydrogen fluoride. Like carbon tetrafluoride, it is not at all reactive and is stable in water or dilute aqueous acids or alkalis. Only when heated does it act as a fluorinating agent, and it reacts with copper, arsenic, antimony, and bismuth on contact at high temperatures to give tetrafluorohydrazine (N2F4). The cations NF+
4 and N
2F+
3 are also known (the latter from reacting tetrafluorohydrazine with strong fluoride-acceptors such as arsenic pentafluoride), as is ONF3, which has aroused interest due to the short N–O distance implying partial double bonding and the highly polar and long N–F bond. Tetrafluorohydrazine, unlike hydrazine itself, can dissociate at room temperature and above to give the radical NF2•. Fluorine azide (FN3) is very explosive and thermally unstable. Dinitrogen difluoride (N2F2) exists as thermally interconvertible cis and trans isomers, and was first found as a product of the thermal decomposition of FN3.[57]

Nitrogen trichloride (NCl3) is a dense, volatile, and explosive liquid whose physical properties are similar to those of carbon tetrachloride, although one difference is that NCl3 is easily hydrolysed by water while CCl4 is not. It was first synthesised in 1811 by Pierre Louis Dulong, who lost three fingers and an eye to its explosive tendencies. As a dilute gas it is less dangerous and is thus used industrially to bleach and sterilise flour. Nitrogen tribromide (NBr3), first prepared in 1975, is a deep red, temperature-sensitive, volatile solid that is explosive even at −100 °C. Nitrogen triiodide (NI3) is still more unstable and was only prepared in 1990. Its adduct with ammonia, which was known earlier, is very shock-sensitive: it can be set off by the touch of a feather, shifting air currents, or even alpha particles.[57][58] For this reason, small amounts of nitrogen triiodide are sometimes synthesised as a demonstration to high school chemistry students or as an act of "chemical magic".[59] Chlorine azide (ClN3) and bromine azide (BrN3) are extremely sensitive and explosive.[60][61]

Two series of nitrogen oxohalides are known: the nitrosyl halides (XNO) and the nitryl halides (XNO2). The first is very reactive gases that can be made by directly halogenating nitrous oxide. Nitrosyl fluoride (NOF) is colourless and a vigorous fluorinating agent. Nitrosyl chloride (NOCl) behaves in much the same way and has often been used as an ionising solvent. Nitrosyl bromide (NOBr) is red. The reactions of the nitryl halides are mostly similar: nitryl fluoride (FNO2) and nitryl chloride (ClNO2) are likewise reactive gases and vigorous halogenating agents.[57]

Oxides

Main article: Nitrogen oxide
 
Nitrogen dioxide at −196 °C, 0 °C, 23 °C, 35 °C, and 50 °C. NO
2 converts to colourless dinitrogen tetroxide (N
2O
4) at low temperatures, and reverts to NO
2 at higher temperatures.

Nitrogen forms nine molecular oxides, some of which were the first gases to be identified: N2O (nitrous oxide), NO (nitric oxide), N2O3 (dinitrogen trioxide), NO2 (nitrogen dioxide), N2O4 (dinitrogen tetroxide), N2O5 (dinitrogen pentoxide), N4O (nitrosylazide),[62] and N(NO2)3 (trinitramide).[63] All are thermally unstable towards decomposition to their elements. One other possible oxide that has not yet been synthesised is oxatetrazole (N4O), an aromatic ring.[62]

Nitrous oxide (N2O), better known as laughing gas, is made by thermal decomposition of molten ammonium nitrate at 250 °C. This is a redox reaction and thus nitric oxide and nitrogen are also produced as byproducts. It is mostly used as a propellant and aerating agent for sprayed canned whipped cream, and was formerly commonly used as an anaesthetic. Despite appearances, it cannot be considered to be the anhydride of hyponitrous acid (H2N2O2) because that acid is not produced by the dissolution of nitrous oxide in water. It is rather unreactive (not reacting with the halogens, the alkali metals, or ozone at room temperature, although reactivity increases upon heating) and has the unsymmetrical structure N–N–O (N≡N+ON=N+=O): above 600 °C it dissociates by breaking the weaker N–O bond.[62] Nitric oxide (NO) is the simplest stable molecule with an odd number of electrons. In mammals, including humans, it is an important cellular signaling molecule involved in many physiological and pathological processes.[64] It is formed by catalytic oxidation of ammonia. It is a colourless paramagnetic gas that, being thermodynamically unstable, decomposes to nitrogen and oxygen gas at 1100–1200 °C. Its bonding is similar to that in nitrogen, but one extra electron is added to a π* antibonding orbital and thus the bond order has been reduced to approximately 2.5; hence dimerisation to O=N–N=O is unfavourable except below the boiling point (where the cis isomer is more stable) because it does not actually increase the total bond order and because the unpaired electron is delocalised across the NO molecule, granting it stability. There is also evidence for the asymmetric red dimer O=N–O=N when nitric oxide is condensed with polar molecules. It reacts with oxygen to give brown nitrogen dioxide and with halogens to give nitrosyl halides. It also reacts with transition metal compounds to give nitrosyl complexes, most of which are deeply coloured.[62]

Blue dinitrogen trioxide (N2O3) is only available as a solid because it rapidly dissociates above its melting point to give nitric oxide, nitrogen dioxide (NO2), and dinitrogen tetroxide (N2O4). The latter two compounds are somewhat difficult to study individually because of the equilibrium between them, although sometimes dinitrogen tetroxide can react by heterolytic fission to nitrosonium and nitrate in a medium with high dielectric constant. Nitrogen dioxide is an acrid, corrosive brown gas. Both compounds may be easily prepared by decomposing a dry metal nitrate. Both react with water to form nitric acid. Dinitrogen tetroxide is very useful for the preparation of anhydrous metal nitrates and nitrato complexes, and it became the storable oxidiser of choice for many rockets in both the United States and USSR by the late 1950s. This is because it is a hypergolic propellant in combination with a hydrazine-based rocket fuel and can be easily stored since it is liquid at room temperature.[62]

The thermally unstable and very reactive dinitrogen pentoxide (N2O5) is the anhydride of nitric acid, and can be made from it by dehydration with phosphorus pentoxide. It is of interest for the preparation of explosives.[65] It is a deliquescent, colourless crystalline solid that is sensitive to light. In the solid state it is ionic with structure [NO2]+[NO3]; as a gas and in solution it is molecular O2N–O–NO2. Hydration to nitric acid comes readily, as does analogous reaction with hydrogen peroxide giving peroxonitric acid (HOONO2). It is a violent oxidising agent. Gaseous dinitrogen pentoxide decomposes as follows:[62]

N2O5 ⇌ NO2 + NO3 → NO2 + O2 + NO
N2O5 + NO ⇌ 3 NO2

Oxoacids, oxoanions, and oxoacid salts

Many nitrogen oxoacids are known, though most of them are unstable as pure compounds and are known only as aqueous solutions or as salts. Hyponitrous acid (H2N2O2) is a weak diprotic acid with the structure HON=NOH (pKa1 6.9, pKa2 11.6). Acidic solutions are quite stable but above pH 4 base-catalysed decomposition occurs via [HONNO] to nitrous oxide and the hydroxide anion. Hyponitrites (involving the N
2O2−
2 anion) are stable to reducing agents and more commonly act as reducing agents themselves. They are an intermediate step in the oxidation of ammonia to nitrite, which occurs in the nitrogen cycle. Hyponitrite can act as a bridging or chelating bidentate ligand.[66]

Nitrous acid (HNO2) is not known as a pure compound, but is a common component in gaseous equilibria and is an important aqueous reagent: its aqueous solutions may be made from acidifying cool aqueous nitrite (NO
2, bent) solutions, although already at room temperature disproportionation to nitrate and nitric oxide is significant. It is a weak acid with pKa 3.35 at 18 °C. They may be titrimetrically analysed by their oxidation to nitrate by permanganate. They are readily reduced to nitrous oxide and nitric oxide by sulfur dioxide, to hyponitrous acid with tin(II), and to ammonia with hydrogen sulfide. Salts of hydrazinium N
2H+
5 react with nitrous acid to produce azides which further react to give nitrous oxide and nitrogen. Sodium nitrite is mildly toxic in concentrations above 100 mg/kg, but small amounts are often used to cure meat and as a preservative to avoid bacterial spoilage. It is also used to synthesise hydroxylamine and to diazotise primary aromatic amines as follows:[66]

ArNH2 + HNO2 → [ArNN]Cl + 2 H2O

Nitrite is also a common ligand that can coordinate in five ways. The most common are nitro (bonded from the nitrogen) and nitrito (bonded from an oxygen). Nitro-nitrito isomerism is common, where the nitrito form is usually less stable.[66]

 
Fuming nitric acid contaminated with yellow nitrogen dioxide

Nitric acid (HNO3) is by far the most important and the most stable of the nitrogen oxoacids. It is one of the three most used acids (the other two being sulfuric acid and hydrochloric acid) and was first discovered by alchemists in the 13th century. It is made by the catalytic oxidation of ammonia to nitric oxide, which is oxidised to nitrogen dioxide, and then dissolved in water to give concentrated nitric acid. In the United States of America, over seven million tonnes of nitric acid are produced every year, most of which is used for nitrate production for fertilisers and explosives, among other uses. Anhydrous nitric acid may be made by distilling concentrated nitric acid with phosphorus pentoxide at low pressure in glass apparatus in the dark. It can only be made in the solid state, because upon melting it spontaneously decomposes to nitrogen dioxide, and liquid nitric acid undergoes self-ionisation to a larger extent than any other covalent liquid as follows:[66]

2 HNO3H
2NO+
3 + NO
3 ⇌ H2O + [NO2]+ + [NO3]

Two hydrates, HNO3·H2O and HNO3·3H2O, are known that can be crystallised. It is a strong acid and concentrated solutions are strong oxidising agents, though gold, platinum, rhodium, and iridium are immune to attack. A 3:1 mixture of concentrated hydrochloric acid and nitric acid, called aqua regia, is still stronger and successfully dissolves gold and platinum, because free chlorine and nitrosyl chloride are formed and chloride anions can form strong complexes. In concentrated sulfuric acid, nitric acid is protonated to form nitronium, which can act as an electrophile for aromatic nitration:[66]

