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Ammonia

From Wikipedia, the free encyclopedia

Preferred IUPAC name [hide]

Azane
Systematic name [hide]

Ammonia
Other names[hide] 
Hydrogen nitride

Nitro-Sil
Spirit of hartshorn
Trihydrogen nitride

Vaporole
Identifiers
CAS number  	7664-41-7
^YesY
PubChem  	222
^YesY ,
12896473
(monohydrate) ^YesY
, 22321416
(dihydrate) ^YesY

ChemSpider  	217  ^YesY
, 11338614  (dihydrate) ^YesY
UNII  	5138Q19F1X
^YesY
EC number  	231-635-3

UN number  	1005
KEGG  	C00014

MeSH  	Ammonia

ChEBI  	16134

RTECS number  	BO0875000
SMILES  	
[show] 
N
InChI  	
[show] 
1S/H3N/h1H3
InChI key 
QGZKDVFQNNGYKY-UHFFFAOYSA-N
Beilstein Reference  	3587154
Gmelin Reference  	79
3DMet 	B00004 
Properties
Molecular formula  	NH_3
Molar mass  	17.031 g/mol
Appearance 	Colourless gas with strong pungent odour
Density  	0.86 kg/m^3 (1.013 bar at boiling point)
0.73 kg/m^3 (1.013 bar at 15 °C)
681.9 kg/m^3 at −33.3 °C (liquid)^[1] 
817 kg/m^3 at -80 °C (transparent solid)^[2] 
Melting point  	

−77.73 °C, 195 K, -108 °F

Boiling point  	

−33.34 °C, 240 K, -28 °F

Solubility  in water  	47% (0 °C)
31% (25 °C)
28% (50 °C)^[3] 
Acidity  (p/K/_a ) 	9.2 (H_2 O) 10.5
(DMSO)
Basicity  (p/K/_b ) 	4.75
Structure
Molecular shape  	Trigonal pyramid

Dipole moment  	1.42 D 
Hazards
MSDS  	External MSDS

EU Index 	007-001-00-5 (anhydrous)
007-001-01-2 (solutions)
EU classification  	Toxic (*T*)
Corrosive (*C*)
Dangerous for the environment (*N*)
R-phrases  	R10 , R23
, R34 , R50

S-phrases  	(S1/2)
, S9
, S16
, S26
,
S36/37/39
,
S45
,
S61


NFPA 704  	
NFPA 704.svg 
1
3
0
Flash point  	flammable gas (/see text/)
Autoignition
temperature  	651 °C
Explosive limits  	15–28%
U.S.  Permissible
exposure limit (PEL)  	50 ppm (25 ppm
ACGIH - TLV; 35 ppm STEL )
Related compounds
Other cations  	Phosphine 
Arsine 
Stibine 
Related nitrogen hydrides 	Hydrazine 
Hydrazoic acid 
Related compounds 	Ammonium hydroxide 
Supplementary data page 
Structure and
properties  	/n/
, ε_r , etc.
Thermodynamic
data  	Phase behaviour
Solid, liquid, gas
Spectral data  	UV
, IR , NMR
, MS 
YesY (what is this?)
(verify)

Except where noted otherwise, data are given for materials in their
standard state (at 25 °C, 100 kPa) 
Infobox references 


*Ammonia* is a compound of nitrogen and hydrogen with the formula NH_3 .
It is a colourless gas with a characteristic pungent odour . Ammonia
contributes significantly to the nutritional needs of terrestrial
organisms by serving as a precursor to food and fertilizers . Ammonia,
either directly or indirectly, is also a building block for the synthesis
of many pharmaceuticals . Although in wide use, ammonia is both caustic
and hazardous . In 2006, worldwide production was estimated at 146.5
million tonnes.^[4] It is used in commercial cleaning products.

Ammonia, as used commercially, is often called /anhydrous ammonia./ This
term emphasizes the absence of water in the material. Because NH_3 boils
at -33.34 °C, (-28.012 °F) the liquid must be stored under high pressure
or at low temperature. Its heat of vapourization is, however, sufficiently
high so that NH_3 can be readily handled in ordinary beakers , in a fume
hood (i.e., if it is already a liquid it will not boil readily).
"Household ammonia" or "ammonium hydroxide " is a solution of NH_3 in
water. The strength of such solutions is measured in units of baume
(density ), with 26 degrees baume (about 30 weight percent ammonia at 15.5
°C) being the typical high concentration commercial product.^[5]
Household ammonia ranges in concentration from 5 to 10 weight percent
ammonia.


Contents

[hide ]

* 1 Structure and basic chemical properties

o 1.1 Natural occurrence 
* 2 History 
* 3 Synthesis and production 
* 4 Biosynthesis 
* 5 Properties 
o 5.1 Basicity 
o 5.2 Acidity 
o 5.3 Self-dissociation 
o 5.4 Combustion 
o 5.5 Formation of other compounds 
o 5.6 Ammonia as a ligand 
* 6 Interstellar formation and destruction

o 6.1 Formation mechanisms 
o 6.2 Destruction mechanisms 
* 7 Uses 
o 7.1 Fertilizer 
o 7.2 Precursor to nitrogenous compounds

o 7.3 Cleaner 
o 7.4 Minor and emerging uses 
+ 7.4.1 Refrigeration – R717 
+ 7.4.2 For remediation of gaseous emissions

+ 7.4.3 As a fuel 
+ 7.4.4 Antimicrobial agent for food products

+ 7.4.5 As a stimulant in sports 
+ 7.4.6 Textile 
+ 7.4.7 Lifting gas 
+ 7.4.8 Woodworking 
* 8 Ammonia's role in biological systems and human disease

o 8.1 Excretion 
* 9 Liquid ammonia as a solvent 
o 9.1 Solubility of salts 
o 9.2 Solutions of metals 
o 9.3 Redox properties of liquid ammonia

* 10 Detection and determination 
o 10.1 Interstellar space 
+ 10.1.1 Single antenna detections

