Chemicals/Nitrogens

File:Violet aurora Ohio US Oct 2013.jpg

This is a lecture on the general nature and specific characteristics of various natural and hominin-made nitrogens. It is an offering from the school of chemistry.

The aurora on the right contains an intense violet band above the pink band. Template:Clear

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A nitrogen green emission line occurs in plasmas at 566.934 nm from N VIII.^[1]

Nitrogen has an emission line at 658.4 nm.

Nitrogen has two emission lines that occur in plasmas at 455.368 and 455.545 nm from N VII.^[1]

There is an "(0,2) vibrational component of the B-x electronic transition of N₂⁽⁺⁾ at 470.9 nm."^[2]

Nitrogen has an emission line that occurs in plasmas at 388.678 nm from N VII.^[1]

As seen in its spectrum above, nitrogen has many emission lines in the violet. Template:Clear

Template:Main Atomic nitrogen is an allotrope of nitrogen.

Given the great reactivity of atomic nitrogen, elemental nitrogen usually occurs as molecular N₂, dinitrogen which is a colourless, odourless, and tasteless diamagnetic gas at standard conditions: it melts at −210 °C and boils at −196 °C.^[3] Dinitrogen is mostly unreactive at room temperature, but it will nevertheless react with lithium metal and some transition metal complexes 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 chemical inertness.^[3]

Azide is Template:Chem, pentazenium (Template:Chem), and pentazolide (cyclic aromatic Template:Chem).^[4]

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".^[5]

Template:Main 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.^[3]

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In the nuclide map on the right, 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.

1. Template:Chem
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3. Template:Chem 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 even milliseconds. No other nitrogen isotopes are possible as they would fall outside the nuclear drip lines, leaking out a proton or neutron.^[6] 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.^[7]
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5. Template:Chem Nitrogen has two stable isotopes: ¹⁴N and ¹⁵N, where 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%, which leads to an atomic weight of around 14.007 u.^[8] Both of these stable isotopes are produced in the CNO cycle in stars, but ¹⁴N is (1) more common as its neutron capture is the rate-limiting step and (2) ¹⁴N is one of the five stable odd–odd nuclides (a nuclide having an odd number of protons and neutrons).^[9]
6. Template:Chem
7. Template:Chem The radioisotope ¹⁶N is the dominant radionuclide in the coolant of pressurised water reactors or boiling water reactors during normal operation, and thus 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. 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,^[6] but during its decay back to ¹⁶O produces high-energy gamma radiation (5 to 7 MeV).^[6][10] Because of this, access to the primary coolant piping in a pressurised water reactor must be restricted during reactor power operation.^[10]
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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.^[11] Biologically mediated reactions (e.g., assimilation, nitrification, and denitrification) strongly control nitrogen dynamics in the soil, where these reactions typically result in ¹⁵N enrichment of the substrate and depletion of the product.^[12]

The ¹⁵N:¹⁴N ratio is commonly used in stable isotope analysis in the fields of geochemistry, hydrology, paleoclimatology and paleoceanography, where it is called δTemplate:Chem.^[13] Template:Clear

Template:Main "The disintegration of nitrogen by slow neutrons has been studied in photographic emulsions of different sensitivity, which enable an unambiguous distinction to be made between the emission of α-particles and protons. Evidence has been obtained that the disintegration takes place according to the reaction

¹n + Template:Nuclide → Template:Nuclide + Template:Nuclide

with a cross-section of about 10−24 cm²."^[14]

"The fast neutrons from uranium fission can be moderated by elastic collision with graphite or heavy water in a nuclear reactor until their velocity is reduced to that of thermal energies (average 2200 meters/sec= 0.025 electron volts); such very slow neutrons are called thermal neutrons. Unlike fast neutrons, whose principal reaction with matter is one of scattering, thermal neutrons because of their very low energy and velocity are more likely to be captured than scattered by the atoms they encounter. Most of the reactions of biological elements with thermal neutrons are capture reactions. After an atom captures a neutron, it forms a new compound nucleus with an excess of energy. This new compound nucleus may then:

1. emit immediately a capture radiation to form a radioactive daughter which subsequently emits beta or gamma rays at a rate characteristic for the isotope formed, e.g.,

Template:Nuclide + ¹n → [[[:Template:Nuclide]]] → Template:Nuclide* + p (half life = 6,000 years) → Template:Nuclide + β^-."^[15]

Template:Main Nitrogen is element number seven based on the number of protons in its nucleus.