HNO3 + 2 H2SO4NO+
2 + H3O+ + 2 HSO
4

The thermal stabilities of nitrates (involving the trigonal planar NO
3 anion) depends on the basicity of the metal, and so do the products of decomposition (thermolysis), which can vary between the nitrite (for example, sodium), the oxide (potassium and lead), or even the metal itself (silver) depending on their relative stabilities. Nitrate is also a common ligand with many modes of coordination.[66]

Finally, although orthonitric acid (H3NO4), which would be analogous to orthophosphoric acid, does not exist, the tetrahedral orthonitrate anion NO3−
4 is known in its sodium and potassium salts:[66]

 

These white crystalline salts are very sensitive to water vapour and carbon dioxide in the air:[66]

Na3NO4 + H2O + CO2 → NaNO3 + NaOH + NaHCO3

Despite its limited chemistry, the orthonitrate anion is interesting from a structural point of view due to its regular tetrahedral shape and the short N–O bond lengths, implying significant polar character to the bonding.[66]

Organic nitrogen compounds

Nitrogen is one of the most important elements in organic chemistry. Many organic functional groups involve a carbon–nitrogen bond, such as amides (RCONR2), amines (R3N), imines (RC(=NR)R), imides (RCO)2NR, azides (RN3), azo compounds (RN2R), cyanates and isocyanates (ROCN or RCNO), nitrates (RONO2), nitriles and isonitriles (RCN or RNC), nitrites (RONO), nitro compounds (RNO2), nitroso compounds (RNO), oximes (RCR=NOH), and pyridine derivatives. C–N bonds are strongly polarised towards nitrogen. In these compounds, nitrogen is usually trivalent (though it can be tetravalent in quaternary ammonium salts, R4N+), with a lone pair that can confer basicity on the compound by being coordinated to a proton. This may be offset by other factors: for example, amides are not basic because the lone pair is delocalised into a double bond (though they may act as acids at very low pH, being protonated at the oxygen), and pyrrole is not acidic because the lone pair is delocalised as part of an aromatic ring.[67] The amount of nitrogen in a chemical substance can be determined by the Kjeldahl method.[68] In particular, nitrogen is an essential component of nucleic acids, amino acids and thus proteins, and the energy-carrying molecule adenosine triphosphate and is thus vital to all life on Earth.[67]

Occurrence

 
Schematic representation of the flow of nitrogen compounds through a land environment
See also: Nitrogen cycle

Nitrogen is the most common pure element in the earth, making up 78.1% of the volume of the atmosphere[6] (75.5% by mass), around 3.89 million gigatonnes. Despite this, it is not very abundant in Earth's crust, making up somewhere around 19 parts per million of this, on par with niobium, gallium, and lithium. (This represents 300,000 to a million gigatonnes of nitrogen, depending on the mass of the crust.[69]) The only important nitrogen minerals are nitre (potassium nitrate, saltpetre) and soda nitre (sodium nitrate, Chilean saltpetre). However, these have not been an important source of nitrates since the 1920s, when the industrial synthesis of ammonia and nitric acid became common.[70]

Nitrogen compounds constantly interchange between the atmosphere and living organisms. Nitrogen must first be processed, or "fixed", into a plant-usable form, usually ammonia. Some nitrogen fixation is done by lightning strikes producing the nitrogen oxides, but most is done by diazotrophic bacteria through enzymes known as nitrogenases (although today industrial nitrogen fixation to ammonia is also significant). When the ammonia is taken up by plants, it is used to synthesise proteins. These plants are then digested by animals who use the nitrogen compounds to synthesise their proteins and excrete nitrogen-bearing waste. Finally, these organisms die and decompose, undergoing bacterial and environmental oxidation and denitrification, returning free dinitrogen to the atmosphere. Industrial nitrogen fixation by the Haber process is mostly used as fertiliser, although excess nitrogen–bearing waste, when leached, leads to eutrophication of freshwater and the creation of marine dead zones, as nitrogen-driven bacterial growth depletes water oxygen to the point that all higher organisms die. Furthermore, nitrous oxide, which is produced during denitrification, attacks the atmospheric ozone layer.[70]

Many saltwater fish manufacture large amounts of trimethylamine oxide to protect them from the high osmotic effects of their environment; conversion of this compound to dimethylamine is responsible for the early odour in unfresh saltwater fish.[71] In animals, free radical nitric oxide (derived from an amino acid), serves as an important regulatory molecule for circulation.[72]

Nitric oxide's rapid reaction with water in animals results in the production of its metabolite nitrite. Animal metabolism of nitrogen in proteins, in general, results in the excretion of urea, while animal metabolism of nucleic acids results in the excretion of urea and uric acid. The characteristic odour of animal flesh decay is caused by the creation of long-chain, nitrogen-containing amines, such as putrescine and cadaverine, which are breakdown products of the amino acids ornithine and lysine, respectively, in decaying proteins.[73]

Production

Nitrogen gas is an industrial gas produced by the fractional distillation of liquid air, or by mechanical means using gaseous air (pressurised reverse osmosis membrane or pressure swing adsorption). Nitrogen gas generators using membranes or pressure swing adsorption (PSA) are typically more cost and energy efficient than bulk-delivered nitrogen.[74] Commercial nitrogen is often a byproduct of air-processing for industrial concentration of oxygen for steelmaking and other purposes. When supplied compressed in cylinders it is often called OFN (oxygen-free nitrogen).[75] Commercial-grade nitrogen already contains at most 20 ppm oxygen, and specially purified grades containing at most 2 ppm oxygen and 10 ppm argon are also available.[76]

In a chemical laboratory, it is prepared by treating an aqueous solution of ammonium chloride with sodium nitrite.[77]

NH4Cl + NaNO2 → N2 + NaCl + 2 H2O

Small amounts of the impurities NO and HNO3 are also formed in this reaction. The impurities can be removed by passing the gas through aqueous sulfuric acid containing potassium dichromate.[77] Very pure nitrogen can be prepared by the thermal decomposition of barium azide or sodium azide.[78]

2 NaN3 → 2 Na + 3 N2

Applications

Gas

The applications of nitrogen compounds are naturally extremely widely varied due to the huge size of this class: hence, only applications of pure nitrogen itself will be considered here. Two-thirds (2/3) of nitrogen produced by industry is sold as gas and the remaining one-third (1/3) as a liquid.

The gas is mostly used as a low reactivity safe atmosphere wherever the oxygen in the air would pose a fire, explosion, or oxidising hazard. Some examples include:[76]

Nitrogen is commonly used during sample preparation in chemical analysis. It is used to concentrate and reduce the volume of liquid samples. Directing a pressurised stream of nitrogen gas perpendicular to the surface of the liquid causes the solvent to evaporate while leaving the solute(s) and un-evaporated solvent behind.[84]

Nitrogen can be used as a replacement, or in combination with, carbon dioxide to pressurise kegs of some beers, particularly stouts and British ales, due to the smaller bubbles it produces, which makes the dispensed beer smoother and headier.[85] A pressure-sensitive nitrogen capsule known commonly as a "widget" allows nitrogen-charged beers to be packaged in cans and bottles.[86][87] Nitrogen tanks are also replacing carbon dioxide as the main power source for paintball guns. Nitrogen must be kept at a higher pressure than CO2, making N2 tanks heavier and more expensive.[88]

Equipment

Some construction equipment uses pressurized nitrogen gas to help hydraulic system to provide extra power to devices such as hydraulic hammer. Nitrogen gas, formed from the decomposition of sodium azide, is used for the inflation of airbags.[89]

Execution

As nitrogen is an asphyxiant gas, some jurisdictions have considered asphyxiation by inhalation of pure nitrogen as a means of capital punishment (as a substitute for lethal injection).[90][91][92]

However, as of 2020, no executions using nitrogen gas have yet been carried out by any jurisdiction, and at least one jurisdiction (Oklahoma) which had considered nitrogen asphyxiation as an execution protocol had abandoned the effort.[93]

Liquid

Air balloon submerged in liquid nitrogen

Liquid nitrogen is a cryogenic liquid which looks like water. When insulated in proper containers such as dewar flasks, it can be transported and stored with a low rate of evaporative loss.[94]

 
A container vehicle carrying liquid nitrogen.

Like dry ice, the main use of liquid nitrogen is for cooling to low temperatures. It is used in the cryopreservation of biological materials such as blood and reproductive cells (sperm and eggs). It is used in cryotherapy to remove cysts and warts on the skin by freezing them.[95] It is used in laboratory cold traps, and in cryopumps to obtain lower pressures in vacuum pumped systems. It is used to cool heat-sensitive electronics such as infrared detectors and X-ray detectors. Other uses include freeze-grinding and machining materials that are soft or rubbery at room temperature, shrink-fitting and assembling engineering components, and more generally to attain very low temperatures where necessary. Because of its low cost, liquid nitrogen is often used for cooling even when such low temperatures are not strictly necessary, such as refrigeration of food, freeze-branding livestock, freezing pipes to halt flow when valves are not present, and consolidating unstable soil by freezing whenever excavation is going on underneath.[76]

Safety

Gas

Although nitrogen is non-toxic, when released into an enclosed space it can displace oxygen, and therefore presents an asphyxiation hazard. This may happen with few warning symptoms, since the human carotid body is a relatively poor and slow low-oxygen (hypoxia) sensing system.[96] An example occurred shortly before the launch of the first Space Shuttle mission on March 19, 1981, when two technicians died from asphyxiation after they walked into a space located in the Space Shuttle's mobile launcher platform that was pressurised with pure nitrogen as a precaution against fire.[97]

When inhaled at high partial pressures (more than about 4 bar, encountered at depths below about 30 m in scuba diving), nitrogen is an anesthetic agent, causing nitrogen narcosis, a temporary state of mental impairment similar to nitrous oxide intoxication.[98][99]