+ 10.1.2 Interferometric studies 
+ 10.1.3 Infrared detections 
* 11 Astronomical observations and research applications

o 11.1 Observations of nearby dark clouds

o 11.2 UC HII regions 
o 11.3 Extragalactic detection 
* 12 Safety precautions 
o 12.1 Toxicity and storage information

o 12.2 Household use 
o 12.3 Laboratory use of ammonia solutions

o 12.4 Laboratory use of anhydrous ammonia (gas or liquid)

o 12.5 Mapping of industrial releases in the United States

* 13 See also 
* 14 References 
* 15 Bibliography 
* 16 External links 


[edit ] Structure
and basic chemical properties

The ammonia molecule has a trigonal pyramidal shape with a bond angle of
107.8° as shown above, as predicted by the valence shell electron pair
repulsion theory (VSEPR ). The central nitrogen atom has five outer
electrons with an additional electron from each hydrogen atom. This gives
a total of eight electrons, or four electron pairs which are arranged
tetrahedrally. Three of these electron pairs are used as bond pairs, which
leaves one lone pair of electrons. The lone pair of electrons repel more
strongly than bond pairs, therefore the bond angle is not 109.5° as
expected for a regular tetrahedral arrangement, but is measured at
107.8°. The nitrogen atom in the molecule has a lone electron pair ,
which makes ammonia a base , a proton acceptor. This shape gives the
molecule a dipole moment and makes it polar . The molecule's polarity and,
especially, its ability to form hydrogen bonds , makes ammonia highly
miscible with water . Ammonia is moderately basic, a 1.0 M aqueous
solution has a pH of 11.6 and if a strong acid is added to such a solution
until the solution is neutral (pH = 7), 99.4% of the ammonia molecules are
protonated . Temperature and salinity also affect the proportion of NH_4
^+ . The latter has the shape of a regular tetrahedron and is
isoelectronic with methane . It is known to have the highest specific heat
capacity of any substance.


[edit ] Natural occurrence

Ammonia is found in trace quantities in the atmosphere, being produced
from the putrefaction of nitrogenous animal and vegetable matter. Ammonia
and ammonium salts are also found in small quantities in rainwater,
whereas ammonium chloride (sal-ammoniac), and ammonium sulfate are found
in volcanic districts; crystals of ammonium bicarbonate have been found in
Patagonian guano . The kidneys secrete NH_3 to neutralize excess acid.^[6]
Ammonium salts also are found distributed through all fertile soil and in
seawater. Substances containing ammonia, or those that are similar to it,
are called /ammoniacal/.


[edit ] History



This high-pressure reactor was built in 1921 by BASF in Ludwigshafen and
was re-erected on the premises of the University of Karlsruhe in Germany.

The Romans called the ammonium chloride deposits they collected from near
the Temple of Jupiter Amun (Greek Ἄμμων /Ammon/) in ancient Libya
'sal ammoniacus' (salt of Amun) because of proximity to the nearby
temple.^[7] Salts of ammonia have been known from very early times; thus
the term /Hammoniacus sal/ appears in the writings of Pliny , although it
is not known whether the term is identical with the more modern
/sal-ammoniac/.^[8]

In the form of sal-ammoniac (nushadir), ammonia was important to the
Muslim alchemists as early as the 8th century, first mentioned by the
Islamic chemist Jābir ibn Hayyān ,^[9] and to the European alchemists
since the 13th century, being mentioned by Albertus Magnus . It was also
used by dyers in the Middle Ages in the form of fermented urine to alter
the colour of vegetable dyes. In the 15th century, Basilius Valentinus
showed that ammonia could be obtained by the action of alkalis on
sal-ammoniac. At a later period, when sal-ammoniac was obtained by
distilling the hooves and horns of oxen and neutralizing the resulting
carbonate with hydrochloric acid , the name "spirit of hartshorn" was
applied to ammonia.^[10]

Gaseous ammonia was first isolated by Joseph Priestley in 1774 and was
termed by him /alkaline air/.^[11] Eleven years later in 1785, Claude
Louis Berthollet ascertained its composition.

The Haber-Bosch process to produce ammonia from the nitrogen in the air
was developed by Fritz Haber and Carl Bosch in 1909 and patented in 1910.
It was first used on an industrial scale by the Germans during World War I
,^[4] following the allied blockade that cut off the supply of nitrates
from Chile . The ammonia was used to produce explosives to sustain their
war effort.^[12]


Prior to the advent of cheap natural gas, hydrogen as a precursor to
ammonia production was produced via the electrolysis of water or using the
chloralkali process . The Vemork 60 MW hydroelectric plant in Norway,
constructed in 1911, was used purely for plants using the Birkeland-Eyde
process .


[edit ] Synthesis and production

See also: Haber-Bosch process


Production trend of ammonia between 1947 and 2007

Because of its many uses, ammonia is one of the most highly produced
inorganic chemicals. Dozens of chemical plants worldwide produce ammonia.
The worldwide ammonia production in 2004 was 109 million metric tonnes
.^[13] The People's Republic of China produced 28.4% of the worldwide
production (increasingly from coal as part of urea synthesis)^[14]
followed by India with 8.6%, Russia with 8.4%, and the United States with
8.2%.^[13] About 80% or more of the ammonia produced is used for
fertilizing agricultural crops.^[13]

Before the start of World War I , most ammonia was obtained by the dry
distillation ^[15] of nitrogenous vegetable and animal waste products,
including camel dung , where it was distilled by the reduction of nitrous
acid and nitrites with hydrogen; in addition, it was produced by the
distillation of coal , and also by the decomposition of ammonium salts by
alkaline hydroxides^[16] such as quicklime , the salt most generally used
being the chloride (sal-ammoniac ) thus:

2 NH_4 Cl + 2 CaO → CaCl_2 + Ca(OH)_2 + 2 NH_3

Today, the typical modern ammonia-producing plant first converts natural
gas (i.e., methane) or liquefied petroleum gas (such gases are propane and
butane ) or petroleum naphtha into gaseous hydrogen. The process used in
producing the hydrogen begins with removal of sulfur compounds from the
natural gas (because sulfur deactivates the catalysts used in subsequent
steps). Catalytic hydrogenation converts organosulfur compounds into
gaseous hydrogen sulfide :

H_2 + RSH → RH + H_2 S (g)

The hydrogen sulfide is then removed by passing the gas through beds of
zinc oxide where it is adsorbed and converted to solid zinc sulfide :

H_2 S + ZnO → ZnS + H_2 O

Catalytic steam reforming of the sulfur-free feedstock is then used to
form hydrogen plus carbon monoxide :

CH_4 + H_2 O → CO + 3 H_2

In the next step, the water gas shift reaction is used to convert the
carbon monoxide into carbon dioxide and more hydrogen:

CO + H_2 O → CO_2 + H_2

The carbon dioxide is then removed either by absorption in aqueous
ethanolamine solutions or by adsorption in pressure swing adsorbers (PSA)
using proprietary solid adsorption media.

