|Allotropes||O2, O3 (ozone) and more (see Allotropes of oxygen)|
liquid and solid: pale blue
|Standard atomic weight Ar, std(O)||[15.99903, 15.99977] conventional: 15.999|
|in the Earth's crust||461000 ppm|
|Oxygen in the periodic table|
|Atomic number (Z)||8|
|Group||group 16 (chalcogens)|
|Electron configuration||[He] 2s2 2p4|
|Electrons per shell||2, 6|
|Melting point||(O2) 54.36 K (−218.79 °C, −361.82 °F)|
|Boiling point||(O2) 90.188 K (−182.962 °C, −297.332 °F)|
|Density (at STP)||1.429 g/L|
|when liquid (at b.p.)||1.141 g/cm3|
|Triple point||54.361 K, 0.1463 kPa|
|Critical point||154.581 K, 5.043 MPa|
|Heat of fusion||(O2) 0.444 kJ/mol|
|Heat of vaporization||(O2) 6.82 kJ/mol|
|Molar heat capacity||(O2) 29.378 J/(mol·K)|
|Oxidation states||−2, −1, 0, +1, +2|
|Electronegativity||Pauling scale: 3.44|
|Covalent radius||66±2 pm|
|Van der Waals radius||152 pm|
|Spectral lines of oxygen|
|Speed of sound||330 m/s (gas, at 27 °C)|
|Thermal conductivity||26.58×10−3 W/(m⋅K)|
|Molar magnetic susceptibility||+3449.0×10−6 cm3/mol (293 K)|
|Discovery||Carl Wilhelm Scheele (1771)|
|Named by||Antoine Lavoisier (1777)|
|Main isotopes of oxygen|
Oxygen is the chemical element with the symbol O and atomic number 8. It is a member of the chalcogen group in the periodic table, a highly reactive nonmetal, and an oxidizing agent that readily forms oxides with most elements as well as with other compounds. Oxygen is Earth's most abundant element, and after hydrogen and helium, it is the third-most abundant element in the universe. At standard temperature and pressure, two atoms of the element bind to form dioxygen, a colorless and odorless diatomic gas with the formula O
2. Diatomic oxygen gas currently constitutes 20.95% of the Earth's atmosphere, though this has changed considerably over long periods of time. Oxygen makes up almost half of the Earth's crust in the form of oxides.
Dioxygen provides the energy released in combustion and aerobic cellular respiration, and many major classes of organic molecules in living organisms contain oxygen atoms, such as proteins, nucleic acids, carbohydrates, and fats, as do the major constituent inorganic compounds of animal shells, teeth, and bone. Most of the mass of living organisms is oxygen as a component of water, the major constituent of lifeforms. Oxygen is continuously replenished in Earth's atmosphere by photosynthesis, which uses the energy of sunlight to produce oxygen from water and carbon dioxide. Oxygen is too chemically reactive to remain a free element in air without being continuously replenished by the photosynthetic action of living organisms. Another form (allotrope) of oxygen, ozone (O
3), strongly absorbs ultraviolet UVB radiation and the high-altitude ozone layer helps protect the biosphere from ultraviolet radiation. However, ozone present at the surface is a byproduct of smog and thus a pollutant.
Oxygen was isolated by Michael Sendivogius before 1604, but it is commonly believed that the element was discovered independently by Carl Wilhelm Scheele, in Uppsala, in 1773 or earlier, and Joseph Priestley in Wiltshire, in 1774. Priority is often given for Priestley because his work was published first. Priestley, however, called oxygen "dephlogisticated air", and did not recognize it as a chemical element. The name oxygen was coined in 1777 by Antoine Lavoisier, who first recognized oxygen as a chemical element and correctly characterized the role it plays in combustion.
Common uses of oxygen include production of steel, plastics and textiles, brazing, welding and cutting of steels and other metals, rocket propellant, oxygen therapy, and life support systems in aircraft, submarines, spaceflight and diving.
History of study
One of the first known experiments on the relationship between combustion and air was conducted by the 2nd century BCE Greek writer on mechanics, Philo of Byzantium. In his work Pneumatica, Philo observed that inverting a vessel over a burning candle and surrounding the vessel's neck with water resulted in some water rising into the neck. Philo incorrectly surmised that parts of the air in the vessel were converted into the classical element fire and thus were able to escape through pores in the glass. Many centuries later Leonardo da Vinci built on Philo's work by observing that a portion of air is consumed during combustion and respiration.
In the late 17th century, Robert Boyle proved that air is necessary for combustion. English chemist John Mayow (1641–1679) refined this work by showing that fire requires only a part of air that he called spiritus nitroaereus. In one experiment, he found that placing either a mouse or a lit candle in a closed container over water caused the water to rise and replace one-fourteenth of the air's volume before extinguishing the subjects. From this, he surmised that nitroaereus is consumed in both respiration and combustion.
Mayow observed that antimony increased in weight when heated, and inferred that the nitroaereus must have combined with it. He also thought that the lungs separate nitroaereus from air and pass it into the blood and that animal heat and muscle movement result from the reaction of nitroaereus with certain substances in the body. Accounts of these and other experiments and ideas were published in 1668 in his work Tractatus duo in the tract "De respiratione".
Robert Hooke, Ole Borch, Mikhail Lomonosov, and Pierre Bayen all produced oxygen in experiments in the 17th and the 18th century but none of them recognized it as a chemical element. This may have been in part due to the prevalence of the philosophy of combustion and corrosion called the phlogiston theory, which was then the favored explanation of those processes.
Established in 1667 by the German alchemist J. J. Becher, and modified by the chemist Georg Ernst Stahl by 1731, phlogiston theory stated that all combustible materials were made of two parts. One part, called phlogiston, was given off when the substance containing it was burned, while the dephlogisticated part was thought to be its true form, or calx.
Highly combustible materials that leave little residue, such as wood or coal, were thought to be made mostly of phlogiston; non-combustible substances that corrode, such as iron, contained very little. Air did not play a role in phlogiston theory, nor were any initial quantitative experiments conducted to test the idea; instead, it was based on observations of what happens when something burns, that most common objects appear to become lighter and seem to lose something in the process.