Nitrogen dissolves in the blood and body fats. Rapid decompression (as when divers ascend too quickly or astronauts decompress too quickly from cabin pressure to spacesuit pressure) can lead to a potentially fatal condition called decompression sickness (formerly known as caisson sickness or the bends), when nitrogen bubbles form in the bloodstream, nerves, joints, and other sensitive or vital areas.[100][101] Bubbles from other "inert" gases (gases other than carbon dioxide and oxygen) cause the same effects, so replacement of nitrogen in breathing gases may prevent nitrogen narcosis, but does not prevent decompression sickness.[102]

Liquid

As a cryogenic liquid, liquid nitrogen can be dangerous by causing cold burns on contact, although the Leidenfrost effect provides protection for very short exposure (about one second).[103] Ingestion of liquid nitrogen can cause severe internal damage. For example, in 2012, a young woman in England had to have her stomach removed after ingesting a cocktail made with liquid nitrogen.[104]

Because the liquid-to-gas expansion ratio of nitrogen is 1:694 at 20 °C, a tremendous amount of force can be generated if liquid nitrogen is rapidly vaporised in an enclosed space. In an incident on January 12, 2006, at Texas A&M University, the pressure-relief devices of a tank of liquid nitrogen were malfunctioning and later sealed. As a result of the subsequent pressure buildup, the tank failed catastrophically. The force of the explosion was sufficient to propel the tank through the ceiling immediately above it, shatter a reinforced concrete beam immediately below it, and blow the walls of the laboratory 0.1–0.2 m off their foundations.[105]

Liquid nitrogen readily evaporates to form gaseous nitrogen, and hence the precautions associated with gaseous nitrogen also apply to liquid nitrogen.[106][107][108] For example, oxygen sensors are sometimes used as a safety precaution when working with liquid nitrogen to alert workers of gas spills into a confined space.[109]

Vessels containing liquid nitrogen can condense oxygen from air. The liquid in such a vessel becomes increasingly enriched in oxygen (boiling point −183 °C, higher than that of nitrogen) as the nitrogen evaporates, and can cause violent oxidation of organic material.[110]

Oxygen deficiency monitors

Oxygen deficiency monitors are used to measure levels of oxygen in confined spaces and any place where nitrogen gas or liquid are stored or used. In the event of a nitrogen leak, and a decrease in oxygen to a pre-set alarm level, an oxygen deficiency monitor can be programmed to set off audible and visual alarms, thereby providing notification of the possible impending danger. Most commonly the oxygen range to alert personnel is when oxygen levels get below 19.5%. OSHA specifies that a hazardous atmosphere may include one where the oxygen concentration is below 19.5% or above 23.5%.[111] Oxygen deficiency monitors can either be fixed, mounted to the wall and hard-wired into the building's power supply or simply plugged into a power outlet, or a portable hand-held or wearable monitor.