The final step in producing the hydrogen is to use catalytic methanation
to remove any small residual amounts of carbon monoxide or carbon dioxide
from the hydrogen:

CO + 3 H_2 → CH_4 + H_2 O CO_2 + 4 H_2 → CH_4 + 2 H_2 O

To produce the desired end-product ammonia, the hydrogen is then
catalytically reacted with nitrogen (derived from process air) to form
anhydrous liquid ammonia. This step is known as the ammonia synthesis loop
(also referred to as the Haber-Bosch process):

3 H_2 + N_2 → 2 NH_3

Hydrogen required for ammonia synthesis could also be produced
economically using other sources like coal or coke gasification, less
economically from the electrolysis of water into oxygen + hydrogen and
other alternatives which are presently impractical for large scale. At one
time, most of Europe's ammonia was produced from the Hydro plant at Vemork
, via the electrolysis route. Various renewable energy electricity sources
are also potentially applicable.


[edit ] Biosynthesis

In certain organisms, ammonia is produced from atmospheric nitrogen by
enzymes called nitrogenases . The overall process is called nitrogen
fixation . Although it is unlikely that biomimetic methods will be
developed that are competitive with the Haber process , intense effort has
been directed toward understanding the mechanism of biological nitrogen
fixation. The scientific interest in this problem is motivated by the
unusual structure of the active site of the enzyme, which consists of an
Fe_7 MoS_9 ensemble.

Ammonia is also a metabolic product of amino acid deamination . Ammonia
excretion is common in aquatic animals. In humans, it is quickly converted
to urea , which is much less toxic. This urea is a major component of the
dry weight of urine . Most reptiles, birds, as well as insects and snails
solely excrete uric acid as nitrogenous waste.


[edit ] Properties

Ammonia is a colourless gas with a characteristic pungent smell. It is
lighter than air , its density being 0.589 times that of air . It is
easily liquefied due to the strong hydrogen bonding between molecules; the
liquid boils at −33.3 °C, and solidifies at −77.7 °C to white
crystals. The crystal symmetry is cubic, Pearson symbol cP16, space group
P2_1 3 No.198, lattice constant 0.5125 nm.^[17] Liquid ammonia possesses
strong ionising powers reflecting its high ε of 22. Liquid ammonia has a
very high standard enthalpy change of vapourization (23.35 kJ /mol, /cf./
water 40.65 kJ/mol, methane 8.19 kJ/mol, phosphine 14.6 kJ/mol) and can
therefore be used in laboratories in non-insulated vessels without
additional refrigeration.

It is miscible with water. Ammonia in an aqueous solution can be expelled
by boiling. The aqueous solution of ammonia is basic . The maximum
concentration of ammonia in water (a saturated solution) has a density of
0.880 g/cm^3 and is often known as '.880 Ammonia'. Ammonia does not burn
readily or sustain combustion , except under narrow fuel-to-air mixtures
of 15–25% air. When mixed with oxygen , it burns with a pale
yellowish-green flame. At high temperature and in the presence of a
suitable catalyst, ammonia is decomposed into its constituent elements.
Ignition occurs when chlorine is passed into ammonia, forming nitrogen and
hydrogen chloride ; if chlorine is present in excess, then the highly
explosive nitrogen trichloride (NCl_3 ) is also formed.

The ammonia molecule readily undergoes nitrogen inversion at room
temperature; a useful analogy is an umbrella turning itself inside out in
a strong wind. The energy barrier to this inversion is 24.7 kJ/mol, and
the resonance frequency is 23.79 GHz , corresponding to microwave
radiation of a wavelength of 1.260 cm. The absorption at this frequency
was the first microwave spectrum to be observed.^[18]

Ammonia may be conveniently deodorized by reacting it with either sodium
bicarbonate or acetic acid. Both of these reactions form an odourless
ammonium salt.


[edit ] Basicity

One of the most characteristic properties of ammonia is its basicity . It
combines with acids to form salts ; thus with hydrochloric acid it forms
ammonium chloride (sal-ammoniac); with nitric acid , ammonium nitrate ,
etc. However, perfectly dry ammonia will not combine with perfectly dry
hydrogen chloride : moisture is necessary to bring about the
reaction.^[19]

NH_3 + HCl → NH_4 Cl

The salts produced by the action of ammonia on acids are known as the
ammonium salts and all contain the ammonium ion (NH_4 ^+ ). Anhydrous
ammonia is often used for the production of methamphetamine . Dilute
aqueous ammonia can be applied on the skin to lessen the effects of acidic
animal poisons, such as from insects and jellyfish .


[edit ] Acidity

Although ammonia is well known as a strong base, it can also act as an
extremely weak acid. It is a protic substance and is capable of formation
of amides (which contain the NH_2 ^− ion). For example, lithium and
ammonia react to give a solution of lithium amide :

2 Li + 2 NH_3 → 2 LiNH_2 + H_2


[edit ] Self-dissociation

Like water, ammonia undergoes molecular autoionisation to form its acid
and base conjugates:

2 NH_3 (l) is in equilibrium with NH+4 (aq) + NH−2 (aq)

At standard pressure and temperature, [NH+4][NH−2] = 10^−30 M^2 .


[edit ] Combustion

The combustion of ammonia to nitrogen and water is exothermic :

4 NH_3 + 3 O_2 → 2 N_2 + 6 H_2 O (/g/) (Δ/H/º_r = –1267.20 kJ/mol)

The standard enthalpy change of combustion , Δ/H/º_c , expressed per
mole of ammonia and with condensation of the water formed, is –382.81
kJ/mol. Dinitrogen is the thermodynamic product of combustion: all
nitrogen oxides are unstable with respect to nitrogen and oxygen , which
is the principle behind the catalytic converter . However, nitrogen oxides
can be formed as kinetic products in the presence of appropriate
catalysts, a reaction of great industrial importance in the production of
nitric acid :

4 NH_3 + 5 O_2 → 4 NO + 6 H_2 O

A subsequent reaction leads to water and N_2 O

The combustion of ammonia in air is very difficult in the absence of a
catalyst (such as platinum gauze), as the temperature of the flame is
usually lower than the ignition temperature of the ammonia-air mixture.
The flammable range of ammonia in air is 16–25%.^[20]


[edit ] Formation of other compounds

In organic chemistry , ammonia can act as a nucleophile in substitution
reactions. Amines can be formed by the reaction of ammonia with alkyl
halides , although the resulting –NH_2 group is also nucleophilic and
secondary and tertiary amines are often formed as by-products. An excess
of ammonia helps minimise multiple substitution, and neutralises the
hydrogen halide formed. Methylamine is prepared commercially by the
reaction of ammonia with chloromethane , and the reaction of ammonia with
2-bromopropanoic acid has been used to prepare racemic alanine in 70%
yield. Ethanolamine is prepared by a ring-opening reaction with ethylene
oxide : the reaction is sometimes allowed to go further to produce
diethanolamine and triethanolamine .