Polish alchemist, philosopher, and physician Michael Sendivogius (Michał Sędziwój) in his work De Lapide Philosophorum Tractatus duodecim e naturae fonte et manuali experientia depromti (1604) described a substance contained in air, referring to it as 'cibus vitae' (food of life,) and according to Polish historian Roman Bugaj, this substance is identical with oxygen. Sendivogius, during his experiments performed between 1598 and 1604, properly recognized that the substance is equivalent to the gaseous byproduct released by the thermal decomposition of potassium nitrate. In Bugaj's view, the isolation of oxygen and the proper association of the substance to that part of air which is required for life, provides sufficient evidence for the discovery of oxygen by Sendivogius. This discovery of Sendivogius was however frequently denied by the generations of scientists and chemists which succeeded him.
It is also commonly claimed that oxygen was first discovered by Swedish pharmacist Carl Wilhelm Scheele. He had produced oxygen gas by heating mercuric oxide (HgO) and various nitrates in 1771–72. Scheele called the gas "fire air" because it was then the only known agent to support combustion. He wrote an account of this discovery in a manuscript titled Treatise on Air and Fire, which he sent to his publisher in 1775. That document was published in 1777.
In the meantime, on August 1, 1774, an experiment conducted by the British clergyman Joseph Priestley focused sunlight on mercuric oxide contained in a glass tube, which liberated a gas he named "dephlogisticated air". He noted that candles burned brighter in the gas and that a mouse was more active and lived longer while breathing it. After breathing the gas himself, Priestley wrote: "The feeling of it to my lungs was not sensibly different from that of common air, but I fancied that my breast felt peculiarly light and easy for some time afterwards." Priestley published his findings in 1775 in a paper titled "An Account of Further Discoveries in Air", which was included in the second volume of his book titled Experiments and Observations on Different Kinds of Air. Because he published his findings first, Priestley is usually given priority in the discovery.
The French chemist Antoine Laurent Lavoisier later claimed to have discovered the new substance independently. Priestley visited Lavoisier in October 1774 and told him about his experiment and how he liberated the new gas. Scheele had also dispatched a letter to Lavoisier on September 30, 1774, which described his discovery of the previously unknown substance, but Lavoisier never acknowledged receiving it. (A copy of the letter was found in Scheele's belongings after his death.)
Lavoisier conducted the first adequate quantitative experiments on oxidation and gave the first correct explanation of how combustion works. He used these and similar experiments, all started in 1774, to discredit the phlogiston theory and to prove that the substance discovered by Priestley and Scheele was a chemical element.
In one experiment, Lavoisier observed that there was no overall increase in weight when tin and air were heated in a closed container. He noted that air rushed in when he opened the container, which indicated that part of the trapped air had been consumed. He also noted that the tin had increased in weight and that increase was the same as the weight of the air that rushed back in. This and other experiments on combustion were documented in his book Sur la combustion en général, which was published in 1777. In that work, he proved that air is a mixture of two gases; 'vital air', which is essential to combustion and respiration, and azote (Gk. ἄζωτον "lifeless"), which did not support either. Azote later became nitrogen in English, although it has kept the earlier name in French and several other European languages.
Lavoisier renamed 'vital air' to oxygène in 1777 from the Greek roots ὀξύς (oxys) (acid, literally "sharp", from the taste of acids) and -γενής (-genēs) (producer, literally begetter), because he mistakenly believed that oxygen was a constituent of all acids. Chemists (such as Sir Humphry Davy in 1812) eventually determined that Lavoisier was wrong in this regard, but by then the name was too well established.
Oxygen entered the English language despite opposition by English scientists and the fact that the Englishman Priestley had first isolated the gas and written about it. This is partly due to a poem praising the gas titled "Oxygen" in the popular book The Botanic Garden (1791) by Erasmus Darwin, grandfather of Charles Darwin.
John Dalton's original atomic hypothesis presumed that all elements were monatomic and that the atoms in compounds would normally have the simplest atomic ratios with respect to one another. For example, Dalton assumed that water's formula was HO, leading to the conclusion that the atomic mass of oxygen was 8 times that of hydrogen, instead of the modern value of about 16. In 1805, Joseph Louis Gay-Lussac and Alexander von Humboldt showed that water is formed of two volumes of hydrogen and one volume of oxygen; and by 1811 Amedeo Avogadro had arrived at the correct interpretation of water's composition, based on what is now called Avogadro's law and the diatomic elemental molecules in those gases.[a]
By the late 19th century scientists realized that air could be liquefied and its components isolated by compressing and cooling it. Using a cascade method, Swiss chemist and physicist Raoul Pierre Pictet evaporated liquid sulfur dioxide in order to liquefy carbon dioxide, which in turn was evaporated to cool oxygen gas enough to liquefy it. He sent a telegram on December 22, 1877, to the French Academy of Sciences in Paris announcing his discovery of liquid oxygen. Just two days later, French physicist Louis Paul Cailletet announced his own method of liquefying molecular oxygen. Only a few drops of the liquid were produced in each case and no meaningful analysis could be conducted. Oxygen was liquefied in a stable state for the first time on March 29, 1883, by Polish scientists from Jagiellonian University, Zygmunt Wróblewski and Karol Olszewski.
In 1891 Scottish chemist James Dewar was able to produce enough liquid oxygen for study. The first commercially viable process for producing liquid oxygen was independently developed in 1895 by German engineer Carl von Linde and British engineer William Hampson. Both men lowered the temperature of air until it liquefied and then distilled the component gases by boiling them off one at a time and capturing them separately. Later, in 1901, oxyacetylene welding was demonstrated for the first time by burning a mixture of acetylene and compressed O
2. This method of welding and cutting metal later became common.
In 1923, the American scientist Robert H. Goddard became the first person to develop a rocket engine that burned liquid fuel; the engine used gasoline for fuel and liquid oxygen as the oxidizer. Goddard successfully flew a small liquid-fueled rocket 56 m at 97 km/h on March 16, 1926, in Auburn, Massachusetts, US.
In academic laboratories, oxygen can be prepared by heating together potassium chlorate mixed with a small proportion of manganese dioxide.
Oxygen levels in the atmosphere are trending slightly downward globally, possibly because of fossil-fuel burning.
Properties and molecular structure
As dioxygen, two oxygen atoms are chemically bound to each other. The bond can be variously described based on level of theory, but is reasonably and simply described as a covalent double bond that results from the filling of molecular orbitals formed from the atomic orbitals of the individual oxygen atoms, the filling of which results in a bond order of two. More specifically, the double bond is the result of sequential, low-to-high energy, or Aufbau, filling of orbitals, and the resulting cancellation of contributions from the 2s electrons, after sequential filling of the low σ and σ* orbitals; σ overlap of the two atomic 2p orbitals that lie along the O–O molecular axis and π overlap of two pairs of atomic 2p orbitals perpendicular to the O–O molecular axis, and then cancellation of contributions from the remaining two 2p electrons after their partial filling of the π* orbitals.