See also

References

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Bibliography

External links

January 31, 2023
nitrogen, chemical, element, with, symbol, atomic, number, nonmetal, lightest, member, group, periodic, table, often, called, pnictogens, common, element, universe, estimated, seventh, total, abundance, milky, solar, system, standard, temperature, pressure, at. Nitrogen is the chemical element with the symbol N and atomic number 7 Nitrogen is a nonmetal and the lightest member of group 15 of the periodic table often called the pnictogens It is a common element in the universe estimated at seventh in total abundance in the Milky Way and the Solar System At standard temperature and pressure two atoms of the element bond to form N2 a colorless and odorless diatomic gas N2 forms about 78 of Earth s atmosphere making it the most abundant uncombined element Nitrogen occurs in all organisms primarily in amino acids and thus proteins in the nucleic acids DNA and RNA and in the energy transfer molecule adenosine triphosphate The human body contains about 3 nitrogen by mass the fourth most abundant element in the body after oxygen carbon and hydrogen The nitrogen cycle describes the movement of the element from the air into the biosphere and organic compounds then back into the atmosphere Nitrogen 7NLiquid nitrogen N2 at lt 196 C NitrogenAllotropessee AllotropesAppearancecolorless gas liquid or solidStandard atomic weight Ar N 14 00643 14 00728 14 007 0 001 abridged 1 Nitrogen in the periodic tableHydrogen HeliumLithium Beryllium Boron Carbon Nitrogen Oxygen Fluorine NeonSodium Magnesium Aluminium Silicon Phosphorus Sulfur Chlorine ArgonPotassium Calcium Scandium Titanium Vanadium Chromium Manganese Iron Cobalt Nickel Copper Zinc Gallium Germanium Arsenic Selenium Bromine KryptonRubidium Strontium Yttrium Zirconium Niobium Molybdenum Technetium Ruthenium Rhodium Palladium Silver Cadmium Indium Tin Antimony Tellurium Iodine XenonCaesium Barium Lanthanum Cerium Praseodymium Neodymium Promethium Samarium Europium Gadolinium Terbium Dysprosium Holmium Erbium Thulium Ytterbium Lutetium Hafnium Tantalum Tungsten Rhenium Osmium Iridium Platinum Gold Mercury element Thallium Lead Bismuth Polonium Astatine RadonFrancium Radium Actinium Thorium Protactinium Uranium Neptunium Plutonium Americium Curium Berkelium Californium Einsteinium Fermium Mendelevium Nobelium Lawrencium Rutherfordium Dubnium Seaborgium Bohrium Hassium Meitnerium Darmstadtium Roentgenium Copernicium Nihonium Flerovium Moscovium Livermorium Tennessine Oganesson N Pcarbon nitrogen oxygenAtomic number Z 7Groupgroup 15 pnictogens Periodperiod 2Block p blockElectron configuration He 2s2 2p3Electrons per shell2 5Physical propertiesPhase at STPgasMelting point N2 63 23 2 K 209 86 2 C 345 75 2 F Boiling point N2 77 355 K 195 795 C 320 431 F Density at STP 1 2506 g L 3 at 0 C 1013 mbarwhen liquid at b p 0 808 g cm3Triple point63 151 K 12 52 kPaCritical point126 21 K 3 39 MPaHeat of fusion N2 0 72 kJ molHeat of vaporisation N2 5 57 kJ molMolar heat capacity N2 29 124 J mol K Vapour pressureP Pa 1 10 100 1 k 10 k 100 kat T K 37 41 46 53 62 77Atomic propertiesOxidation states 3 2 1 0 4 1 2 3 4 5 a strongly acidic oxide ElectronegativityPauling scale 3 04Ionisation energies1st 1402 3 kJ mol2nd 2856 kJ mol3rd 4578 1 kJ mol more Covalent radius71 1 pmVan der Waals radius155 pmSpectral lines of nitrogenOther propertiesNatural occurrenceprimordialCrystal structure hexagonalSpeed of sound353 m s gas at 27 C Thermal conductivity25 83 10 3 W m K Magnetic orderingdiamagneticCAS Number17778 88 0 7727 37 9 N2 HistoryDiscoveryDaniel Rutherford 1772 Named byJean Antoine Chaptal 1790 Main isotopes of nitrogenveIso tope Decayabun dance half life t1 2 mode pro duct13N syn 9 965 min b 13C14N 99 578 99 663 stable15N 0 337 0 422 stable Category Nitrogenviewtalkedit referencesMany industrially important compounds such as ammonia nitric acid organic nitrates propellants and explosives and cyanides contain nitrogen The extremely strong triple bond in elemental nitrogen N N the second strongest bond in any diatomic molecule after carbon monoxide CO 5 dominates nitrogen chemistry This causes difficulty for both organisms and industry in converting N2 into useful compounds but at the same time it means that burning exploding or decomposing nitrogen compounds to form nitrogen gas releases large amounts of often useful energy Synthetically produced ammonia and nitrates are key industrial fertilisers and fertiliser nitrates are key pollutants in the eutrophication of water systems It was first discovered and isolated by Scottish physician Daniel Rutherford in 1772 Although Carl Wilhelm Scheele and Henry Cavendish had independently done so at about the same time Rutherford is generally accorded the credit because his work was published first The name nitrogene was suggested by French chemist Jean Antoine Claude Chaptal in 1790 when it was found that nitrogen was present in nitric acid and nitrates Antoine Lavoisier suggested instead the name azote from the Ancient Greek ἀzwtikos no life as it is an asphyxiant gas this name is used in several languages including French Italian Russian Romanian Portuguese and Turkish and appears in the English names of some nitrogen compounds such as hydrazine azides and azo compounds Apart from its use in fertilisers and energy stores nitrogen is a constituent of organic compounds as diverse as Kevlar used in high strength fabric and cyanoacrylate used in superglue Nitrogen is a constituent of every major pharmacological drug class including antibiotics Many drugs are mimics or prodrugs of natural nitrogen containing signal molecules for example the organic nitrates nitroglycerin and nitroprusside control blood pressure by metabolizing into nitric oxide Many notable nitrogen containing drugs such as the natural caffeine and morphine or the synthetic amphetamines act on receptors of animal neurotransmitters Contents 1 History 2 Properties 2 1 Atomic 2 2 Isotopes 3 Chemistry and compounds 3 1 Allotropes 3 2 Dinitrogen complexes 3 3 Nitrides azides and nitrido complexes 3 4 Hydrides 3 5 Halides and oxohalides 3 6 Oxides 3 7 Oxoacids oxoanions and oxoacid salts 3 8 Organic nitrogen compounds 4 Occurrence 5 Production 6 Applications 6 1 Gas 6 1 1 Equipment 6 1 2 Execution 6 2 Liquid 7 Safety 7 1 Gas 7 2 Liquid 7 3 Oxygen deficiency monitors 8 See also 9 References 10 Bibliography 11 External linksHistory Daniel Rutherford discoverer of nitrogen Nitrogen compounds have a very long history ammonium chloride having been known to Herodotus They were well known by the Middle Ages Alchemists knew nitric acid as aqua fortis strong water as well as other nitrogen compounds such as ammonium salts and nitrate salts The mixture of nitric and hydrochloric acids was known as aqua regia royal water celebrated for its ability to dissolve gold the king of metals 6 The discovery of nitrogen is attributed to the Scottish physician Daniel Rutherford in 1772 who called it noxious air 7 8 Though he did not recognise it as an entirely different chemical substance he clearly distinguished it from Joseph Black s fixed air or carbon dioxide 9 The fact that there was a component of air that does not support combustion was clear to Rutherford although he was not aware that it was an element Nitrogen was also studied at about the same time by Carl Wilhelm Scheele 10 Henry Cavendish 11 and Joseph Priestley 12 who referred to it as burnt air or phlogisticated air French chemist Antoine Lavoisier referred to nitrogen gas as mephitic air or azote from the Greek word azwtikos azotikos no life due to it being asphyxiant 13 14 In an atmosphere of pure nitrogen animals died and flames were extinguished Though Lavoisier s name was not accepted in English since it was pointed out that all gases but oxygen are either asphyxiant or outright toxic it is used in many languages French Italian Portuguese Polish Russian Albanian Turkish etc the German Stickstoff similarly refers to the same characteristic viz ersticken to choke or suffocate and still remains in English in the common names of many nitrogen compounds such as hydrazine and compounds of the azide ion Finally it led to the name pnictogens for the group headed by nitrogen from the Greek pnigein to choke 6 The English word nitrogen 1794 entered the language from the French nitrogene coined in 1790 by French chemist Jean Antoine Chaptal 1756 1832 15 from the French nitre potassium nitrate also called saltpeter and the French suffix gene producing from the Greek genhs genes begotten Chaptal s meaning was that nitrogen is the essential part of nitric acid which in turn was produced from nitre In earlier times niter had been confused with Egyptian natron sodium carbonate called nitron nitron in Greek which despite the name contained no nitrate 16 The earliest military industrial and agricultural applications of nitrogen compounds used saltpeter sodium nitrate or potassium nitrate most notably in gunpowder and later as fertiliser In 1910 Lord Rayleigh discovered that an electrical discharge in nitrogen gas produced active nitrogen a monatomic allotrope of nitrogen 17 The whirling cloud of brilliant yellow light produced by his apparatus reacted with mercury to produce explosive mercury nitride 18 For a long time sources of nitrogen compounds were limited Natural sources originated either from biology or deposits of nitrates produced by atmospheric reactions Nitrogen fixation by industrial processes like the Frank Caro process 1895 1899 and Haber Bosch process 1908 1913 eased this shortage of nitrogen compounds to the extent that half of global food production see Applications now relies on synthetic nitrogen fertilisers 19 At the same time use of the Ostwald process 1902 to produce nitrates from industrial nitrogen fixation allowed the large scale industrial production of nitrates as feedstock in the manufacture of explosives in the World Wars of the 20th century 20 21 PropertiesAtomic The shapes of the five orbitals occupied in nitrogen The two colours show the phase or sign of the wave function in each region From left to right 1s 2s cutaway to show internal structure 2px 2py 2pz A nitrogen atom has seven electrons In the ground state they are arranged in the electron configuration 1s2 2s2 2p1x 2p1y 2p1z It therefore has five valence electrons in the 2s and 2p orbitals three of which the p electrons are unpaired It has one of the highest electronegativities among the elements 3 04 on the Pauling scale exceeded only by chlorine 3 16 oxygen 3 44 and fluorine 3 98 The light noble gases helium neon and argon would presumably also be more electronegative and in fact are on the Allen scale 22 Following periodic trends its single bond covalent radius of 71 pm is smaller than those of boron 84 pm and carbon 76 pm while it is larger than those of oxygen 66 pm and fluorine 57 pm The nitride anion N3 is much larger at 146 pm similar to that of the oxide O2 140 pm and fluoride F 133 pm anions 22 The first three ionisation energies of nitrogen are 1 402 2 856 and 4 577 MJ mol 1 and the sum of the fourth and fifth is 16 920 MJ mol 1 Due to these very high figures nitrogen has no simple cationic chemistry 23 The lack of radial nodes in the 2p subshell is directly responsible for many of the anomalous properties of the first row of the p block especially in nitrogen oxygen and fluorine The 2p subshell is very small and has a very similar radius to the 2s shell facilitating orbital hybridisation It also results in very large electrostatic forces of attraction between the nucleus and the valence electrons in the 2s and 2p shells resulting in very high electronegativities Hypervalency is almost unknown in the 2p elements for the same reason because the high electronegativity makes it difficult for a small nitrogen atom to be a central atom in an electron rich three center four electron bond since it would tend to attract the electrons strongly to itself Thus despite nitrogen s position at the head of group 15 in the periodic table its chemistry shows huge differences from that of its heavier congeners phosphorus arsenic antimony and bismuth 24 Nitrogen may be usefully compared to its horizontal neighbours carbon and oxygen as well as its vertical neighbours in the pnictogen column phosphorus arsenic antimony and bismuth Although each period 2 element from lithium to oxygen shows some similarities to the period 3 element in the next group from magnesium to chlorine these are known as diagonal relationships their degree drops off abruptly past the boron silicon pair The similarities of