Amides can be prepared by the reaction of ammonia with a number of
carboxylic acid derivatives. Acyl chlorides are the most reactive, but the
ammonia must be present in at least a twofold excess to neutralise the
hydrogen chloride formed. Esters and anhydrides also react with ammonia to
form amides. Ammonium salts of carboxylic acids can be dehydrated to
amides so long as there are no thermally sensitive groups present:
temperatures of 150–200 °C are required.

The hydrogen in ammonia is capable of replacement by metals , thus
magnesium burns in the gas with the formation of magnesium nitride Mg_3
N_2 , and when the gas is passed over heated sodium or potassium ,
sodamide, NaNH_2 , and potassamide, KNH_2 , are formed. Where necessary in
substitutive nomenclature , IUPAC recommendations prefer the name *azane*
to ammonia: hence chloramine would be named /chloroazane/ in substitutive
nomenclature, not /chloroammonia/.

Pentavalent ammonia is known as λ^5 -amine, or more commonly, ammonium
hydride. This crystalline solid is only stable under high pressure, and
decomposes back into trivalent ammonia and hydrogen gas at normal
conditions. This substance is was once investigated as a possible solid
rocket fuel in 1966.^[21]


[edit ] Ammonia as a ligand



Ball-and-stick model of the tetraamminediaquacopper(II) cation, [Cu(NH_3
)_4 (H_2 O)_2 ]^2+


Ball-and-stick model of the diamminesilver(I) cation, [Ag(NH_3 )_2 ]^+

Ammonia can act as a ligand in transition metal complexes . It is a pure
σ-donor, in the middle of the spectrochemical series , and shows
intermediate hard-soft behaviour. For historical reasons, ammonia is named
*ammine* in the nomenclature of coordination compounds . Some notable
ammine complexes include:

* *Tetraamminediaquacopper(II)*, [Cu(NH_3 )_4 (H_2 O)_2 ]^2+ , a
characteristic dark blue complex formed by adding ammonia to solution of
copper(II) salts. Known as Schweizer's reagent . * *Diamminesilver(I)*,
[Ag(NH_3 )_2 ]^+ , the active species in Tollens' reagent . Formation of
this complex can also help to distinguish between precipitates of the
different silver halides: silver chloride (AgCl) is soluble in dilute (2M)
ammonia solution, silver bromide (AgBr) is only soluble in concentrated
ammonia solution while silver iodide (AgI) is insoluble in aqueous
solution of ammonia.

Ammine complexes of chromium (III) were known in the late 19th century,
and formed the basis of Alfred Werner 's theory of coordination compounds.
Werner noted that only two isomers (/fac/- and /mer/-) of the complex
[CrCl_3 (NH_3 )_3 ] could be formed, and concluded that the ligands must
be arranged around the metal ion at the vertices of an octahedron . This
proposal has since been confirmed by X-ray crystallography .

An ammine ligand bound to a metal ion is markedly more acidic than a free
ammonia molecule, although deprotonation in aqueous solution is still
rare. One example is the Calomel reaction , where the resulting
amidomercury(II) compound is highly insoluble.

Hg_2 Cl_2 + 2 NH_3 → Hg + HgCl(NH_2 ) + NH_4 ^+ + Cl^−


[edit ] Interstellar formation and destruction


[edit ] Formation mechanisms

The interstellar abundance for ammonia has been measured for a variety of
environments. The [NH_3 ]/[H_2 ] ratio has been estimated to range from
10^−7 in small dark clouds^[22] up to 10^−5 in the dense core of the
Orion Molecular Cloud Complex .^[23] Although a total of 18 total
production routes have been proposed,^[24] the principal formation
mechanism for interstellar NH_3 is the reaction:

NH_4 ^+ + e^− → NH_3 + H·

The rate constant, /k/, of this reaction depends on the temperature of the
environment, with a value of 5.2×10^−6 at 10 K.^[25] The rate constant
was calculated from the formula /k = a(T/300)^B /. For the primary
formation reaction, /a/ = 1.05×10^−6 and /B/ = −0.47. Assuming an
NH_4 ^+ abundance of 3×10^−7 and an electron abundance of 10^−7
typical of molecular clouds, the formation will proceed at a rate of
1.6×10^−9 cm^−3 s^−1 in a molecular cloud of total density 10^5
cm^−3 .^[26]

All other proposed formation reactions have rate constants of between 2
and 13 orders of magnitude smaller, making their contribution to the
abundance of ammonia relatively insignificant.^[27] As an example of the
minor contribution other formation reactions play, the reaction:

H_2 + NH_2 → NH_3 + H

has a rate constant of 2.2×10^−15 . Assuming H_2 densities of 10^5 and
NH_2 /H_2 ratio of 10^−7 , this reaction proceeds at a rate of
2.2×10^−12 , more than 3 orders of magnitude slower that the primary
reaction above.

Some of the other possible formation reactions are:

H^− + NH_4 ^+ → NH_3 + H_2 PNH_3 ^+ + e^− → P + NH_3


[edit ] Destruction mechanisms

There are 113 total proposed reactions leading to the destruction of NH_3
. Of these, 39 were tabulated in extensive tables of the chemistry among
C, N, and O compounds.^[28] A review of interstellar ammonia cites the
following reactions as the principal dissociation mechanisms:^[29]

(1) NH_3 + H_3 ^+ → NH_4 ^+ + H_2 (2) NH_3 + HCO^+ → NH_4 ^+ + CO

with rate constants of 4.39×10^−9 ^[30] and 2.2×10^−9 ,^[31]
respectively. The above equations (1,2) run at a rate of 8.8×10^−9 and
4.4×10^−13 , respectively. These calculations assumed the given rate
constants and abundances of [NH_3 ]/[H_2 ] = 10^−5 , [H_3 ^+ ]/[H_2 ] =
2×10^−5 , [HCO^+ ]/[H_2 ] = 2×10^−9 , and total densities of n =
10^5 , typical of cold, dense, molecular clouds.^[32] Clearly, between
these two primary reactions, equation (1) is the dominant destruction
reaction, with a rate ~10,000 times faster than equation (2). This is due
to the relatively high abundance of H_3 ^+ .


[edit ] Uses


[edit ] Fertilizer

Approximately 83% (as of 2004) of ammonia is used as fertilizers either as
its salts or as solutions. Consuming more than 1% of all man-made power,
the production of ammonia is a significant component of the world energy
budget.^[4]


[edit ] Precursor to nitrogenous compounds

Ammonia is directly or indirectly the precursor to most
nitrogen-containing compounds. Virtually all synthetic nitrogen compounds
are derived from ammonia. An important derivative is nitric acid . This
key material is generated via the Ostwald process by oxidation of ammonia
with air over a platinum catalyst at 700–850 °C, ~9 atm. Nitric oxide
is an intermediate in this conversion:^[33]

NH_3 + 2 O_2 → HNO_3 + H_2 O

Nitric acid is used for the production of fertilizers , explosives , and
many organonitrogen compounds.