Template:Main "Isotopes which undergo this decay and thereby emit positrons include carbon-11, potassium-40, nitrogen-13, oxygen-15, fluorine-18, and iodine-121. As an example, the following equation describes the beta plus decay of carbon-11 to boron-11, emitting a positron and a neutrino:"^[16]

${\displaystyle \underset{11}{\overset{}{6}}}C\to {}_5^{11}B+e^{+}+{\nu }_e+\gamma (0.96MeV).$

Template:Main "The [cosmic-ray] shower can be observed by: i) sampling the electromagnetic and hadronic components when they reach the ground with an array of particle detectors such as scintillators, ii) detecting the fluorescent light emitted by atmospheric nitrogen excited by the passage of the shower particles, iii) detecting the Cerenkov light emitted by the large number of particles at shower maximum, and iv) detecting muons and neutrinos underground."^[17]

Template:Main "These “atmospheric neutrinos” come from the decay of pions and kaons produced by the collisions of cosmic-ray particles with nitrogen and oxygen in the atmosphere."^[18]

Template:Main Several emission lines occur in plasmas at 347.872, 348.30, and 348.493 nm from N IV and 252.255, 344.211, and 388.678 nm from N VII.^[1]

Molecular nitrogen and nitrogen compounds have been detected in interstellar space by astronomers using the Far Ultraviolet Spectroscopic Explorer.^[19]

Template:Main "[T]he 5198-, 5201-A lines of nitrogen [occur] in the [Earth's] nightglow."^[20]

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File:Violet aurora.jpg

"Auroras are known to be generated by beams of electrons which are accelerated along Earth's magnetic field lines. The fast-moving electrons collide with atoms in the ionosphere at altitudes of between 100 to 600 km. This interaction with oxygen atoms results in a green or, more rarely, red glow in the night sky, while nitrogen atoms yield blue and purple colours."^[21]

The aurora borealis imaged on the right shows blue, violet, and purple colors with the Milky Way in the background. Template:Clear

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File:Blue aurora.jpg

File:Micha- DSC0788 filtered 1393514536 lg.jpg

File:Northern Lights Canada 1 Oct 2012.jpg

"When the charged particles from the Sun penetrate Earth's magnetic shield, they are channelled downwards along the magnetic field lines until they strike atoms of gas high in the atmosphere. Like a giant fluorescent neon lamp, the interaction with excited oxygen atoms generates a green or, more rarely, red glow in the night sky, while excited nitrogen atoms yield blue and purple colours."^[22]

There is an "(0,2) vibrational component of the B-x electronic transition of N₂⁽⁺⁾ at 470.9 nm."^[2]

The image on the right shows blue aurora borealis that occurred over Iceland.

The second image down on the right shows an extensive blue aurora above the green over Canada.

The image on the left shows an extensive blue aurora. Template:Clear

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Nitrogen appears to have lines near to the cyan.

"M2-9 [in the image at right] is a striking example of a "butterfly" or a bipolar planetary nebula. Another more revealing name might be the "Twin Jet Nebula." If the nebula is sliced across the star, each side of it appears much like a pair of exhausts from jet engines. Indeed, because of the nebula's shape and the measured velocity of the gas, in excess of 200 miles per second, astronomers believe that the description as a super-super-sonic jet exhaust is quite apt. Ground-based studies have shown that the nebula's size increases with time, suggesting that the stellar outburst that formed the lobes occurred just 1,200 years ago."^[23]

"The central star in M2-9 is known to be one of a very close pair which orbit one another at perilously close distances. It is even possible that one star is being engulfed by the other. Astronomers suspect the gravity of one star pulls weakly bound gas from the surface of the other and flings it into a thin, dense disk which surrounds both stars and extends well into space."^[23]

"The disk can actually be seen in shorter exposure images obtained with the Hubble telescope. It measures approximately 10 times the diameter of Pluto's orbit. Models of the type that are used to design jet engines ("hydrodynamics") show that such a disk can successfully account for the jet-exhaust-like appearance of M2-9. The high-speed wind from one of the stars rams into the surrounding disk, which serves as a nozzle. The wind is deflected in a perpendicular direction and forms the pair of jets that we see in the nebula's image. This is much the same process that takes place in a jet engine: The burning and expanding gases are deflected by the engine walls through a nozzle to form long, collimated jets of hot air at high speeds."^[23]

"M2-9 is 2,100 light-years away in the constellation Ophiucus. The observation was taken Aug. 2, 1997 by the Hubble telescope's Wide Field and Planetary Camera 2. In this image, neutral oxygen is shown in red, once-ionized nitrogen in green, and twice-ionized oxygen in blue."^[23] Template:Clear

Template:Main Nitrogen has a yellow forbidden line, specifically N II at 575.5 nm, that may be used to indicate nitrogen abundances and contribute to nitrogen/oxygen (N/O) abundance gradients. Surveys of H II regions in spiral galaxies have suggested that N/O abundance ratios increase from outer-arm nebulae to inner-arm nebulae.^[24] "Electron temperatures are generally derived from the ratio of auroral to nebular lines in [O III] or [N II]."^[25] "[B]ecause of the proximity of strong night-sky lines at λ4358 and λλ5770, 5791, the auroral lines of [O III] λ4363 and [N II] λ5755 are often contaminated."^[25] Template:Clear

Template:Main Nitrogen has a weak line in the orange.