nitrogen to sulfur are mostly limited to sulfur nitride ring compounds when both elements are the only ones present 25 Nitrogen does not share the proclivity of carbon for catenation Like carbon nitrogen tends to form ionic or metallic compounds with metals Nitrogen forms an extensive series of nitrides with carbon including those with chain graphitic and fullerenic like structures 26 It resembles oxygen with its high electronegativity and concomitant capability for hydrogen bonding and the ability to form coordination complexes by donating its lone pairs of electrons There are some parallels between the chemistry of ammonia NH3 and water H2O For example the capacity of both compounds to be protonated to give NH4 and H3O or deprotonated to give NH2 and OH with all of these able to be isolated in solid compounds 27 Nitrogen shares with both its horizontal neighbours a preference for forming multiple bonds typically with carbon oxygen or other nitrogen atoms through pp pp interactions 25 Thus for example nitrogen occurs as diatomic molecules and therefore has very much lower melting 210 C and boiling points 196 C than the rest of its group as the N2 molecules are only held together by weak van der Waals interactions and there are very few electrons available to create significant instantaneous dipoles This is not possible for its vertical neighbours thus the nitrogen oxides nitrites nitrates nitro nitroso azo and diazo compounds azides cyanates thiocyanates and imino derivatives find no echo with phosphorus arsenic antimony or bismuth By the same token however the complexity of the phosphorus oxoacids finds no echo with nitrogen 25 Setting aside their differences nitrogen and phosphorus form an extensive series of compounds with one another these have chain ring and cage structures 28 Table of thermal and physical properties of nitrogen N2 at atmospheric pressure 29 30 Temperature K Density kg m 3 Specific heat kJ kg C Dynamic viscosity kg m s Kinematic viscosity m 2 s Thermal conductivity W m C Thermal diffusivity m 2 s Prandtl Number100 3 4388 1 07 6 88E 06 2 00E 06 0 00958 2 60E 06 0 768150 2 2594 1 05 1 01E 05 4 45E 06 0 0139 5 86E 06 0 759200 1 7108 1 0429 1 29E 05 7 57E 06 0 01824 1 02E 05 0 747300 1 1421 1 0408 1 78E 05 1 56E 05 0 0262 2 20E 05 0 713400 0 8538 1 0459 2 20E 05 2 57E 05 0 03335 3 73E 05 0 691500 0 6824 1 0555 2 57E 05 3 77E 05 0 03984 5 53E 05 0 684600 0 5687 1 0756 2 91E 05 5 12E 05 0 0458 7 49E 05 0 686700 0 4934 1 0969 3 21E 05 6 67E 05 0 05123 9 47E 05 0 691800 0 4277 1 1225 3 48E 05 8 15E 05 0 05609 1 17E 04 0 7900 0 3796 1 1464 3 75E 05 9 11E 05 0 0607 1 39E 04 0 7111000 0 3412 1 1677 4 00E 05 1 19E 04 0 06475 1 63E 04 0 7241100 0 3108 1 1857 4 23E 05 1 36E 04 0 0685 1 86E 04 0 7361200 0 2851 1 2037 4 45E 05 1 56E 04 0 07184 2 09E 04 0 7481300 0 2591 1 219 4 66E 05 1 80E 04 0 081 2 56E 04 0 701Isotopes Main article Isotopes of nitrogen Table of nuclides Segre chart from carbon to fluorine including nitrogen Orange indicates proton emission nuclides outside the proton drip line pink for positron emission inverse beta decay black for stable nuclides blue for electron emission beta decay and violet for neutron emission nuclides outside the neutron drip line Proton number increases going up the vertical axis and neutron number going to the right on the horizontal axis Nitrogen has two stable isotopes 14N and 15N The first is much more common making up 99 634 of natural nitrogen and the second which is slightly heavier makes up the remaining 0 366 This leads to an atomic weight of around 14 007 u 22 Both of these stable isotopes are produced in the CNO cycle in stars but 14N is more common as its neutron capture is the rate limiting step 14N is one of the five stable odd odd nuclides a nuclide having an odd number of protons and neutrons the other four are 2H 6Li 10B and 180mTa 31 The relative abundance of 14N and 15N is practically constant in the atmosphere but can vary elsewhere due to natural isotopic fractionation from biological redox reactions and the evaporation of natural ammonia or nitric acid 32 Biologically mediated reactions e g assimilation nitrification and denitrification strongly control nitrogen dynamics in the soil These reactions typically result in 15N enrichment of the substrate and depletion of the product 33 The heavy isotope 15N was first discovered by S M Naude in 1929 and soon after heavy isotopes of the neighbouring elements oxygen and carbon were discovered 34 It presents one of the lowest thermal neutron capture cross sections of all isotopes 35 It is frequently used in nuclear magnetic resonance NMR spectroscopy to determine the structures of nitrogen containing molecules due to its fractional nuclear spin of one half which offers advantages for NMR such as narrower line width 14N though also theoretically usable has an integer nuclear spin of one and thus has a quadrupole moment that leads to wider and less useful spectra 22 15N NMR nevertheless has complications not encountered in the more common 1H and 13C NMR spectroscopy The low natural abundance of 15N 0 36 significantly reduces sensitivity a problem which is only exacerbated by its low gyromagnetic ratio only 10 14 that of 1H As a result the signal to noise ratio for 1H is about 300 times as much as that for 15N at the same magnetic field strength 36 This may be somewhat alleviated by isotopic enrichment of 15N by chemical exchange or fractional distillation 15N enriched compounds have the advantage that under standard conditions they do not undergo chemical exchange of their nitrogen atoms with atmospheric nitrogen unlike compounds with labelled hydrogen carbon and oxygen isotopes that must be kept away from the atmosphere 22 The 15N 14N ratio is commonly used in stable isotope analysis in the fields of geochemistry hydrology paleoclimatology and paleoceanography where it is called d15N 37 Of the ten other isotopes produced synthetically ranging from 12N to 23N 13N has a half life of ten minutes and the remaining isotopes have half lives on the order of seconds 16N and 17N or milliseconds No other nitrogen isotopes are possible as they would fall outside the nuclear drip lines leaking out a proton or neutron 38 Given the half life difference 13N is the most important nitrogen radioisotope being relatively long lived enough to use in positron emission tomography PET although its half life is still short and thus it must be produced at the venue of the PET for example in a cyclotron via proton bombardment of 16O producing 13N and an alpha particle 39 The radioisotope 16N is the dominant radionuclide in the coolant of pressurised water reactors or boiling water reactors during normal operation It is produced from 16O in water via an n p reaction in which the 16O atom captures a neutron and expels a proton It has a short half life of about 7 1 s 38 but during its decay back to 16O produces high energy gamma radiation 5 to 7 MeV 38 40 Because of this access to the primary coolant piping in a pressurised water reactor must be restricted during reactor power operation 40 It is a sensitive and immediate indicator of leaks from the primary coolant system to the secondary steam cycle and is the primary means of detection for such leaks 40 Chemistry and compoundsAllotropes See also Solid nitrogen Molecular orbital diagram of dinitrogen molecule N2 There are five bonding orbitals and two antibonding orbitals marked with an asterisk orbitals involving the inner 1s electrons not shown giving a total bond order of three Atomic nitrogen also known as active nitrogen is highly reactive being a triradical with three unpaired electrons Free nitrogen atoms easily react with most elements to form nitrides and even when two free nitrogen atoms collide to produce an excited N2 molecule they may release so much energy on collision with even such stable molecules as carbon dioxide and water to cause homolytic fission into radicals such as CO and O or OH and H Atomic nitrogen is prepared by passing an electric discharge through nitrogen gas at 0 1 2 mmHg which produces atomic nitrogen along with a peach yellow emission that fades slowly as an afterglow for several minutes even after the discharge terminates 25 Given the great reactivity of atomic nitrogen elemental nitrogen usually occurs as molecular N2 dinitrogen This molecule is a colourless odourless and tasteless diamagnetic gas at standard conditions it melts at 210 C and boils at 196 C 25 Dinitrogen is mostly unreactive at room temperature but it will nevertheless react with lithium metal and some transition metal complexes This is due to its bonding which is unique among the diatomic elements at standard conditions in that it has an N N triple bond Triple bonds have short bond lengths in this case 109 76 pm and high dissociation energies in this case 945 41 kJ mol and are thus very strong explaining dinitrogen s low level of chemical reactivity 25 41 Other nitrogen oligomers and polymers may be possible If they could be synthesised they may have potential applications as materials with a very high energy density that could be used as powerful propellants or explosives 42 Under extremely high pressures 1 1 million atm and high temperatures 2000 K as produced in a diamond anvil cell nitrogen polymerises into the single bonded cubic gauche crystal structure This structure is similar to that of diamond and both have extremely strong covalent bonds resulting in its nickname nitrogen diamond 43 Solid nitrogen on the plains of Sputnik Planitia on the bottom right side of the image on Pluto next to water ice mountains on the up left side of the image At atmospheric pressure molecular nitrogen condenses liquefies at 77 K 195 79 C and freezes at 63 K 210 01 C 44 into the beta hexagonal close packed crystal allotropic form Below 35 4 K 237 6 C nitrogen assumes the cubic crystal allotropic form called the alpha phase 45 Liquid nitrogen a colourless fluid resembling water in appearance but with 80 8 of the density the density of liquid nitrogen at its boiling point is 0 808 g mL is a common cryogen 46 Solid nitrogen has many crystalline modifications It forms a significant dynamic surface coverage on Pluto 47 and outer moons of the Solar System such as Triton 48 Even at the low temperatures of solid nitrogen it is fairly volatile and can sublime to form an atmosphere or condense back into nitrogen frost It is very weak and flows in the form of glaciers and on Triton geysers of nitrogen gas come from the polar ice cap region 49 Dinitrogen complexes Main article Dinitrogen complex Structure of Ru NH3 5 N2 2 pentaamine dinitrogen ruthenium II the first dinitrogen complex to be discovered The first example of a dinitrogen complex to be discovered was Ru NH3 5 N2 2 see figure at right and soon many other such complexes were discovered These complexes in which a nitrogen molecule donates at least one lone pair of electrons to a central metal cation illustrate how N2 might bind to the metal s in nitrogenase and the catalyst for the Haber process these processes involving dinitrogen activation are vitally important in biology and in the production of fertilisers 50 51 Dinitrogen is able to coordinate to metals in five different ways The more well characterised ways are the end on M N N h1 and M N N M m bis h1 in which the lone pairs on the nitrogen atoms are donated to the metal cation The less well characterised ways involve dinitrogen donating electron pairs from the triple bond either as a bridging ligand to two metal cations m bis h2 or to just one h2 The fifth and unique method involves triple coordination as a bridging ligand donating all three electron pairs from the triple bond m3 N2 A few complexes feature multiple N2 ligands and some feature N2 bonded in multiple ways Since N2 is isoelectronic with carbon monoxide CO and acetylene C2H2 the bonding in dinitrogen complexes is closely allied to that in carbonyl compounds although N2 is a weaker s donor and p acceptor than CO Theoretical studies show that s donation is a more important factor allowing the formation of the M N bond than p back donation which mostly only weakens the N N bond and end on h1 donation is more readily accomplished than side on h2 donation 25 Today dinitrogen complexes are known for almost all the transition metals accounting for several hundred compounds They are normally prepared by three methods 25 Replacing labile ligands such as H2O H or CO directly by nitrogen these are often reversible reactions that proceed at mild conditions Reducing metal complexes in the presence of a suitable co ligand in excess under nitrogen gas A