[edit ] Cleaner

Household ammonia is a solution of NH_3 in water (i.e., ammonium hydroxide
) used as a general purpose cleaner for many surfaces. Because ammonia
results in a relatively streak-free shine, one of its most common uses is
to clean glass, porcelain and stainless steel. It is also frequently used
for cleaning ovens and soaking items to loosen baked-on grime. Household
ammonia ranges in concentration from 5 to 10 weight percent ammonia.


[edit ] Minor and emerging uses


[edit ] Refrigeration – R717

Because of its favourable vaporization properties, ammonia is an
attractive refrigerant .^[4] It was commonly used prior to the
popularisation of chlorofluorocarbons (Freons). Anhydrous ammonia is
widely used in industrial refrigeration applications and hockey rinks
because of its high energy efficiency and low cost. The Kalina cycle ,
which is of growing importance to geothermal power plants, depends on the
wide boiling range of the ammonia-water mixture. Ammonia is used less
frequently in commercial applications, such as in grocery store freezer
cases and refrigerated displays due to its toxicity.


[edit ] For remediation of gaseous emissions

Ammonia is used to scrub SO_2 from the burning of fossil fuels, and the
resulting product is converted to ammonium sulfate for use as fertilizer.
Ammonia neutralizes the nitrogen oxides (NO_x ) pollutants emitted by
diesel engines. This technology, called SCR (selective catalytic reduction
), relies on a vanadia-based catalyst.^[34]


[edit ] As a fuel



Drawing of an Ammoniacal Gas Engine Streetcar in New Orleans (1871) by
Alfred Rudolph Waud

Ammonia was used during World War II to power buses in Belgium, and in
engine and solar energy applications prior to 1900. Liquid ammonia was
used as the fuel of the rocket airplane, the X-15 . Although not as
powerful as other fuels, it left no soot in the reusable rocket engine and
its density approximately matches the density of the oxidizer, liquid
oxygen, which simplified the aircraft's design.

Ammonia has been proposed as a practical alternative to fossil fuel for
internal combustion engines .^[35] The calorific value of ammonia is 22.5
MJ/kg (9690 BTU /lb) which is about half that of diesel. In a normal
engine, in which the water vapour is not condensed, the calorific value of
ammonia will be about 21% less than this figure. It can be used in
existing engines with only minor modifications to carburettors /injectors
.

To meet these demands, significant capital would be required to increase
present production levels. Although the second most produced chemical, the
scale of ammonia production is a small fraction of world petroleum usage.
It could be manufactured from renewable energy sources, as well as coal or
nuclear power. It is however significantly less efficient than batteries.
The 60 MW Rjukan dam in Telemark , Norway produced ammonia via
electrolysis of water for many years from 1913 producing fertilizer for
much of Europe. If produced from coal, the CO_2 can be readily sequestered
^[35] ^[36] (the combustion products are nitrogen and water). In 1981 a
Canadian company converted a 1981 Chevrolet Impala to operate using
ammonia as fuel.^[37] ^[38]

Ammonia engines or ammonia motors, using ammonia as a working fluid , have
been proposed and occasionally used ^[39] . The principle is similar to
that used in a fireless locomotive , but with ammonia as the working
fluid, instead of steam or compressed air. Ammonia engines were used
experimentally in the 19th century by Goldsworthy Gurney in the UK and in
streetcars in New Orleans in the USA.


[edit ] Antimicrobial agent for food products

As early as in 1895 it was known that ammonia was "strongly antiseptic ..
it requires 1.4 grams per litre to preserve beef tea ."^[40] Anhydrous
ammonia has been shown effective as an antimicrobial agent for animal feed
^[41] and is currently used commercially to reduce or eliminate microbial
contamination of beef .^[42] ^[43] ^[44] The New York Times reported in
October, 2009 on an American company, Beef Products Inc. , which turns
fatty beef trimmings , averaging between 50 and 70 percent fat, into seven
million pounds per week of lean finely textured beef by removing the fat
using heat and centrifugation , then disinfecting the lean product with
ammonia; the process was rated by the US Department of Agriculture as
effective and safe on the basis of a study (financed by Beef Products)
which found that the treatment reduces E. coli to undetectable
levels.^[45] Further investigation by /The New York Times/ published in
December, 2009 revealed safety concerns about the process as well as
consumer complaints about the taste and smell of beef treated at optimal
levels of ammonia.^[46]


[edit ] As a stimulant in sports

Ammonia has found significant use in various sports – particularly the
strength sports of powerlifting and Olympic weightlifting as a respiratory
stimulant.^[/citation needed /]


[edit ] Textile

Liquid ammonia is used for treatment of cotton materials, give a
properties like mercerisation using alkalies. In particular, it is used
for pre-washing of wool.^[47]


[edit ] Lifting gas

At standard temperature and pressure ammonia is lighter than air, and has
approximately 60% of the lifting power of hydrogen or helium. Ammonia has
sometimes been used to fill weather balloons as a lifting gas . Because of
its relatively high boiling point (compared to helium and hydrogen),
ammonia could potentially be refrigerated and liquefied aboard an airship
to reduce lift and add ballast (and returned to a gas to add lift and
reduce ballast).


[edit ] Woodworking

Ammonia was historically used to darken quartersawn white oak in Arts &
Crafts and Mission style furniture. Ammonia fumes react with the natural
tannins in the wood and cause it to change colours.^[48]


[edit ] Ammonia's role in biological systems and human disease



Main symptoms of hyperammonemia (ammonia reaching toxic
concentrations).^[49]

Ammonia is an important source of nitrogen for living systems. Although
atmospheric nitrogen abounds, few living creatures are capable of using
this nitrogen. Nitrogen is required for the synthesis of amino acids,
which are the building blocks of protein . Some plants rely on ammonia and
other nitrogenous wastes incorporated into the soil by decaying matter.
Others, such as nitrogen-fixing legumes , benefit from symbiotic
relationships with rhizobia which create ammonia from atmospheric
nitrogen.^[50]

Ammonia also plays a role in both normal and abnormal animal physiology .
Ammonia is biosynthesised through normal amino acid metabolism and is
toxic in high concentrations.^[51] The liver converts ammonia to urea
through a series of reactions known as the urea cycle . Liver dysfunction,
such as that seen in cirrhosis , may lead to elevated amounts of ammonia
in the blood (hyperammonemia ). Likewise, defects in the enzymes
responsible for the urea cycle, such as ornithine transcarbamylase , lead
to hyperammonemia. Hyperammonemia contributes to the confusion and coma of
hepatic encephalopathy as well as the neurologic disease common in people
with urea cycle defects and organic acidurias .^[52]

Ammonia is important for normal animal acid/base balance. After formation
of ammonium from glutamine , α-ketoglutarate may be degraded to produce
two molecules of bicarbonate , which are then available as buffers for
dietary acids. Ammonium is excreted in the urine, resulting in net acid
loss. Ammonia may itself diffuse across the renal tubules, combine with a
hydrogen ion, and thus allow for further acid excretion.^[53]




Reference ranges for blood tests , comparing blood content of ammonia
(shown in yellow near middle) with other constituents.