This combination of cancellations and σ and π overlaps results in dioxygen's double-bond character and reactivity, and a triplet electronic ground state. An electron configuration with two unpaired electrons, as is found in dioxygen orbitals (see the filled π* orbitals in the diagram) that are of equal energy—i.e., degenerate—is a configuration termed a spin triplet state. Hence, the ground state of the O
2 molecule is referred to as triplet oxygen.[b] The highest-energy, partially filled orbitals are antibonding, and so their filling weakens the bond order from three to two. Because of its unpaired electrons, triplet oxygen reacts only slowly with most organic molecules, which have paired electron spins; this prevents spontaneous combustion.
In the triplet form, O
2 molecules are paramagnetic. That is, they impart magnetic character to oxygen when it is in the presence of a magnetic field, because of the spin magnetic moments of the unpaired electrons in the molecule, and the negative exchange energy between neighboring O
2 molecules. Liquid oxygen is so magnetic that, in laboratory demonstrations, a bridge of liquid oxygen may be supported against its own weight between the poles of a powerful magnet.[c]
Singlet oxygen is a name given to several higher-energy species of molecular O
2 in which all the electron spins are paired. It is much more reactive with common organic molecules than is normal (triplet) molecular oxygen. In nature, singlet oxygen is commonly formed from water during photosynthesis, using the energy of sunlight. It is also produced in the troposphere by the photolysis of ozone by light of short wavelength and by the immune system as a source of active oxygen. Carotenoids in photosynthetic organisms (and possibly animals) play a major role in absorbing energy from singlet oxygen and converting it to the unexcited ground state before it can cause harm to tissues.
The common allotrope of elemental oxygen on Earth is called dioxygen, O
2, the major part of the Earth's atmospheric oxygen (see Occurrence). O2 has a bond length of 121 pm and a bond energy of 498 kJ/mol, which is smaller than the energy of other double bonds or pairs of single bonds in the biosphere and responsible for the exothermic reaction of O2 with any organic molecule. Due to its energy content, O2 is used by complex forms of life, such as animals, in cellular respiration. Other aspects of O
2 are covered in the remainder of this article.
3) is usually known as ozone and is a very reactive allotrope of oxygen that is damaging to lung tissue. Ozone is produced in the upper atmosphere when O
2 combines with atomic oxygen made by the splitting of O
2 by ultraviolet (UV) radiation. Since ozone absorbs strongly in the UV region of the spectrum, the ozone layer of the upper atmosphere functions as a protective radiation shield for the planet. Near the Earth's surface, it is a pollutant formed as a by-product of automobile exhaust. At low earth orbit altitudes, sufficient atomic oxygen is present to cause corrosion of spacecraft.
The metastable molecule tetraoxygen (O
4) was discovered in 2001, and was assumed to exist in one of the six phases of solid oxygen. It was proven in 2006 that this phase, created by pressurizing O
2 to 20 GPa, is in fact a rhombohedral O
8 cluster. This cluster has the potential to be a much more powerful oxidizer than either O
2 or O
3 and may therefore be used in rocket fuel. A metallic phase was discovered in 1990 when solid oxygen is subjected to a pressure of above 96 GPa and it was shown in 1998 that at very low temperatures, this phase becomes superconducting.
Oxygen dissolves more readily in water than in nitrogen, and in freshwater more readily than in seawater. Water in equilibrium with air contains approximately 1 molecule of dissolved O
2 for every 2 molecules of N
2 (1:2), compared with an atmospheric ratio of approximately 1:4. The solubility of oxygen in water is temperature-dependent, and about twice as much (14.6 mg/L) dissolves at 0 °C than at 20 °C (7.6 mg/L). At 25 °C and 1 standard atmosphere (101.3 kPa) of air, freshwater can dissolve about 6.04 milliliters (mL) of oxygen per liter, and seawater contains about 4.95 mL per liter. At 5 °C the solubility increases to 9.0 mL (50% more than at 25 °C) per liter for freshwater and 7.2 mL (45% more) per liter for sea water.
|5 °C||25 °C|
Oxygen condenses at 90.20 K (−182.95 °C, −297.31 °F) and freezes at 54.36 K (−218.79 °C, −361.82 °F). Both liquid and solid O
2 are clear substances with a light sky-blue color caused by absorption in the red (in contrast with the blue color of the sky, which is due to Rayleigh scattering of blue light). High-purity liquid O
2 is usually obtained by the fractional distillation of liquefied air. Liquid oxygen may also be condensed from air using liquid nitrogen as a coolant.
Liquid oxygen is a highly reactive substance and must be segregated from combustible materials.
The spectroscopy of molecular oxygen is associated with the atmospheric processes of aurora and airglow. The absorption in the Herzberg continuum and Schumann–Runge bands in the ultraviolet produces atomic oxygen that is important in the chemistry of the middle atmosphere. Excited-state singlet molecular oxygen is responsible for red chemiluminescence in solution.
Isotopes and stellar origin
Most 16O is synthesized at the end of the helium fusion process in massive stars but some is made in the neon burning process. 17O is primarily made by the burning of hydrogen into helium during the CNO cycle, making it a common isotope in the hydrogen burning zones of stars. Most 18O is produced when 14 (made abundant from CNO burning) captures a 4He nucleus, making 18O common in the helium-rich zones of evolved, massive stars.
Fourteen radioisotopes have been characterized. The most stable are 15O with a half-life of 122.24 seconds and 14O with a half-life of 70.606 seconds. All of the remaining radioactive isotopes have half-lives that are less than 27 s and the majority of these have half-lives that are less than 83 milliseconds. The most common decay mode of the isotopes lighter than 16O is β+ decay to yield nitrogen, and the most common mode for the isotopes heavier than 18O is beta decay to yield fluorine.
|Z||Element||Mass fraction in parts per million|
|1||Hydrogen||739,000||71 × mass of oxygen (red bar)|
|2||Helium||240,000||23 × mass of oxygen (red bar)|
Oxygen is the most abundant chemical element by mass in the Earth's biosphere, air, sea and land. Oxygen is the third most abundant chemical element in the universe, after hydrogen and helium. About 0.9% of the Sun's mass is oxygen. Oxygen constitutes 49.2% of the Earth's crust by mass as part of oxide compounds such as silicon dioxide and is the most abundant element by mass in the Earth's crust. It is also the major component of the world's oceans (88.8% by mass). Oxygen gas is the second most common component of the Earth's atmosphere, taking up 20.8% of its volume and 23.1% of its mass (some 1015 tonnes).[d] Earth is unusual among the planets of the Solar System in having such a high concentration of oxygen gas in its atmosphere: Mars (with 0.1% O
2 by volume) and Venus have much less. The O
2 surrounding those planets is produced solely by the action of ultraviolet radiation on oxygen-containing molecules such as carbon dioxide.