common choice includes replacing chloride ligands with dimethylphenylphosphine PMe2Ph to make up for the smaller number of nitrogen ligands attached to the original chlorine ligands Converting a ligand with N N bonds such as hydrazine or azide directly into a dinitrogen ligand Occasionally the N N bond may be formed directly within a metal complex for example by directly reacting coordinated ammonia NH3 with nitrous acid HNO2 but this is not generally applicable Most dinitrogen complexes have colours within the range white yellow orange red brown a few exceptions are known such as the blue Ti h5 C5H5 2 2 N2 25 Nitrides azides and nitrido complexes Nitrogen bonds to almost all the elements in the periodic table except the first three noble gases helium neon and argon and some of the very short lived elements after bismuth creating an immense variety of binary compounds with varying properties and applications in which pentazenium tetraazidoborate has the highest nitrogen content 25 Many binary compounds are known with the exception of the nitrogen hydrides oxides and fluorides these are typically called nitrides Many stoichiometric phases are usually present for most elements e g MnN Mn6N5 Mn3N2 Mn2N Mn4N and MnxN for 9 2 lt x lt 25 3 They may be classified as salt like mostly ionic covalent diamond like and metallic or interstitial although this classification has limitations generally stemming from the continuity of bonding types instead of the discrete and separate types that it implies They are normally prepared by directly reacting a metal with nitrogen or ammonia sometimes after heating or by thermal decomposition of metal amides 52 3 Ca N2 Ca3N2 3 Mg 2 NH3 Mg3N2 3 H2 at 900 C 3 Zn NH2 2 Zn3N2 4 NH3Many variants on these processes are possible The most ionic of these nitrides are those of the alkali metals and alkaline earth metals Li3N Na K Rb and Cs do not form stable nitrides for steric reasons and M3N2 M Be Mg Ca Sr Ba These can formally be thought of as salts of the N3 anion although charge separation is not actually complete even for these highly electropositive elements However the alkali metal azides NaN3 and KN3 featuring the linear N 3 anion are well known as are Sr N3 2 and Ba N3 2 Azides of the B subgroup metals those in groups 11 through 16 are much less ionic have more complicated structures and detonate readily when shocked 52 Mesomeric structures of borazine BH NH 3 Many covalent binary nitrides are known Examples include cyanogen CN 2 triphosphorus pentanitride P3N5 disulfur dinitride S2N2 and tetrasulfur tetranitride S4N4 The essentially covalent silicon nitride Si3N4 and germanium nitride Ge3N4 are also known silicon nitride in particular would make a promising ceramic if not for the difficulty of working with and sintering it In particular the group 13 nitrides most of which are promising semiconductors are isoelectronic with graphite diamond and silicon carbide and have similar structures their bonding changes from covalent to partially ionic to metallic as the group is descended In particular since the B N unit is isoelectronic to C C and carbon is essentially intermediate in size between boron and nitrogen much of organic chemistry finds an echo in boron nitrogen chemistry such as in borazine inorganic benzene Nevertheless the analogy is not exact due to the ease of nucleophilic attack at boron due to its deficiency in electrons which is not possible in a wholly carbon containing ring 52 The largest category of nitrides are the interstitial nitrides of formulae MN M2N and M4N although variable composition is perfectly possible where the small nitrogen atoms are positioned in the gaps in a metallic cubic or hexagonal close packed lattice They are opaque very hard and chemically inert melting only at very high temperatures generally over 2500 C They have a metallic lustre and conduct electricity as do metals They hydrolyse only very slowly to give ammonia or nitrogen 52 The nitride anion N3 is the strongest p donor known among ligands the second strongest is O2 Nitrido complexes are generally made by the thermal decomposition of azides or by deprotonating ammonia and they usually involve a terminal N 3 group The linear azide anion N 3 being isoelectronic with nitrous oxide carbon dioxide and cyanate forms many coordination complexes Further catenation is rare although N4 4 isoelectronic with carbonate and nitrate is known 52 Hydrides Standard reduction potentials for nitrogen containing species Top diagram shows potentials at pH 0 bottom diagram shows potentials at pH 14 53 Industrially ammonia NH3 is the most important compound of nitrogen and is prepared in larger amounts than any other compound because it contributes significantly to the nutritional needs of terrestrial organisms by serving as a precursor to food and fertilisers It is a colourless alkaline gas with a characteristic pungent smell The presence of hydrogen bonding has very significant effects on ammonia conferring on it its high melting 78 C and boiling 33 C points As a liquid it is a very good solvent with a high heat of vaporisation enabling it to be used in vacuum flasks that also has a low viscosity and electrical conductivity and high dielectric constant and is less dense than water However the hydrogen bonding in NH3 is weaker than that in H2O due to the lower electronegativity of nitrogen compared to oxygen and the presence of only one lone pair in NH3 rather than two in H2O It is a weak base in aqueous solution pKb 4 74 its conjugate acid is ammonium NH 4 It can also act as an extremely weak acid losing a proton to produce the amide anion NH 2 It thus undergoes self dissociation similar to water to produce ammonium and amide Ammonia burns in air or oxygen though not readily to produce nitrogen gas it burns in fluorine with a greenish yellow flame to give nitrogen trifluoride Reactions with the other nonmetals are very complex and tend to lead to a mixture of products Ammonia reacts on heating with metals to give nitrides 54 Many other binary nitrogen hydrides are known but the most important are hydrazine N2H4 and hydrogen azide HN3 Although it is not a nitrogen hydride hydroxylamine NH2OH is similar in properties and structure to ammonia and hydrazine as well Hydrazine is a fuming colourless liquid that smells similar to ammonia Its physical properties are very similar to those of water melting point 2 0 C boiling point 113 5 C density 1 00 g cm3 Despite it being an endothermic compound it is kinetically stable It burns quickly and completely in air very exothermically to give nitrogen and water vapour It is a very useful and versatile reducing agent and is a weaker base than ammonia 55 It is also commonly used as a rocket fuel 56 Hydrazine is generally made by reaction of ammonia with alkaline sodium hypochlorite in the presence of gelatin or glue 55 NH3 OCl NH2Cl OH NH2Cl NH3 N2 H 5 Cl slow N2 H 5 OH N2H4 H2O fast The attacks by hydroxide and ammonia may be reversed thus passing through the intermediate NHCl instead The reason for adding gelatin is that it removes metal ions such as Cu2 that catalyses the destruction of hydrazine by reaction with monochloramine NH2Cl to produce ammonium chloride and nitrogen 55 Hydrogen azide HN3 was first produced in 1890 by the oxidation of aqueous hydrazine by nitrous acid It is very explosive and even dilute solutions can be dangerous It has a disagreeable and irritating smell and is a potentially lethal but not cumulative poison It may be considered the conjugate acid of the azide anion and is similarly analogous to the hydrohalic acids 55 Halides and oxohalides Nitrogen trichloride All four simple nitrogen trihalides are known A few mixed halides and hydrohalides are known but are mostly unstable examples include NClF2 NCl2F NBrF2 NF2H NFH2 NCl2H and NClH2 57 Nitrogen trifluoride NF3 first prepared in 1928 is a colourless and odourless gas that is thermodynamically stable and most readily produced by the electrolysis of molten ammonium fluoride dissolved in anhydrous hydrogen fluoride Like carbon tetrafluoride it is not at all reactive and is stable in water or dilute aqueous acids or alkalis Only when heated does it act as a fluorinating agent and it reacts with copper arsenic antimony and bismuth on contact at high temperatures to give tetrafluorohydrazine N2F4 The cations NF 4 and N2 F 3 are also known the latter from reacting tetrafluorohydrazine with strong fluoride acceptors such as arsenic pentafluoride as is ONF3 which has aroused interest due to the short N O distance implying partial double bonding and the highly polar and long N F bond Tetrafluorohydrazine unlike hydrazine itself can dissociate at room temperature and above to give the radical NF2 Fluorine azide FN3 is very explosive and thermally unstable Dinitrogen difluoride N2F2 exists as thermally interconvertible cis and trans isomers and was first found as a product of the thermal decomposition of FN3 57 Nitrogen trichloride NCl3 is a dense volatile and explosive liquid whose physical properties are similar to those of carbon tetrachloride although one difference is that NCl3 is easily hydrolysed by water while CCl4 is not It was first synthesised in 1811 by Pierre Louis Dulong who lost three fingers and an eye to its explosive tendencies As a dilute gas it is less dangerous and is thus used industrially to bleach and sterilise flour Nitrogen tribromide NBr3 first prepared in 1975 is a deep red temperature sensitive volatile solid that is explosive even at 100 C Nitrogen triiodide NI3 is still more unstable and was only prepared in 1990 Its adduct with ammonia which was known earlier is very shock sensitive it can be set off by the touch of a feather shifting air currents or even alpha particles 57 58 For this reason small amounts of nitrogen triiodide are sometimes synthesised as a demonstration to high school chemistry students or as an act of chemical magic 59 Chlorine azide ClN3 and bromine azide BrN3 are extremely sensitive and explosive 60 61 Two series of nitrogen oxohalides are known the nitrosyl halides XNO and the nitryl halides XNO2 The first is very reactive gases that can be made by directly halogenating nitrous oxide Nitrosyl fluoride NOF is colourless and a vigorous fluorinating agent Nitrosyl chloride NOCl behaves in much the same way and has often been used as an ionising solvent Nitrosyl bromide NOBr is red The reactions of the nitryl halides are mostly similar nitryl fluoride FNO2 and nitryl chloride ClNO2 are likewise reactive gases and vigorous halogenating agents 57 Oxides Main article Nitrogen oxide Nitrogen dioxide at 196 C 0 C 23 C 35 C and 50 C NO2 converts to colourless dinitrogen tetroxide N2 O4 at low temperatures and reverts to NO2 at higher temperatures Nitrogen forms nine molecular oxides some of which were the first gases to be identified N2O nitrous oxide NO nitric oxide N2O3 dinitrogen trioxide NO2 nitrogen dioxide N2O4 dinitrogen tetroxide N2O5 dinitrogen pentoxide N4O nitrosylazide 62 and N NO2 3 trinitramide 63 All are thermally unstable towards decomposition to their elements One other possible oxide that has not yet been synthesised is oxatetrazole N4O an aromatic ring 62 Nitrous oxide N2O better known as laughing gas is made by thermal decomposition of molten ammonium nitrate at 250 C This is a redox reaction and thus nitric oxide and nitrogen are also produced as byproducts It is mostly used as a propellant and aerating agent for sprayed canned whipped cream and was formerly commonly used as an anaesthetic Despite appearances it cannot be considered to be the anhydride of hyponitrous acid H2N2O2 because that acid is not produced by the dissolution of nitrous oxide in water It is rather unreactive not reacting with the halogens the alkali metals or ozone at room temperature although reactivity increases upon heating and has the unsymmetrical structure N N O N N O N N O above 600 C it dissociates by breaking the weaker N O bond 62 Nitric oxide NO is the simplest stable molecule with an odd number of electrons In mammals including humans it is an important cellular signaling molecule involved in many physiological and pathological processes 64 It is formed by catalytic oxidation of ammonia It is a colourless paramagnetic gas that being thermodynamically unstable decomposes to nitrogen and oxygen gas at 1100 1200 C Its bonding is similar to that in nitrogen but one extra electron is added to a p antibonding orbital and thus the bond order has been reduced to approximately 2 5 hence dimerisation to O N N O is unfavourable except below the boiling point where the cis isomer is more stable