[edit ] Excretion

Main article: Excretion

Ammonium ions are a toxic waste product of the metabolism in animals . In
fish and aquatic invertebrates, it is excreted directly into the water. In
mammals, sharks, and amphibians, it is converted in the urea cycle to urea
, because it is less toxic and can be stored more efficiently. In birds,
reptiles, and terrestrial snails, metabolic ammonium is converted into
uric acid , which is solid, and can therefore be excreted with minimal
water loss.^[54]


[edit ] Liquid ammonia as a solvent

See also: Inorganic nonaqueous solvent

Liquid ammonia is the best-known and most widely studied non-aqueous
ionising solvent. Its most conspicuous property is its ability to dissolve
alkali metals to form highly coloured, electrically conducting solutions
containing solvated electrons . Apart from these remarkable solutions,
much of the chemistry in liquid ammonia can be classified by analogy with
related reactions in aqueous solutions. Comparison of the physical
properties of NH_3 with those of water shows that NH_3 has the lower
melting point, boiling point, density, viscosity , dielectric constant and
electrical conductivity ; this is due at least in part to the weaker H
bonding in NH_3 and the fact that such bonding cannot form cross-linked
networks since each NH_3 molecule has only 1 lone-pair of electrons
compared with 2 for each H_2 O molecule. The ionic self-dissociation
constant of liquid NH_3 at −50 °C is about 10^−33 mol^2 ·L^−2 .


[edit ]
Solubility of salts

	Solubility (g of salt per 100 g liquid NH_3 )
Ammonium acetate  	253.2
Ammonium nitrate  	389.6
Lithium nitrate  	243.7
Sodium nitrate  	97.6
Potassium nitrate  	10.4
Sodium fluoride  	0.35
Sodium chloride  	3.0
Sodium bromide  	138.0
Sodium iodide  	161.9
Sodium thiocyanate  	205.5

Liquid ammonia is an ionising solvent, although less so than water, and
dissolves a range of ionic compounds including many nitrates , nitrites ,
cyanides and thiocyanates . Most ammonium salts are soluble, and these
salts act as acids in liquid ammonia solutions. The solubility of halide
salts increases from fluoride to iodide . A saturated solution of ammonium
nitrate contains 0.83 mol solute per mole of ammonia, and has a vapour
pressure of less than 1 bar even at 25 °C (77 °F).


[edit ] Solutions of metals

See also: Solvated electron

Liquid ammonia will dissolve the alkali metals and other electropositive
metals such as calcium , strontium , barium , europium and ytterbium . At
low concentrations (<0.06 mol/L), deep blue solutions are formed: these
contain metal cations and solvated electrons , free electrons which are
surrounded by a cage of ammonia molecules.

These solutions are very useful as strong reducing agents. At higher
concentrations, the solutions are metallic in appearance and in electrical
conductivity. At low temperatures, the two types of solution can coexist
as immiscible phases.


[edit ] Redox properties of liquid ammonia

See also: Redox
	/E/°  (V, ammonia) 	/E/°
(V, water)
Li^+ + e^− ⇌ Li 	−2.24 	−3.04
K^+ + e^− ⇌ K 	−1.98 	−2.93
Na^+ + e^− ⇌ Na 	−1.85 	−2.71
Zn^2+ + 2e^− ⇌ Zn 	−0.53 	−0.76
NH_4 ^+ + e^− ⇌ ½ H_2 + NH_3 	0.00 	—
Cu^2+ + 2e^− ⇌ Cu 	+0.43 	+0.34
Ag^+ + e^− ⇌ Ag 	+0.83 	+0.80

The range of thermodynamic stability of liquid ammonia solutions is very
narrow, as the potential for oxidation to dinitrogen, /E/° (N_2 + 6NH_4
^+ + 6e^− ⇌ 8NH_3 ), is only +0.04 V. In practice, both oxidation to
dinitrogen and reduction to dihydrogen are slow. This is particularly true
of reducing solutions: the solutions of the alkali metals mentioned above
are stable for several days, slowly decomposing to the metal amide and
dihydrogen. Most studies involving liquid ammonia solutions are done in
reducing conditions: although oxidation of liquid ammonia is usually slow,
there is still a risk of explosion, particularly if transition metal ions
are present as possible catalysts.


[edit ] Detection and determination

Ammonia and ammonium salts can be readily detected, in very minute traces,
by the addition of Nessler's solution , which gives a distinct yellow
coloration in the presence of the least trace of ammonia or ammonium
salts. Sulfur sticks are burnt to detect small leaks in industrial ammonia
refrigeration systems. Larger quantities can be detected by warming the
salts with a caustic alkali or with quicklime , when the characteristic
smell of ammonia will be at once apparent. The amount of ammonia in
ammonium salts can be estimated quantitatively by distillation of the
salts with sodium or potassium hydroxide , the ammonia evolved being
absorbed in a known volume of standard sulfuric acid and the excess of
acid then determined volumetrically ; or the ammonia may be absorbed in
hydrochloric acid and the ammonium chloride so formed precipitated as
ammonium hexachloroplatinate , (NH_4 )_2 PtCl_6 .


[edit ] Interstellar space

Ammonia was first detected in interstellar space in 1968, based on
microwave emissions from the direction of the galactic core .^[55] This
was the first polyatomic molecule to be so detected. The sensitivity of
the molecule to a broad range of excitations and the ease with which it
can be observed in a number of regions has made ammonia one of the most
important molecules for studies of molecular clouds .^[29] The relative
intensity of the ammonia lines can be used to measure the temperature of
the emitting medium.

The following isotopic species of ammonia have been detected:

NH_3 , ^15 NH_3 , NH_2 D , NHD_2 , and ND_3

The detection of triply-deuterated ammonia was considered a surprise as
deuterium is relatively scarce. It is thought that the low-temperature
conditions allow this molecule to survive and accumulate.^[56] The ammonia
molecule has also been detected in the atmospheres of the gas giant
planets, including Jupiter , along with other gases like methane,
hydrogen, and helium . The interior of Saturn may include frozen crystals
of ammonia.^[57] It is naturally found on Deimos and phobos; the moons of
Mars.