The unusually high concentration of oxygen gas on Earth is the result of the oxygen cycle. This biogeochemical cycle describes the movement of oxygen within and between its three main reservoirs on Earth: the atmosphere, the biosphere, and the lithosphere. The main driving factor of the oxygen cycle is photosynthesis, which is responsible for modern Earth's atmosphere. Photosynthesis releases oxygen into the atmosphere, while respiration, decay, and combustion remove it from the atmosphere. In the present equilibrium, production and consumption occur at the same rate.
Free oxygen also occurs in solution in the world's water bodies. The increased solubility of O
2 at lower temperatures (see Physical properties) has important implications for ocean life, as polar oceans support a much higher density of life due to their higher oxygen content. Water polluted with plant nutrients such as nitrates or phosphates may stimulate growth of algae by a process called eutrophication and the decay of these organisms and other biomaterials may reduce the O
2 content in eutrophic water bodies. Scientists assess this aspect of water quality by measuring the water's biochemical oxygen demand, or the amount of O
2 needed to restore it to a normal concentration.
Paleoclimatologists measure the ratio of oxygen-18 and oxygen-16 in the shells and skeletons of marine organisms to determine the climate millions of years ago (see oxygen isotope ratio cycle). Seawater molecules that contain the lighter isotope, oxygen-16, evaporate at a slightly faster rate than water molecules containing the 12% heavier oxygen-18, and this disparity increases at lower temperatures. During periods of lower global temperatures, snow and rain from that evaporated water tends to be higher in oxygen-16, and the seawater left behind tends to be higher in oxygen-18. Marine organisms then incorporate more oxygen-18 into their skeletons and shells than they would in a warmer climate. Paleoclimatologists also directly measure this ratio in the water molecules of ice core samples as old as hundreds of thousands of years.
Planetary geologists have measured the relative quantities of oxygen isotopes in samples from the Earth, the Moon, Mars, and meteorites, but were long unable to obtain reference values for the isotope ratios in the Sun, believed to be the same as those of the primordial solar nebula. Analysis of a silicon wafer exposed to the solar wind in space and returned by the crashed Genesis spacecraft has shown that the Sun has a higher proportion of oxygen-16 than does the Earth. The measurement implies that an unknown process depleted oxygen-16 from the Sun's disk of protoplanetary material prior to the coalescence of dust grains that formed the Earth.
Oxygen presents two spectrophotometric absorption bands peaking at the wavelengths 687 and 760 nm. Some remote sensing scientists have proposed using the measurement of the radiance coming from vegetation canopies in those bands to characterize plant health status from a satellite platform. This approach exploits the fact that in those bands it is possible to discriminate the vegetation's reflectance from its fluorescence, which is much weaker. The measurement is technically difficult owing to the low signal-to-noise ratio and the physical structure of vegetation; but it has been proposed as a possible method of monitoring the carbon cycle from satellites on a global scale.
Biological production and role of O2
Photosynthesis and respiration
In nature, free oxygen is produced by the light-driven splitting of water during oxygenic photosynthesis. According to some estimates, green algae and cyanobacteria in marine environments provide about 70% of the free oxygen produced on Earth, and the rest is produced by terrestrial plants. Other estimates of the oceanic contribution to atmospheric oxygen are higher, while some estimates are lower, suggesting oceans produce ~45% of Earth's atmospheric oxygen each year.
A simplified overall formula for photosynthesis is
- 6 CO2 + 6 H
2O + photons → C
6 + 6 O
Photolytic oxygen evolution occurs in the thylakoid membranes of photosynthetic organisms and requires the energy of four photons.[e] Many steps are involved, but the result is the formation of a proton gradient across the thylakoid membrane, which is used to synthesize adenosine triphosphate (ATP) via photophosphorylation. The O
2 remaining (after production of the water molecule) is released into the atmosphere.[f]
The chemical energy of oxygen is released in mitochondria to generate ATP during oxidative phosphorylation. The reaction for aerobic respiration is essentially the reverse of photosynthesis and is simplified as
6 + 6 O
2 → 6 CO2 + 6 H
2O + 2880 kJ/mol
In vertebrates, O
2 diffuses through membranes in the lungs and into red blood cells. Hemoglobin binds O
2, changing color from bluish red to bright red (CO
2 is released from another part of hemoglobin through the Bohr effect). Other animals use hemocyanin (molluscs and some arthropods) or hemerythrin (spiders and lobsters). A liter of blood can dissolve 200 cm3 of O
Reactive oxygen species, such as superoxide ion (O−
2) and hydrogen peroxide (H
2), are reactive by-products of oxygen use in organisms. Parts of the immune system of higher organisms create peroxide, superoxide, and singlet oxygen to destroy invading microbes. Reactive oxygen species also play an important role in the hypersensitive response of plants against pathogen attack. Oxygen is damaging to obligately anaerobic organisms, which were the dominant form of early life on Earth until O
2 began to accumulate in the atmosphere about 2.5 billion years ago during the Great Oxygenation Event, about a billion years after the first appearance of these organisms.
|Arterial blood oxygen||Venous blood gas|
The free oxygen partial pressure in the body of a living vertebrate organism is highest in the respiratory system, and decreases along any arterial system, peripheral tissues, and venous system, respectively. Partial pressure is the pressure that oxygen would have if it alone occupied the volume.
Build-up in the atmosphere
Free oxygen gas was almost nonexistent in Earth's atmosphere before photosynthetic archaea and bacteria evolved, probably about 3.5 billion years ago. Free oxygen first appeared in significant quantities during the Paleoproterozoic eon (between 3.0 and 2.3 billion years ago). Even if there was much dissolved iron in the oceans when oxygenic photosynthesis was getting more common, it appears the banded iron formations were created by anoxyenic or micro-aerophilic iron-oxidizing bacteria which dominated the deeper areas of the photic zone, while oxygen-producing cyanobacteria covered the shallows. Free oxygen began to outgas from the oceans 3–2.7 billion years ago, reaching 10% of its present level around 1.7 billion years ago.