because it does not actually increase the total bond order and because the unpaired electron is delocalised across the NO molecule granting it stability There is also evidence for the asymmetric red dimer O N O N when nitric oxide is condensed with polar molecules It reacts with oxygen to give brown nitrogen dioxide and with halogens to give nitrosyl halides It also reacts with transition metal compounds to give nitrosyl complexes most of which are deeply coloured 62 Blue dinitrogen trioxide N2O3 is only available as a solid because it rapidly dissociates above its melting point to give nitric oxide nitrogen dioxide NO2 and dinitrogen tetroxide N2O4 The latter two compounds are somewhat difficult to study individually because of the equilibrium between them although sometimes dinitrogen tetroxide can react by heterolytic fission to nitrosonium and nitrate in a medium with high dielectric constant Nitrogen dioxide is an acrid corrosive brown gas Both compounds may be easily prepared by decomposing a dry metal nitrate Both react with water to form nitric acid Dinitrogen tetroxide is very useful for the preparation of anhydrous metal nitrates and nitrato complexes and it became the storable oxidiser of choice for many rockets in both the United States and USSR by the late 1950s This is because it is a hypergolic propellant in combination with a hydrazine based rocket fuel and can be easily stored since it is liquid at room temperature 62 The thermally unstable and very reactive dinitrogen pentoxide N2O5 is the anhydride of nitric acid and can be made from it by dehydration with phosphorus pentoxide It is of interest for the preparation of explosives 65 It is a deliquescent colourless crystalline solid that is sensitive to light In the solid state it is ionic with structure NO2 NO3 as a gas and in solution it is molecular O2N O NO2 Hydration to nitric acid comes readily as does analogous reaction with hydrogen peroxide giving peroxonitric acid HOONO2 It is a violent oxidising agent Gaseous dinitrogen pentoxide decomposes as follows 62 N2O5 NO2 NO3 NO2 O2 NO N2O5 NO 3 NO2Oxoacids oxoanions and oxoacid salts Many nitrogen oxoacids are known though most of them are unstable as pure compounds and are known only as aqueous solutions or as salts Hyponitrous acid H2N2O2 is a weak diprotic acid with the structure HON NOH pKa1 6 9 pKa2 11 6 Acidic solutions are quite stable but above pH 4 base catalysed decomposition occurs via HONNO to nitrous oxide and the hydroxide anion Hyponitrites involving the N2 O2 2 anion are stable to reducing agents and more commonly act as reducing agents themselves They are an intermediate step in the oxidation of ammonia to nitrite which occurs in the nitrogen cycle Hyponitrite can act as a bridging or chelating bidentate ligand 66 Nitrous acid HNO2 is not known as a pure compound but is a common component in gaseous equilibria and is an important aqueous reagent its aqueous solutions may be made from acidifying cool aqueous nitrite NO 2 bent solutions although already at room temperature disproportionation to nitrate and nitric oxide is significant It is a weak acid with pKa 3 35 at 18 C They may be titrimetrically analysed by their oxidation to nitrate by permanganate They are readily reduced to nitrous oxide and nitric oxide by sulfur dioxide to hyponitrous acid with tin II and to ammonia with hydrogen sulfide Salts of hydrazinium N2 H 5 react with nitrous acid to produce azides which further react to give nitrous oxide and nitrogen Sodium nitrite is mildly toxic in concentrations above 100 mg kg but small amounts are often used to cure meat and as a preservative to avoid bacterial spoilage It is also used to synthesise hydroxylamine and to diazotise primary aromatic amines as follows 66 ArNH2 HNO2 ArNN Cl 2 H2ONitrite is also a common ligand that can coordinate in five ways The most common are nitro bonded from the nitrogen and nitrito bonded from an oxygen Nitro nitrito isomerism is common where the nitrito form is usually less stable 66 Fuming nitric acid contaminated with yellow nitrogen dioxide Nitric acid HNO3 is by far the most important and the most stable of the nitrogen oxoacids It is one of the three most used acids the other two being sulfuric acid and hydrochloric acid and was first discovered by alchemists in the 13th century It is made by the catalytic oxidation of ammonia to nitric oxide which is oxidised to nitrogen dioxide and then dissolved in water to give concentrated nitric acid In the United States of America over seven million tonnes of nitric acid are produced every year most of which is used for nitrate production for fertilisers and explosives among other uses Anhydrous nitric acid may be made by distilling concentrated nitric acid with phosphorus pentoxide at low pressure in glass apparatus in the dark It can only be made in the solid state because upon melting it spontaneously decomposes to nitrogen dioxide and liquid nitric acid undergoes self ionisation to a larger extent than any other covalent liquid as follows 66 2 HNO3 H2 NO 3 NO 3 H2O NO2 NO3 Two hydrates HNO3 H2O and HNO3 3H2O are known that can be crystallised It is a strong acid and concentrated solutions are strong oxidising agents though gold platinum rhodium and iridium are immune to attack A 3 1 mixture of concentrated hydrochloric acid and nitric acid called aqua regia is still stronger and successfully dissolves gold and platinum because free chlorine and nitrosyl chloride are formed and chloride anions can form strong complexes In concentrated sulfuric acid nitric acid is protonated to form nitronium which can act as an electrophile for aromatic nitration 66 HNO3 2 H2SO4 NO 2 H3O 2 HSO 4The thermal stabilities of nitrates involving the trigonal planar NO 3 anion depends on the basicity of the metal and so do the products of decomposition thermolysis which can vary between the nitrite for example sodium the oxide potassium and lead or even the metal itself silver depending on their relative stabilities Nitrate is also a common ligand with many modes of coordination 66 Finally although orthonitric acid H3NO4 which would be analogous to orthophosphoric acid does not exist the tetrahedral orthonitrate anion NO3 4 is known in its sodium and potassium salts 66 NaNO 3 Na 2 O 300 C for 7 days Ag crucible Na 3 NO 4 displaystyle ce NaNO3 Na2O gt ce Ag crucible ce 300 circ C for 7days Na3NO4 These white crystalline salts are very sensitive to water vapour and carbon dioxide in the air 66 Na3NO4 H2O CO2 NaNO3 NaOH NaHCO3Despite its limited chemistry the orthonitrate anion is interesting from a structural point of view due to its regular tetrahedral shape and the short N O bond lengths implying significant polar character to the bonding 66 Organic nitrogen compounds Nitrogen is one of the most important elements in organic chemistry Many organic functional groups involve a carbon nitrogen bond such as amides RCONR2 amines R3N imines RC NR R imides RCO 2NR azides RN3 azo compounds RN2R cyanates and isocyanates ROCN or RCNO nitrates RONO2 nitriles and isonitriles RCN or RNC nitrites RONO nitro compounds RNO2 nitroso compounds RNO oximes RCR NOH and pyridine derivatives C N bonds are strongly polarised towards nitrogen In these compounds nitrogen is usually trivalent though it can be tetravalent in quaternary ammonium salts R4N with a lone pair that can confer basicity on the compound by being coordinated to a proton This may be offset by other factors for example amides are not basic because the lone pair is delocalised into a double bond though they may act as acids at very low pH being protonated at the oxygen and pyrrole is not acidic because the lone pair is delocalised as part of an aromatic ring 67 The amount of nitrogen in a chemical substance can be determined by the Kjeldahl method 68 In particular nitrogen is an essential component of nucleic acids amino acids and thus proteins and the energy carrying molecule adenosine triphosphate and is thus vital to all life on Earth 67 Occurrence Schematic representation of the flow of nitrogen compounds through a land environment See also Nitrogen cycle Nitrogen is the most common pure element in the earth making up 78 1 of the volume of the atmosphere 6 75 5 by mass around 3 89 million gigatonnes Despite this it is not very abundant in Earth s crust making up somewhere around 19 parts per million of this on par with niobium gallium and lithium This represents 300 000 to a million gigatonnes of nitrogen depending on the mass of the crust 69 The only important nitrogen minerals are nitre potassium nitrate saltpetre and soda nitre sodium nitrate Chilean saltpetre However these have not been an important source of nitrates since the 1920s when the industrial synthesis of ammonia and nitric acid became common 70 Nitrogen compounds constantly interchange between the atmosphere and living organisms Nitrogen must first be processed or fixed into a plant usable form usually ammonia Some nitrogen fixation is done by lightning strikes producing the nitrogen oxides but most is done by diazotrophic bacteria through enzymes known as nitrogenases although today industrial nitrogen fixation to ammonia is also significant When the ammonia is taken up by plants it is used to synthesise proteins These plants are then digested by animals who use the nitrogen compounds to synthesise their proteins and excrete nitrogen bearing waste Finally these organisms die and decompose undergoing bacterial and environmental oxidation and denitrification returning free dinitrogen to the atmosphere Industrial nitrogen fixation by the Haber process is mostly used as fertiliser although excess nitrogen bearing waste when leached leads to eutrophication of freshwater and the creation of marine dead zones as nitrogen driven bacterial growth depletes water oxygen to the point that all higher organisms die Furthermore nitrous oxide which is produced during denitrification attacks the atmospheric ozone layer 70 Many saltwater fish manufacture large amounts of trimethylamine oxide to protect them from the high osmotic effects of their environment conversion of this compound to dimethylamine is responsible for the early odour in unfresh saltwater fish 71 In animals free radical nitric oxide derived from an amino acid serves as an important regulatory molecule for circulation 72 Nitric oxide s rapid reaction with water in animals results in the production of its metabolite nitrite Animal metabolism of nitrogen in proteins in general results in the excretion of urea while animal metabolism of nucleic acids results in the excretion of urea and uric acid The characteristic odour of animal flesh decay is caused by the creation of long chain nitrogen containing amines such as putrescine and cadaverine which are breakdown products of the amino acids ornithine and lysine respectively in decaying proteins 73 ProductionNitrogen gas is an industrial gas produced by the fractional distillation of liquid air or by mechanical means using gaseous air pressurised reverse osmosis membrane or pressure swing adsorption Nitrogen gas generators using membranes or pressure swing adsorption PSA are typically more cost and energy efficient than bulk delivered nitrogen 74 Commercial nitrogen is often a byproduct of air processing for industrial concentration of oxygen for steelmaking and other purposes When supplied compressed in cylinders it is often called OFN oxygen free nitrogen 75 Commercial grade nitrogen already contains at most 20 ppm oxygen and specially purified grades containing at most 2 ppm oxygen and 10 ppm argon are also available 76 In a chemical laboratory it is prepared by treating an aqueous solution of ammonium chloride with sodium nitrite 77 NH4Cl NaNO2 N2 NaCl 2 H2OSmall amounts of the impurities NO and HNO3 are also formed in this reaction The impurities can be removed by passing the gas through aqueous sulfuric acid containing potassium dichromate 77 Very pure nitrogen can be prepared by the thermal decomposition of barium azide or sodium azide 78 2 NaN3 2 Na 3 N2ApplicationsGas The applications of nitrogen compounds are naturally extremely widely varied due to the huge size of this class hence only applications of pure nitrogen itself will be considered here Two thirds 2 3 of nitrogen produced by industry is sold as gas and the remaining one third 1 3 as a liquid The gas is mostly used as a low reactivity safe atmosphere wherever the oxygen in the air would pose a fire explosion or oxidising hazard Some examples include 76 As a modified atmosphere pure or mixed with carbon dioxide to nitrogenate and preserve the freshness of packaged