Since its interstellar discovery, NH_3 has proved to be an invaluable
spectroscopic tool in the study of the interstellar medium. With a large
number of transitions sensitive to a wide range of excitation conditions,
NH_3 has been widely astronomically detected – its detection has been
reported in hundreds of journal articles. Listed below is a sample of
journal articles that highlights the range of detectors that have been
used to identify ammonia.


[edit ] Single antenna detections

Radio observations of NH_3 from the Effelsberg 100-m Radio Telescope
reveal that the ammonia line is separated into two components – a
background ridge and an unresolved core. The background corresponds well
with the locations previously-detected CO.^[58] The 25 m Chilbolton
telescope in England detected radio signatures of ammonia in H II regions
, HNH_2 O masers , H-H objects, and other objects associated with star
formation. A comparison of emission line widths indicates that turbulent
or systematic velocities do not increase in the central cores of molecular
clouds.^[59]


Microwave radiation from ammonia was observed in several galactic objects
including W3(OH), Orion A , W43, W51, and five sources in the galactic
centre. The high detection rate indicates that this is a common molecule
in the interstellar medium and that high-density regions are common in the
galaxy.^[60]


[edit ] Interferometric studies

VLA observations of NH_3 in seven regions with high-velocity gaseous
outflows reveal condensations of less than 0.1 pc in L1551, S140, and
Cepheus A . Three individual condensations were detected in Cepheus A, one
of them with a highly elongated shape. They may play an important role in
creating the bipolar outflow in the region.^[61]

Extragalactic ammonia was imaged using the VLA in IC 342 . The hot gas has
temperatures above 70 K inferred from ammonia line ratios and appears to
be closely associated with the innermost portions of the nuclear bar seen
in CO.^[62] NH_3 was also monitored by VLA towards a sample of four
galactic ultracompact HII regions: G9.62+0.19, G10.47+0.03, G29.96-0.02,
and G31.41+0.31. Based upon temperature and density diagnostics, it is
concluded that in general such clumps are likely to be the sites of
massive star formation in an early evolutionary phase prior to the
development of an ultracompact HII region.^[63]


[edit ] Infrared detections

Absorption at 2.97 micrometres due to solid ammonia was recorded from
interstellar grains in the Becklin-Neugebauer Object and probably in NGC
2264-IR as well. This detection helped explaining the physical shape of
previously poorly understood and related ice absorption lines.^[64]

A spectrum of the disk of Jupiter was obtained from the Kuiper Airborne
Observatory , covering the 100 to 300 cm^−1 spectral range. Analysis of
the spectrum provides information on global mean properties of ammonia gas
and an ammonia ice haze.^[65]


A total of 149 dark cloud positions were surveyed for evidence of 'dense
cores' by using the (J,K) = (1,1) rotating inversion line of NH_3 . The
cores are not generally spherically shaped, with aspect ratios ranging
from 1.1 to 4.4. It is also found that cores with stars have broader lines
than cores without stars.^[66]

Ammonia has been detected in the Draco Nebula and in one or possibly two
molecular clouds, which are associated with the high-latitude galactic
infrared cirrus . The finding is significant because they may represent
the birthplaces for the Population I metallicity B-type stars in the
galactic halo which could have been borne in the galactic disk.^[67]


[edit ] Astronomical observations and research applications

The study of interstellar ammonia has been important to a number of areas
of research in the last few decades. Some of these are delineated below
and primarily involve using ammonia as an interstellar thermometer.


[edit ] Observations of nearby dark clouds

By balancing and stimulated emission with spontaneous emission, it is
possible to construct a relation between excitation temperature and
density. Moreover, since the transitional levels of ammonia can be
approximated by a 2-level system at low temperatures, this calculation is
fairly simple. This premise can be applied to dark clouds, regions
suspected of having extremely low temperatures and possible sites for
future star formation. Detections of ammonia in dark clouds show very
narrow lines — indicative not only of low temperatures, but also of a
low level of inner-cloud turbulence. Line ratio calculations provide a
measurement of cloud temperature that is independent of previous CO
observations. The ammonia observations were consistent with CO
measurements of rotation temperatures of ~10 K. With this, densities can
be determined, and have been calculated to range between 10^4 and 10^5
cm^−3 in dark clouds. Mapping of NH_3 gives typical clouds sizes of 0.1
pc and masses near 1 solar mass. These cold, dense cores are the sites of
future star formation.


[edit ] UC HII regions

Ultra-compact HII regions are among the best tracers of high-mass star
formation. The dense material surrounding UCHII regions is likely
primarily molecular. Since a complete study of massive star formation
necessarily involves the cloud from which the star formed, ammonia is an
invaluable tool in understanding this surrounding molecular material.
Since this molecular material can be spatially resolved, it is possible to
constrain the heating/ionising sources, temperatures, masses, and sizes of
the regions. Doppler-shifted velocity components allow for the separation
of distinct regions of molecular gas which can trace outflows and hot
cores originating from forming stars.


[edit ] Extragalactic detection

Ammonia has been detected in external galaxies, and by simultaneously
measuring several lines, it is possible to directly measure the gas
temperature in these galaxies. Line ratios imply that gas temperatures are
warm (~50 K), originating from dense clouds with sizes of tens of pc. This
picture is consistent with the picture within our Milky Way galaxy — hot
dense molecular cores form around newly-forming stars embedded in larger
clouds of molecular material on the scale of several hundred pc (giant
molecular clouds; GMCs).


[edit ] Safety precautions



The world's longest ammonia pipeline , running from the TogliattiAzot
plant in Russia to Odessa in Ukraine .

The U. S. Occupational Safety and Health Administration (OSHA) has set a
15-minute exposure limit for gaseous ammonia of 35 ppm by volume in the
environmental air and an 8-hour exposure limit of 25 ppm by volume.^[68]
NIOSH recently reduced the IDLH from 500 to 300 based on recent more
conservative interpretations of original research in 1943. IDLH
(Immediately Dangerous to Life and Health) is the level to which a healthy
worker can be exposed for 30 minutes without suffering irreversible health
effects. Other organizations have varying exposure levels. U.S. Navy
Standards [U.S. Bureau of Ships 1962] maximum allowable concentrations
(MACs):continuous exposure (60 days): 25 ppm / 1 hour: 400 ppm ^[69]
Ammonia vapour has a sharp, irritating, pungent odour that acts as a
warning of potentially dangerous exposure. The average odour threshold is
5 ppm, well below any danger or damage. Exposure to very high
concentrations of gaseous ammonia can result in lung damage and
death.^[68] Although ammonia is regulated in the United States as a
non-flammable gas, it still meets the definition of a material that is
toxic by inhalation and requires a hazardous safety permit when
transported in quantities greater than 13,248 L (3,500 gallons).^[70]


[edit ] Toxicity and storage information



Hydrochloric acid sample releasing HCl fumes, which are reacting with
ammonia fumes to produce a white smoke of ammonium chloride.