The presence of large amounts of dissolved and free oxygen in the oceans and atmosphere may have driven most of the extant anaerobic organisms to extinction during the Great Oxygenation Event (oxygen catastrophe) about 2.4 billion years ago. Cellular respiration using O
2 enables aerobic organisms to produce much more ATP than anaerobic organisms. Cellular respiration of O
2 occurs in all eukaryotes, including all complex multicellular organisms such as plants and animals.
Since the beginning of the Cambrian period 540 million years ago, atmospheric O
2 levels have fluctuated between 15% and 30% by volume. Towards the end of the Carboniferous period (about 300 million years ago) atmospheric O
2 levels reached a maximum of 35% by volume, which may have contributed to the large size of insects and amphibians at this time.
Variations in atmospheric oxygen concentration have shaped past climates. When oxygen declined, atmospheric density dropped, which in turn increased surface evaporation, causing precipitation increases and warmer temperatures.
At the current rate of photosynthesis it would take about 2,000 years to regenerate the entire O
2 in the present atmosphere.
Extraterrestrial free oxygen
In the field of astrobiology and in the search for extraterrestrial life oxygen is a strong biosignature. That said it might not be a definite biosignature, being possibly produced abiotically on celestial bodies with processes and conditions (such as a peculiar hydrosphere) which allow free oxygen, like with Europa's and Ganymede's thin oxygen atmospheres.
One hundred million tonnes of O
2 are extracted from air for industrial uses annually by two primary methods. The most common method is fractional distillation of liquefied air, with N
2 distilling as a vapor while O
2 is left as a liquid.
The other primary method of producing O
2 is passing a stream of clean, dry air through one bed of a pair of identical zeolite molecular sieves, which absorbs the nitrogen and delivers a gas stream that is 90% to 93% O
2. Simultaneously, nitrogen gas is released from the other nitrogen-saturated zeolite bed, by reducing the chamber operating pressure and diverting part of the oxygen gas from the producer bed through it, in the reverse direction of flow. After a set cycle time the operation of the two beds is interchanged, thereby allowing for a continuous supply of gaseous oxygen to be pumped through a pipeline. This is known as pressure swing adsorption. Oxygen gas is increasingly obtained by these non-cryogenic technologies (see also the related vacuum swing adsorption).
Oxygen gas can also be produced through electrolysis of water into molecular oxygen and hydrogen. DC electricity must be used: if AC is used, the gases in each limb consist of hydrogen and oxygen in the explosive ratio 2:1. A similar method is the electrocatalytic O
2 evolution from oxides and oxoacids. Chemical catalysts can be used as well, such as in chemical oxygen generators or oxygen candles that are used as part of the life-support equipment on submarines, and are still part of standard equipment on commercial airliners in case of depressurization emergencies. Another air separation method is forcing air to dissolve through ceramic membranes based on zirconium dioxide by either high pressure or an electric current, to produce nearly pure O
Oxygen storage methods include high-pressure oxygen tanks, cryogenics and chemical compounds. For reasons of economy, oxygen is often transported in bulk as a liquid in specially insulated tankers, since one liter of liquefied oxygen is equivalent to 840 liters of gaseous oxygen at atmospheric pressure and 20 °C (68 °F). Such tankers are used to refill bulk liquid-oxygen storage containers, which stand outside hospitals and other institutions that need large volumes of pure oxygen gas. Liquid oxygen is passed through heat exchangers, which convert the cryogenic liquid into gas before it enters the building. Oxygen is also stored and shipped in smaller cylinders containing the compressed gas; a form that is useful in certain portable medical applications and oxy-fuel welding and cutting.
Uptake of O
2 from the air is the essential purpose of respiration, so oxygen supplementation is used in medicine. Treatment not only increases oxygen levels in the patient's blood, but has the secondary effect of decreasing resistance to blood flow in many types of diseased lungs, easing work load on the heart. Oxygen therapy is used to treat emphysema, pneumonia, some heart disorders (congestive heart failure), some disorders that cause increased pulmonary artery pressure, and any disease that impairs the body's ability to take up and use gaseous oxygen.
Treatments are flexible enough to be used in hospitals, the patient's home, or increasingly by portable devices. Oxygen tents were once commonly used in oxygen supplementation, but have since been replaced mostly by the use of oxygen masks or nasal cannulas.
Hyperbaric (high-pressure) medicine uses special oxygen chambers to increase the partial pressure of O
2 around the patient and, when needed, the medical staff. Carbon monoxide poisoning, gas gangrene, and decompression sickness (the 'bends') are sometimes addressed with this therapy. Increased O
2 concentration in the lungs helps to displace carbon monoxide from the heme group of hemoglobin. Oxygen gas is poisonous to the anaerobic bacteria that cause gas gangrene, so increasing its partial pressure helps kill them. Decompression sickness occurs in divers who decompress too quickly after a dive, resulting in bubbles of inert gas, mostly nitrogen and helium, forming in the blood. Increasing the pressure of O
2 as soon as possible helps to redissolve the bubbles back into the blood so that these excess gasses can be exhaled naturally through the lungs. Normobaric oxygen administration at the highest available concentration is frequently used as first aid for any diving injury that may involve inert gas bubble formation in the tissues. There is epidemiological support for its use from a statistical study of cases recorded in a long term database.
Life support and recreational use
An application of O
2 as a low-pressure breathing gas is in modern space suits, which surround their occupant's body with the breathing gas. These devices use nearly pure oxygen at about one-third normal pressure, resulting in a normal blood partial pressure of O
2. This trade-off of higher oxygen concentration for lower pressure is needed to maintain suit flexibility.
Scuba and surface-supplied underwater divers and submariners also rely on artificially delivered O
2. Submarines, submersibles and atmospheric diving suits usually operate at normal atmospheric pressure. Breathing air is scrubbed of carbon dioxide by chemical extraction and oxygen is replaced to maintain a constant partial pressure. Ambient pressure divers breathe air or gas mixtures with an oxygen fraction suited to the operating depth. Pure or nearly pure O
2 use in diving at pressures higher than atmospheric is usually limited to rebreathers, or decompression at relatively shallow depths (~6 meters depth, or less), or medical treatment in recompression chambers at pressures up to 2.8 bar, where acute oxygen toxicity can be managed without the risk of drowning. Deeper diving requires significant dilution of O
2 with other gases, such as nitrogen or helium, to prevent oxygen toxicity.