Template:Main The carbon-burning process is a set of nuclear reactions that may require high temperatures (> 5×10⁸ K or 50 keV) and densities (> 3×10⁹ kg/m³).^[26]

The principal reactions are:^[27]"

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 1.95 MeV

Template:Nuclide2   → Template:Nuclide2 + e⁺ + Template:SubatomicParticle + 1.20 MeV (half-life of 9.965 minutes^[28]), or ¹²C(p,γ)¹³N.

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 7.54 MeV

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 7.35 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 1.73&bsp;MeV (half-life of 122.24 seconds^[28])

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + Template:Nuclide2 + 4.96 MeV:^[29]

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 12.13 MeV

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 0.60 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 2.76 MeV (half-life of 64.49 seconds)

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + Template:Nuclide2 + 1.19 MeV

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 7.35 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 2.75 MeV (half-life of 122.24 seconds)

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 5.61 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 1.656 MeV (half-life of 109.771 minutes)

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + Template:Nuclide2 + 3.98 MeV

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 12.13 MeV

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 0.60 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 2.76 MeV (half-life of 64.49 seconds)

These reactions may occur in massive stars.

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + Template:Nuclide2   + 8.114 MeV

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 0.60 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 2.76 MeV (half-life of 64.49 seconds)

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 5.61 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 1.656 MeV (half-life of 109.771 minutes)

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 7.994 MeV

These are the hot CNO cycles reactions with conditions of higher temperature as have been found in novae and X-ray bursts.

When the rate of proton captures exceeds the rate of beta-decay, the burning conforms to the proton drip line. A radioactive species captures a proton before it can beta decay.

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 1.95 MeV

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 4.63 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 5.14 MeV (half-life of 70.641 seconds)

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 7.35 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 2.75 MeV (half-life of 122.24 seconds)

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + Template:Nuclide2  + 4.96 MeV

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 12.13 MeV

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 0.60 MeV

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 3.92 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 4.44 MeV (half-life of 1.672 seconds)

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + Template:Nuclide2 + 2.88 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 2.75 MeV (half-life of 122.24 seconds)

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 6.41 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 3.32 MeV (half-life of 17.22 seconds)

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + Template:Nuclide2  + 8.11 MeV

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 0.60 MeV

Template:Nuclide2 + Template:Nuclide2 → Template:Nuclide2 + γ   + 3.92 MeV

Template:Nuclide2   → Template:Nuclide2 + Template:SubatomicParticle + Template:SubatomicParticle + 4.44 MeV (half-life of 1.672 seconds)

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Blue jets differ from sprites in that they project from the top of the cumulonimbus above a thunderstorm, typically in a narrow cone, to the lowest levels of the ionosphere 40 to 50 km (25 to 30 miles) above the earth, whereas red sprites tend to be associated with significant lightning strikes, blue jets do not appear to be directly triggered by lightning (they do, however, appear to relate to strong hail activity in thunderstorms).^[30]

They are also brighter than sprites and, as implied by their name, are blue in color. The color is believed to be due to a set of blue and near-ultraviolet emission lines from neutral and ionized molecular nitrogen."^[31] Template:Clear

"Molecular nitrogen (N₂) [is] a colorless, odorless gas at room temperature."^[32] Template:Clear

"The CN radical through emission in its Violet system bands has a long-established presence in comets."^[33] Template:Clear

On the right liquid diatomic nitrogen (N₂) is being poured.

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.^[34] Template:Clear

At atmospheric pressure, molecular nitrogen condenses (liquefies) at 77 K (−195.79 °C) and freezes at 63 K (−210.01 °C)^[35] 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).^[36]

Solid nitrogen has many crystalline modifications, forming a significant dynamic surface coverage on Pluto^[37] and outer moons of the Solar System such as Triton.^[38] 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.^[39]

"In this highest-resolution image [on the right] from NASA's New Horizons spacecraft, great blocks of Pluto's water-ice crust appear jammed together in the informally named al-Idrisi mountains. Some mountain sides appear coated in dark material, while other sides are bright. Several sheer faces appear to show crustal layering, perhaps related to the layers seen in some of Pluto's crater walls. Other materials appear crushed between the mountains, as if these great blocks of water ice, some standing as much as 1.5 miles high, were jostled back and forth. The mountains end abruptly at the shoreline of the informally named Sputnik Planum, where the soft, nitrogen-rich ices of the plain form a nearly level surface, broken only by the fine trace work of striking, cellular boundaries and the textured surface of the plain's ices (which is possibly related to sunlight-driven ice sublimation). This view is about 50 miles wide. The top of the image is to Pluto's northwest."^[40]