The toxicity of ammonia solutions does not usually cause problems for
humans and other mammals, as a specific mechanism exists to prevent its
build-up in the bloodstream. Ammonia is converted to carbamoyl phosphate
by the enzyme carbamoyl phosphate synthetase , and then enters the urea
cycle to be either incorporated into amino acids or excreted in the urine.
However, fish and amphibians lack this mechanism, as they can usually
eliminate ammonia from their bodies by direct excretion. Ammonia even at
dilute concentrations is highly toxic to aquatic animals, and for this
reason it is classified as /dangerous for the environment/. Ammonium
compounds should never be allowed to come in contact with bases (unless in
an intended and contained reaction), as dangerous quantities of ammonia
gas could be released.


[edit ] Household use

Solutions of ammonia (5–10% by weight) are used as household cleaners,
particularly for glass. These solutions are irritating to the eyes and
mucous membranes (respiratory and digestive tracts), and to a lesser
extent the skin. Caution should be used that the chemical is never mixed
into any liquid containing bleach, or a poisonous gas may result. Mixing
with chlorine -containing products or strong oxidants, for example
household bleach can lead to hazardous compounds such as chloramines
.^[71]


[edit ] Laboratory use of ammonia solutions

The hazards of ammonia solutions depend on the concentration: "dilute"
ammonia solutions are usually 5–10% by weight (<5.62 mol/L);
"concentrated" solutions are usually prepared at >25% by weight. A 25% (by
weight) solution has a density of 0.907 g/cm^3 , and a solution which has
a lower density will be more concentrated. The European Union
classification of ammonia solutions is given in the table.

Concentration 
by weight (w/w) 	Molarity  	Concentration

mass/volume (w/v) 	Classification 	R-Phrases 
5–10% 	2.87—5.62 mol/L 	48.9–95.7 g/L 	Irritant (*Xi*) 	R36/37/38

10–25% 	5.62–13.29 mol/L 	95.7–226.3 g/L 	Corrosive (*C*) 	R34

>25% 	>13.29 mol/L 	>226.3 g/L 	Corrosive (*C*)
Dangerous for
the environment (*N*) 	R34 , R50


/S-Phrases : (S1/2)
, S16
,
S36/37/39
,
S45
,
S61
./

The ammonia vapour from concentrated ammonia solutions is severely
irritating to the eyes and the respiratory tract, and these solutions
should only be handled in a fume hood. Saturated ("0.880") solutions can
develop a significant pressure inside a closed bottle in warm weather, and
the bottle should be opened with care; this is not usually a problem for
25% ("0.900") solutions.

Ammonia solutions should not be mixed with halogens , as toxic and/or
explosive products are formed. Prolonged contact of ammonia solutions with
silver , mercury or iodide salts can also lead to explosive products: such
mixtures are often formed in qualitative chemical analysis , and should be
lightly acidified but not concentrated (<6% w/v) before disposal once the
test is completed.


[edit ] Laboratory use of anhydrous ammonia (gas or liquid)

Anhydrous ammonia is classified as toxic (*T*) and dangerous for the
environment (*N*). The gas is flammable (autoignition temperature : 651
°C) and can form explosive mixtures with air (16–25%). The permissible
exposure limit (PEL) in the United States is 50 ppm (35 mg/m^3 ), while
the IDLH concentration is estimated at 300 ppm. Repeated exposure to
ammonia lowers the sensitivity to the smell of the gas: normally the odour
is detectable at concentrations of less than 50 ppm, but desensitised
individuals may not detect it even at concentrations of 100 ppm. Anhydrous
ammonia corrodes copper - and zinc -containing alloys , and so brass
fittings should not be used for handling the gas. Liquid ammonia can also
attack rubber and certain plastics.

Ammonia reacts violently with the halogens. Nitrogen triiodide , a primary
high explosive , is formed when ammonia comes in contact with iodine .
Ammonia causes the explosive polymerisation of ethylene oxide . It also
forms explosive fulminating compounds with compounds of gold , silver ,
mercury , germanium or tellurium , and with stibine . Violent reactions
have also been reported with acetaldehyde , hypochlorite solutions,
potassium ferricyanide and peroxides .


[edit ] Mapping of industrial releases in the United States

One tool that maps releases of ammonia [1] to particular locations in the
United States^[72] and also provides additional information about such
releases is TOXMAP . TOXMAP is a Geographic Information System (GIS) from
the Division of Specialized Information Services of the United States
National Library of Medicine (NLM) that uses maps of the United States to
help users visually explore data from the United States Environmental
Protection Agency 's (EPA) Toxics Release Inventory and Superfund Basic
Research Programs . TOXMAP is a resource funded by the US Federal
Government. TOXMAP's chemical and environmental health information is
taken from NLM's Toxicology Data Network (TOXNET)^[73] and PubMed , and
from other authoritative sources.


[edit ] See also

* Ammonia (data page) 
* Ammonia production 
* Chlorination 
* Forming gas 
* Relative cost of electricity generated by different sources

* Water purification 


[edit ] References

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[edit ] Bibliography

*  This article incorporates text from a
publication now in the public domain
: Chisholm, Hugh, ed (1911). /Encyclopædia
Britannica /
(Eleventh ed.). Cambridge University Press. 
* Greenwood, Norman N.; Earnshaw, A. (1997), /Chemistry of the
Elements/ (2nd ed.), Oxford: Butterworth-Heinemann, ISBN
0080379419

* Housecroft, C. E.; Sharpe, A. G. (2000). /Inorganic Chemistry/
(1st ed.). Prentice Hall . ISBN
978-0582310803
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* edited by L. Bretherick. (1986). Bretherick, L.. ed. /Hazards in
the Chemical Laboratory/ (4th Edn. ed.). London: Royal Society of
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* Weast, R. C., ed. (1972), /Handbook of Chemistry and Physics/
(53rd ed.), Cleveland, OH: Chemical Rubber Co. 


[edit ] External
links

	Wikimedia Commons has media related to: /*Ammonia
*/

* International Chemical Safety Card 0414

(anhydrous ammonia), ilo.org.
* International Chemical Safety Card 0215

(aqueous solutions), ilo.org.
* National Pollutant Inventory – Ammonia
,
npi.gov.au.
* CID 222
from
PubChem 
* (French) Institut national de recherche et de sécurité

* Emergency Response to Ammonia Fertilizer Releases (Spills)
for the Minnesota Department of
Agriculture.ammoniaspills.org
* National Institute for Occupational Safety and Health – Ammonia
Page , cdc.gov