People who climb mountains or fly in non-pressurized fixed-wing aircraft sometimes have supplemental O
2 supplies.[h] Pressurized commercial airplanes have an emergency supply of O
2 automatically supplied to the passengers in case of cabin depressurization. Sudden cabin pressure loss activates chemical oxygen generators above each seat, causing oxygen masks to drop. Pulling on the masks "to start the flow of oxygen" as cabin safety instructions dictate, forces iron filings into the sodium chlorate inside the canister. A steady stream of oxygen gas is then produced by the exothermic reaction.
Oxygen, as a mild euphoric, has a history of recreational use in oxygen bars and in sports. Oxygen bars are establishments found in the United States since the late 1990s that offer higher than normal O
2 exposure for a minimal fee. Professional athletes, especially in American football, sometimes go off-field between plays to don oxygen masks to boost performance. The pharmacological effect is doubted; a placebo effect is a more likely explanation. Available studies support a performance boost from oxygen enriched mixtures only if it is inhaled during aerobic exercise.
Smelting of iron ore into steel consumes 55% of commercially produced oxygen. In this process, O
2 is injected through a high-pressure lance into molten iron, which removes sulfur impurities and excess carbon as the respective oxides, SO
2 and CO
2. The reactions are exothermic, so the temperature increases to 1,700 °C.
Another 25% of commercially produced oxygen is used by the chemical industry. Ethylene is reacted with O
2 to create ethylene oxide, which, in turn, is converted into ethylene glycol; the primary feeder material used to manufacture a host of products, including antifreeze and polyester polymers (the precursors of many plastics and fabrics). Large quantities of oxygen or air is used in oxy-cracking process and for the production of acrylic acid, diformyl-furane, and benzylic acid. On the other hand, the electrochemical synthesis of hydrogen peroxide from oxygen is a promising technology to replace the currently used hydroquinone-process. Last but not least, catalytic oxidation is used in afterburners to get rid of hazardous gases.
Most of the remaining 20% of commercially produced oxygen is used in medical applications, metal cutting and welding, as an oxidizer in rocket fuel, and in water treatment. Oxygen is used in oxyacetylene welding, burning acetylene with O
2 to produce a very hot flame. In this process, metal up to 60 cm (24 in) thick is first heated with a small oxy-acetylene flame and then quickly cut by a large stream of O
The oxidation state of oxygen is −2 in almost all known compounds of oxygen. The oxidation state −1 is found in a few compounds such as peroxides. Compounds containing oxygen in other oxidation states are very uncommon: −1/2 (superoxides), −1/3 (ozonides), 0 (elemental, hypofluorous acid), +1/2 (dioxygenyl), +1 (dioxygen difluoride), and +2 (oxygen difluoride).
Oxides and other inorganic compounds
2O) is an oxide of hydrogen and the most familiar oxygen compound. Hydrogen atoms are covalently bonded to oxygen in a water molecule but also have an additional attraction (about 23.3 kJ/mol per hydrogen atom) to an adjacent oxygen atom in a separate molecule. These hydrogen bonds between water molecules hold them approximately 15% closer than what would be expected in a simple liquid with just van der Waals forces.[i]
Due to its electronegativity, oxygen forms chemical bonds with almost all other elements to give corresponding oxides. The surface of most metals, such as aluminium and titanium, are oxidized in the presence of air and become coated with a thin film of oxide that passivates the metal and slows further corrosion. Many oxides of the transition metals are non-stoichiometric compounds, with slightly less metal than the chemical formula would show. For example, the mineral FeO (wüstite) is written as , where x is usually around 0.05.
Oxygen is present in the atmosphere in trace quantities in the form of carbon dioxide (CO
2). The Earth's crustal rock is composed in large part of oxides of silicon (silica SiO
2, as found in granite and quartz), aluminium (aluminium oxide Al
3, in bauxite and corundum), iron (iron(III) oxide Fe
3, in hematite and rust), and calcium carbonate (in limestone). The rest of the Earth's crust is also made of oxygen compounds, in particular various complex silicates (in silicate minerals). The Earth's mantle, of much larger mass than the crust, is largely composed of silicates of magnesium and iron.
Oxygen also acts as a ligand for transition metals, forming transition metal dioxygen complexes, which feature metal–O
2. This class of compounds includes the heme proteins hemoglobin and myoglobin. An exotic and unusual reaction occurs with PtF
6, which oxidizes oxygen to give O2+PtF6−, dioxygenyl hexafluoroplatinate.
Among the most important classes of organic compounds that contain oxygen are (where "R" is an organic group): alcohols (R-OH); ethers (R-O-R); ketones (R-CO-R); aldehydes (R-CO-H); carboxylic acids (R-COOH); esters (R-COO-R); acid anhydrides (R-CO-O-CO-R); and amides (R-C(O)-NR
2). There are many important organic solvents that contain oxygen, including: acetone, methanol, ethanol, isopropanol, furan, THF, diethyl ether, dioxane, ethyl acetate, DMF, DMSO, acetic acid, and formic acid. Acetone ((CH
2CO) and phenol (C
5OH) are used as feeder materials in the synthesis of many different substances. Other important organic compounds that contain oxygen are: glycerol, formaldehyde, glutaraldehyde, citric acid, acetic anhydride, and acetamide. Epoxides are ethers in which the oxygen atom is part of a ring of three atoms. The element is similarly found in almost all biomolecules that are important to (or generated by) life.
Oxygen reacts spontaneously with many organic compounds at or below room temperature in a process called autoxidation. Most of the organic compounds that contain oxygen are not made by direct action of O
2. Organic compounds important in industry and commerce that are made by direct oxidation of a precursor include ethylene oxide and peracetic acid.
Safety and precautions
The NFPA 704 standard rates compressed oxygen gas as nonhazardous to health, nonflammable and nonreactive, but an oxidizer. Refrigerated liquid oxygen (LOX) is given a health hazard rating of 3 (for increased risk of hyperoxia from condensed vapors, and for hazards common to cryogenic liquids such as frostbite), and all other ratings are the same as the compressed gas form.
Oxygen gas (O
2) can be toxic at elevated partial pressures, leading to convulsions and other health problems.[j] Oxygen toxicity usually begins to occur at partial pressures more than 50 kilopascals (kPa), equal to about 50% oxygen composition at standard pressure or 2.5 times the normal sea-level O
2 partial pressure of about 21 kPa. This is not a problem except for patients on mechanical ventilators, since gas supplied through oxygen masks in medical applications is typically composed of only 30–50% O
2 by volume (about 30 kPa at standard pressure).
At one time, premature babies were placed in incubators containing O
2-rich air, but this practice was discontinued after some babies were blinded by the oxygen content being too high.