"These images were made with the telescopic Long Range Reconnaissance Imager (LORRI) aboard New Horizons, in a timespan of about a minute centered on 11:36 UT on July 14 -- just about 15 minutes before New Horizons' closest approach to Pluto -- from a range of just 10,000 miles (17,000 kilometers). They were obtained with an unusual observing mode; instead of working in the usual "point and shoot," LORRI snapped pictures every three seconds while the Ralph/Multispectral Visual Imaging Camera (MVIC) aboard New Horizons was scanning the surface. This mode requires unusually short exposures to avoid blurring the images."^[40] Template:Clear

Template:Main "Initially, the Template:Chem atoms get oxidized to Template:Chem, primarily (Pandow et al. 1960; MacKay et al. (1963):"^[41]

1. C(g) + O₂ ⟶ CO + O: ∆H = –138.96kcal

"In the atmosphere, initially 90–100% of the Template:Chem produced is oxidized to Template:Chem (Pandow et al. 1960)."^[41]

"In the atmosphere, the main removal process for Template:Chem is oxidation by OH radicals (cf. Jockel et al. 1999). Because of the low abundance of CO in the atmosphere, and the formation of Template:Chem initially, the Template:Chem/Template:Chem ratio in the atmospheric CO is much higher than in the atmospheric Template:Chem; by about two orders of magnitude in the lower stratosphere (Brenninkmeijer et al. 1995)."^[41] Template:Clear

"The atmosphere of Titan is largely composed of nitrogen; minor components lead to the formation of methane and ethane clouds and nitrogen-rich organic smog."^[42] Template:Clear

Template:Main

At right is an image gaseous objects ("cometary knots") discovered in the thousands. These knots are imaged with the Hubble Space Telescope while exploring the Helix nebula, the closest planetary nebula to Earth at 450 light-years away in the constellation Aquarius. Although ground-based telescopes have revealed such objects, astronomers have never seen so many of them. The most visible knots all lie along the inner edge of the doomed star's ring, trillions of miles away from the star's nucleus. Although these gaseous knots appear small, they're actually huge. Each gaseous head is at least twice the size of our solar system; each tail stretches for 100 billion miles, about 1,000 times the distance between the Earth and the Sun. The image was taken in August 1994 with Hubble's Wide Field Planetary Camera 2. The red light depicts nitrogen emission ([NII] 658.4 nm).

The left image is a color picture, taken with the Wide Field Planetary Camera-2. It is a composite of three images taken at different wavelengths. (red, hydrogen-alpha; blue, neutral oxygen, 630.0 nm; green, ionized nitrogen, 658.4 nm). This NASA Hubble Space Telescope image shows one of the most complex planetary nebulae ever seen, NGC 6543, nicknamed the "Cat's Eye Nebula." The image was taken on September 18, 1994. NGC 6543 is 3,000 light-years away in the northern constellation Draco. The term planetary nebula is a misnomer; dying stars create these cocoons when they lose outer layers of gas. Template:Clear

Template:Main "The nitrogen abundance appears to increase with decreasing galactocentric distance. ... A least-squares solution weighting the points equally gives a magnitude for the gradient d(log N/H)/dr = -0.10 ± 0.03 kpc^-1."^[25] "The ratio N/O clearly increases with decreasing R. A least-squares fit to the data ... gives d(log N/O)/dr = -0.06 ± 0.02 kpc^-1."^[25]

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"Plasma cleaning involves the removal of impurities and contaminants from surfaces through the use of an energetic plasma created from gaseous species. Gases such as argon and oxygen, as well as mixtures such as air and hydrogen/nitrogen are used. The plasma is created by using high frequency voltages (typically kHz to >MHz) to ionise the low pressure gas (typically around 1/1000 atmospheric pressure), although atmospheric pressure plasmas are now also common."^[43] Template:Clear

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1. To form a nitrogen plasma, diatomic molecular nitrogen gas must be dissociated into monatomic nitrogen gas, then one or more electrons must be either added or taken away.

Template:Div col

• Rocks as chemicals
• Rocks
• Solids
• Thoriums
• Volcanoes

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Template:Div col

• Argons
• Bromines
• Chemicals
• Chlorines
• Fluorines
• Gases
• Geochemistry
• Heliums
• Hydrogens
• Iodines
• Kryptons
• Liquids
• Materials
• Mineraloids
• Neons
• Nitrogens
• Oxidanes
• Oxidation numbers
• Oxygens
• Radons
• Reactions
• Xenons

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