or bulk foods by delaying rancidity and other forms of oxidative damage Pure nitrogen as food additive is labeled in the European Union with the E number E941 79 In incandescent light bulbs as an inexpensive alternative to argon 80 In fire suppression systems for Information technology IT equipment 76 In the manufacture of stainless steel 81 In the case hardening of steel by nitriding 82 In some aircraft fuel systems to reduce fire hazard see inerting system To inflate race car and aircraft tires 83 reducing the problems of inconsistent expansion and contraction caused by moisture and oxygen in natural air 76 Nitrogen is commonly used during sample preparation in chemical analysis It is used to concentrate and reduce the volume of liquid samples Directing a pressurised stream of nitrogen gas perpendicular to the surface of the liquid causes the solvent to evaporate while leaving the solute s and un evaporated solvent behind 84 Nitrogen can be used as a replacement or in combination with carbon dioxide to pressurise kegs of some beers particularly stouts and British ales due to the smaller bubbles it produces which makes the dispensed beer smoother and headier 85 A pressure sensitive nitrogen capsule known commonly as a widget allows nitrogen charged beers to be packaged in cans and bottles 86 87 Nitrogen tanks are also replacing carbon dioxide as the main power source for paintball guns Nitrogen must be kept at a higher pressure than CO2 making N2 tanks heavier and more expensive 88 Equipment Some construction equipment uses pressurized nitrogen gas to help hydraulic system to provide extra power to devices such as hydraulic hammer Nitrogen gas formed from the decomposition of sodium azide is used for the inflation of airbags 89 Execution As nitrogen is an asphyxiant gas some jurisdictions have considered asphyxiation by inhalation of pure nitrogen as a means of capital punishment as a substitute for lethal injection 90 91 92 However as of 2020 update no executions using nitrogen gas have yet been carried out by any jurisdiction and at least one jurisdiction Oklahoma which had considered nitrogen asphyxiation as an execution protocol had abandoned the effort 93 Liquid source source source source source source Air balloon submerged in liquid nitrogen Liquid nitrogen is a cryogenic liquid which looks like water When insulated in proper containers such as dewar flasks it can be transported and stored with a low rate of evaporative loss 94 A container vehicle carrying liquid nitrogen Like dry ice the main use of liquid nitrogen is for cooling to low temperatures It is used in the cryopreservation of biological materials such as blood and reproductive cells sperm and eggs It is used in cryotherapy to remove cysts and warts on the skin by freezing them 95 It is used in laboratory cold traps and in cryopumps to obtain lower pressures in vacuum pumped systems It is used to cool heat sensitive electronics such as infrared detectors and X ray detectors Other uses include freeze grinding and machining materials that are soft or rubbery at room temperature shrink fitting and assembling engineering components and more generally to attain very low temperatures where necessary Because of its low cost liquid nitrogen is often used for cooling even when such low temperatures are not strictly necessary such as refrigeration of food freeze branding livestock freezing pipes to halt flow when valves are not present and consolidating unstable soil by freezing whenever excavation is going on underneath 76 SafetyGas Although nitrogen is non toxic when released into an enclosed space it can displace oxygen and therefore presents an asphyxiation hazard This may happen with few warning symptoms since the human carotid body is a relatively poor and slow low oxygen hypoxia sensing system 96 An example occurred shortly before the launch of the first Space Shuttle mission on March 19 1981 when two technicians died from asphyxiation after they walked into a space located in the Space Shuttle s mobile launcher platform that was pressurised with pure nitrogen as a precaution against fire 97 When inhaled at high partial pressures more than about 4 bar encountered at depths below about 30 m in scuba diving nitrogen is an anesthetic agent causing nitrogen narcosis a temporary state of mental impairment similar to nitrous oxide intoxication 98 99 Nitrogen dissolves in the blood and body fats Rapid decompression as when divers ascend too quickly or astronauts decompress too quickly from cabin pressure to spacesuit pressure can lead to a potentially fatal condition called decompression sickness formerly known as caisson sickness or the bends when nitrogen bubbles form in the bloodstream nerves joints and other sensitive or vital areas 100 101 Bubbles from other inert gases gases other than carbon dioxide and oxygen cause the same effects so replacement of nitrogen in breathing gases may prevent nitrogen narcosis but does not prevent decompression sickness 102 Liquid As a cryogenic liquid liquid nitrogen can be dangerous by causing cold burns on contact although the Leidenfrost effect provides protection for very short exposure about one second 103 Ingestion of liquid nitrogen can cause severe internal damage For example in 2012 a young woman in England had to have her stomach removed after ingesting a cocktail made with liquid nitrogen 104 Because the liquid to gas expansion ratio of nitrogen is 1 694 at 20 C a tremendous amount of force can be generated if liquid nitrogen is rapidly vaporised in an enclosed space In an incident on January 12 2006 at Texas A amp M University the pressure relief devices of a tank of liquid nitrogen were malfunctioning and later sealed As a result of the subsequent pressure buildup the tank failed catastrophically The force of the explosion was sufficient to propel the tank through the ceiling immediately above it shatter a reinforced concrete beam immediately below it and blow the walls of the laboratory 0 1 0 2 m off their foundations 105 Liquid nitrogen readily evaporates to form gaseous nitrogen and hence the precautions associated with gaseous nitrogen also apply to liquid nitrogen 106 107 108 For example oxygen sensors are sometimes used as a safety precaution when working with liquid nitrogen to alert workers of gas spills into a confined space 109 Vessels containing liquid nitrogen can condense oxygen from air The liquid in such a vessel becomes increasingly enriched in oxygen boiling point 183 C higher than that of nitrogen as the nitrogen evaporates and can cause violent oxidation of organic material 110 Oxygen deficiency monitors Oxygen deficiency monitors are used to measure levels of oxygen in confined spaces and any place where nitrogen gas or liquid are stored or used In the event of a nitrogen leak and a decrease in oxygen to a pre set alarm level an oxygen deficiency monitor can be programmed to set off audible and visual alarms thereby providing notification of the possible impending danger Most commonly the oxygen range to alert personnel is when oxygen levels get below 19 5 OSHA specifies that a hazardous atmosphere may include one where the oxygen concentration is below 19 5 or above 23 5 111 Oxygen deficiency monitors can either be fixed mounted to the wall and hard wired into the building s power supply or simply plugged into a power outlet or a portable hand held or wearable monitor See alsoReactive nitrogen species Soil gasReferences Standard Atomic Weights Nitrogen CIAAW 2009 a b c Lide David R 1990 1991 CRC Handbook of Physics and Chemistry 71st ed Boca Raton Ann Arbor Boston CRC Press inc pp 4 22 one page Gases Density The Engineering Toolbox Retrieved 27 January 2019 Tetrazoles contain a pair of double bonded nitrogen atoms with oxidation state 0 in the ring A Synthesis of the parent 1H tetrazole CH2N4 two atoms N 0 is given in Ronald A Henry and William G Finnegan An Improved Procedure for the Deamination of 5 Aminotetrazole J Am Chem Soc 1954 76 1 290 291 https doi org 10 1021 ja01630a086 Common Bond Energies D and Bond Lengths r Archived 2010 05 15 at the Wayback Machine wiredchemist com a b c Greenwood and Earnshaw pp 406 07 Rutherford Daniel 1772 Dissertatio Inauguralis de aere fixo aut mephitico Archived 2020 08 06 at the Wayback Machine Inaugural dissertation on the air called fixed or mephitic M D dissertation University of Edinburgh Scotland English translation Dobbin Leonard 1935 Daniel Rutherford s inaugural dissertation Journal of Chemical Education 12 8 370 75 Bibcode 1935JChEd 12 370D doi 10 1021 ed012p370 Weeks Mary Elvira 1932 The discovery of the elements IV Three important gases Journal of Chemical Education 9 2 215 Bibcode 1932JChEd 9 215W doi 10 1021 ed009p215 Aaron J Ihde The Development of Modern Chemistry New York 1964 Carl Wilhelm Scheele Chemische Abhandlung von der Luft und dem Feuer Chemical treatise on air and fire Upsala Sweden Magnus Swederus 1777 and Leipzig Germany Siegfried Lebrecht Crusius 1777 In the section titled Die Luft muss aus elastischen Flussigkeiten von zweyerley Art zusammengesetzet seyn The air must be composed of elastic fluids of two sorts pp 6 14 Scheele presents the results of eight experiments in which air was reacted with various substances He concluded p 13 So viel sehe ich aus angefuhrten Versuchen dass die Luft aus 2 von einander unterschiedenen Flussigkeiten bestehe von welchen die eine die Eigenschaft das Phlogiston anzuziehen gar nicht aussere die andere aber zur solchen Attraction eigentlich aufgeleget ist und welche zwischen dem 3 ten und 4 ten Theil von der ganzen Luftmasse aus machet So I see this much from the experiments that were conducted that the air consists of two fluids that differ from one another of which the one doesn t express at all the property of attracting phlogiston the other however is capable of such attraction and which makes up between 1 3 and 1 4 part of the entire mass of the air Priestley Joseph 1772 Observations on different kinds of air Philosophical Transactions of the Royal Society of London 62 147 256 doi 10 1098 rstl 1772 0021 S2CID 186210131 see p 225 Archived 2016 09 03 at the Wayback Machine Priestley Joseph 1772 Observations on different kinds of air Philosophical Transactions of the Royal Society of London 62 147 256 doi 10 1098 rstl 1772 0021 S2CID 186210131 see VII Of air infected with the fumes of burning charcoal pp 225 28 Archived 2016 09 03 at the Wayback Machine Lavoisier Antoine with Robert Kerr trans Elements of Chemistry 4th ed Edinburgh Scotland William Creech 1799 pp 85 86 p 85 Archived 2020 08 06 at the Wayback Machine In reflecting upon the circumstances of this experiment we readily perceive that the mercury during its calcination i e roasting in air absorbs the salubrious and respirable part of the air or to speak more strictly the base of this respirable part that the remaining air is a species of mephitis i e a poisonous gas emitted from the earth incapable of supporting combustion or respiration p 86 Archived 2020 08 06 at the Wayback Machine I shall afterwards shew that at least in our climate the atmospheric air is composed of respirable and mephitic airs in the proportion of 27 and 73 Lavoisier Antoine with Robert Kerr trans Elements of Chemistry 4th ed Edinburgh Scotland William Creech 1799 p 101 The chemical properties of the noxious portion of the atmospheric air being hitherto but little known we have been satisfied to derive the name of its base from its known quality of killing such animals as are forced to 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at the Wayback Machine BBC News October 25 1999 Liquid Nitrogen Code of practice for handling United Kingdom Birkbeck University of London 2007 Archived from the original on 2018 06 12 Retrieved 2012 02 08 Levey Christopher G Liquid Nitrogen Safety Thayer School of Engineering at Dartmouth Archived from the original on 2016 03 05 Retrieved 2016 11 23 National Institutes of Health Protocol for Use and Maintenance of Oxygen Monitoring Devices February 2014 at 1 35 UTC Available at https www ors od nih gov sr dohs documents protocoloxygenmonitoring pdf Archived 2020 12 05 at the Wayback Machine Accessed June 23 2020BibliographyGreenwood Norman N Earnshaw Alan 1997 Chemistry of the Elements 2nd ed Butterworth Heinemann ISBN 978 0 08 037941 8 External linksEtymology of Nitrogen Nitrogen at The Periodic Table of Videos University of Nottingham Nitrogen podcast from the Royal Society of Chemistry s Chemistry World Retrieved from https en wikipedia org w index php title Nitrogen amp oldid 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