Breathing pure O
2 in space applications, such as in some modern space suits, or in early spacecraft such as Apollo, causes no damage due to the low total pressures used. In the case of spacesuits, the O
2 partial pressure in the breathing gas is, in general, about 30 kPa (1.4 times normal), and the resulting O
2 partial pressure in the astronaut's arterial blood is only marginally more than normal sea-level O
2 partial pressure.
Oxygen toxicity to the lungs and central nervous system can also occur in deep scuba diving and surface supplied diving. Prolonged breathing of an air mixture with an O
2 partial pressure more than 60 kPa can eventually lead to permanent pulmonary fibrosis. Exposure to an O
2 partial pressures greater than 160 kPa (about 1.6 atm) may lead to convulsions (normally fatal for divers). Acute oxygen toxicity (causing seizures, its most feared effect for divers) can occur by breathing an air mixture with 21% O
2 at 66 m (217 ft) or more of depth; the same thing can occur by breathing 100% O
2 at only 6 m (20 ft).
Combustion and other hazards
Highly concentrated sources of oxygen promote rapid combustion. Fire and explosion hazards exist when concentrated oxidants and fuels are brought into close proximity; an ignition event, such as heat or a spark, is needed to trigger combustion. Oxygen is the oxidant, not the fuel, but nevertheless the source of most of the chemical energy released in combustion.
2 will allow combustion to proceed rapidly and energetically. Steel pipes and storage vessels used to store and transmit both gaseous and liquid oxygen will act as a fuel; and therefore the design and manufacture of O
2 systems requires special training to ensure that ignition sources are minimized. The fire that killed the Apollo 1 crew in a launch pad test spread so rapidly because the capsule was pressurized with pure O
2 but at slightly more than atmospheric pressure, instead of the1⁄3 normal pressure that would be used in a mission.[k]
- These results were mostly ignored until 1860. Part of this rejection was due to the belief that atoms of one element would have no chemical affinity towards atoms of the same element, and part was due to apparent exceptions to Avogadro's law that were not explained until later in terms of dissociating molecules.
- An orbital is a concept from quantum mechanics that models an electron as a wave-like particle that has a spatial distribution about an atom or molecule.
- Oxygen's paramagnetism can be used analytically in paramagnetic oxygen gas analysers that determine the purity of gaseous oxygen. ("Company literature of Oxygen analyzers (triplet)". Servomex. Archived from the original on March 8, 2008. Retrieved December 15, 2007.)
- Figures given are for values up to 80 km (50 mi) above the surface
- Thylakoid membranes are part of chloroplasts in algae and plants while they simply are one of many membrane structures in cyanobacteria. In fact, chloroplasts are thought to have evolved from cyanobacteria that were once symbiotic partners with the progenitors of plants and algae.
- Water oxidation is catalyzed by a manganese-containing enzyme complex known as the oxygen evolving complex (OEC) or water-splitting complex found associated with the lumenal side of thylakoid membranes. Manganese is an important cofactor, and calcium and chloride are also required for the reaction to occur. (Raven 2005)
- (1.8 grams/min/person)×(60 min/h)×(24 h/day)×(365 days/year)×(6.6 billion people)/1,000,000 g/t=6.24 billion tonnes
- The reason is that increasing the proportion of oxygen in the breathing gas at low pressure acts to augment the inspired O
2 partial pressure nearer to that found at sea-level.
- Also, since oxygen has a higher electronegativity than hydrogen, the charge difference makes it a polar molecule. The interactions between the different dipoles of each molecule cause a net attraction force.
- Since O
2's partial pressure is the fraction of O
2 times the total pressure, elevated partial pressures can occur either from high O
2 fraction in breathing gas or from high breathing gas pressure, or a combination of both.
- No single ignition source of the fire was conclusively identified, although some evidence points to an arc from an electrical spark.
- "Standard Atomic Weights: Oxygen". CIAAW. 2009.
- Weast, Robert (1984). CRC, Handbook of Chemistry and Physics. Boca Raton, Florida: Chemical Rubber Company Publishing. pp. E110. ISBN 0-8493-0464-4.
- Atkins, P.; Jones, L.; Laverman, L. (2016).Chemical Principles, 7th edition. Freeman.ISBN 978-1-4641-8395-9
- Weiss, H. M. (2008). "Appreciating Oxygen". J. Chem. Educ. 85 (9): 1218–19. Bibcode:2008JChEd..85.1218W. doi:10.1021/ed085p1218. Archived from the original on October 18, 2020. Retrieved March 13, 2017.
- Schmidt-Rohr, K. (2020). "Oxygen Is the High-Energy Molecule Powering Complex Multicellular Life: Fundamental Corrections to Traditional Bioenergetics” ACS Omega 5: 2221–33. http://dx.doi.org/10.1021/acsomega.9b03352
- Jastrow, Joseph (1936). Story of Human Error. Ayer Publishing. p. 171. ISBN 978-0-8369-0568-7. Archived from the original on October 1, 2021. Retrieved August 23, 2020.
- Cook & Lauer 1968, p. 499.
- Chisholm, Hugh, ed. (1911). Encyclopædia Britannica. Vol. 17 (11th ed.). Cambridge University Press. pp. 938–39..
- "John Mayow". World of Chemistry. Thomson Gale. 2005. ISBN 978-0-669-32727-4. Archived from the original on April 17, 2020. Retrieved December 16, 2007.
- Emsley 2001, p. 299
- Best, Nicholas W. (2015). "Lavoisier's 'Reflections on Phlogiston' I: Against Phlogiston Theory". Foundations of Chemistry. 17 (2): 137–51. doi:10.1007/s10698-015-9220-5. S2CID 170422925.
- Morris, Richard (2003). The last sorcerers: The path from alchemy to the periodic table. Washington, D.C.: Joseph Henry Press. ISBN 978-0-309-08905-0.
- Marples, Frater James A. "Michael Sendivogius, Rosicrucian, and Father of Studies of Oxygen" (PDF). Societas Rosicruciana in Civitatibus Foederatis, Nebraska College. pp. 3–4. Archived (PDF) from the original on May 8, 2020. Retrieved May 25, 2018.
- Bugaj, Roman (1971). "Michał Sędziwój – Traktat o Kamieniu Filozoficznym". Biblioteka Problemów (in Polish). 164: 83–84. ISSN 0137-5032. Archived from the original on October 1, 2021. Retrieved August 23, 2020.
- "Oxygen". RSC.org. Archived from the original on January 28, 2017. Retrieved December 12, 2016.
- Cook & Lauer 1968, p. 500
- Emsley 2001, p. 300
- Priestley, Joseph (1775). "An Account of Further Discoveries in Air". Philosophical Transactions. 65: 384–94. doi:10.1098/rstl.1775.0039.
- Parks, G. D.; Mellor, J. W. (1939). Mellor's Modern Inorganic Chemistry (6th ed.). London: Longmans, Green and Co.
- Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Butterworth-Heinemann. p. 793. ISBN 978-0-08-037941-8.
- DeTurck, Dennis; Gladney, Larry; Pietrovito, Anthony (1997). "Do We Take Atoms for Granted?". The Interactive Textbook of PFP96. University of Pennsylvania. Archived from the original on January 17, 2008. Retrieved January 28, 2008.
- Roscoe, Henry Enfield; Schorlemmer, Carl (1883). A Treatise on Chemistry. D. Appleton and Co. p. 38.
- Daintith, John (1994). Biographical Encyclopedia of Scientists. CRC Press. p. 707. ISBN 978-0-7503-0287-6.
- Papanelopoulou, Faidra (2013). "Louis Paul Cailletet: The liquefaction of oxygen and the emergence of low-temperature research". Notes and Records of the Royal Society of London. 67 (4): 355–73. doi:10.1098/rsnr.2013.0047. PMC 3826198.
- Emsley 2001, p. 303
- "Oxygen". How Products are Made. The Gale Group, Inc. 2002. Archived from the original on April 3, 2019. Retrieved December 16, 2007.
- "Goddard-1926". NASA. Archived from the original on November 8, 2007. Retrieved November 18, 2007.
- Flecker, Oriel Joyce (1924). A school chemistry. MIT Libraries. Oxford, Clarendon press. p. 30.
- Scripps Institute. "Atmospheric Oxygen Research". Archived from the original on July 25, 2017. Retrieved October 8, 2011.
- Jack Barrett, 2002, "Atomic Structure and Periodicity", (Basic concepts in chemistry, Vol. 9 of Tutorial chemistry texts), Cambridge, UK: Royal Society of Chemistry, p. 153,ISBN 0854046577. See Google Books. Archived May 30, 2020, at the Wayback Machine accessed January 31, 2015.
- "Oxygen Facts". Science Kids. February 6, 2015. Archived from the original on May 7, 2020. Retrieved November 14, 2015.
- Jakubowski, Henry. "Chapter 8: Oxidation-Phosphorylation, the Chemistry of Di-Oxygen". Biochemistry Online. Saint John's University. Archived from the original on October 5, 2018. Retrieved January 28, 2008.
- "Demonstration of a bridge of liquid oxygen supported against its own weight between the poles of a powerful magnet". University of Wisconsin-Madison Chemistry Department Demonstration lab. Archived from the original on December 17, 2007. Retrieved December 15, 2007.
- Krieger-Liszkay, Anja (October 13, 2004). "Singlet oxygen production in photosynthesis". Journal of Experimental Botany. 56 (411): 337–346. doi:10.1093/jxb/erh237. PMID 15310815.
- Harrison, Roy M. (1990). Pollution: Causes, Effects & Control (2nd ed.). Cambridge: Royal Society of Chemistry. ISBN 978-0-85186-283-5.
- Wentworth, Paul; McDunn, J. E.; Wentworth, A. D.; Takeuchi, C.; Nieva, J.; Jones, T.; Bautista, C.; Ruedi, J. M.; Gutierrez, A.; Janda, K. D.; Babior, B. M.; Eschenmoser, A.; Lerner, R. A. (December 13, 2002). "Evidence for Antibody-Catalyzed Ozone Formation in Bacterial Killing and Inflammation". Science. 298 (5601): 2195–2219. Bibcode:2002Sci...298.2195W. doi:10.1126/science.1077642. PMID 12434011. S2CID 36537588. Archived from the original on December 12, 2020. Retrieved December 6, 2019.
- Hirayama, Osamu; Nakamura, Kyoko; Hamada, Syoko; Kobayasi, Yoko (1994). "Singlet oxygen quenching ability of naturally occurring carotenoids". Lipids. 29 (2): 149–150. doi:10.1007/BF02537155. PMID 8152349. S2CID 3965039.
- Chieh, Chung. "Bond Lengths and Energies". University of Waterloo. Archived from the original on December 14, 2007. Retrieved December 16, 2007.
- Schmidt-Rohr, K. (2015). "Why Combustions Are Always Exothermic, Yielding About 418 kJ per Mole of O2". J. Chem. Educ. 92 (12): 2094–99. Bibcode:2015JChEd..92.2094S. doi:10.1021/acs.jchemed.5b00333.
- Stwertka, Albert (1998). Guide to the Elements (Revised ed.). Oxford University Press. pp. 48–49. ISBN 978-0-19-508083-4.
- "Atomic oxygen erosion". Archived from the original on June 13, 2007. Retrieved August 8, 2009.
- Cacace, Fulvio; de Petris, Giulia; Troiani, Anna (2001). "Experimental Detection of Tetraoxygen". Angewandte Chemie International Edition. 40 (21): 4062–65. doi:10.1002/1521-3773(20011105)40:21<4062::AID-ANIE4062>3.0.CO;2-X. PMID 12404493.
- Ball, Phillip (September 16, 2001). "New form of oxygen found". Nature News. Archived from the original on October 21, 2013. Retrieved January 9, 2008.
- Lundegaard, Lars F.; Weck, Gunnar; McMahon, Malcolm I.; Desgreniers, Serge; et al. (2006). "Observation of anO
8 molecular lattice in the phase of solid oxygen". Nature. 443 (7108): 201–04. Bibcode:2006Natur.443..201L. doi:10.1038/nature05174. PMID 16971946. S2CID 4384225.
- Desgreniers, S.; Vohra, Y. K.; Ruoff, A. L. (1990). "Optical response of very high density solid oxygen to 132 GPa". J. Phys. Chem. 94 (3): 1117–22. doi:10.1021/j100366a020.
- Shimizu, K.; Suhara, K.; Ikumo, M.; Eremets, M. I.; et al. (1998). "Superconductivity in oxygen". Nature. 393 (6687): 767–69. Bibcode:1998Natur.393..767S. doi:10.1038/31656. S2CID 205001394.
- "Air solubility in water". The Engineering Toolbox. Archived from the original on April 4, 2019. Retrieved December 21, 2007.
- Evans, David Hudson; Claiborne, James B. (2005). The Physiology of Fishes (3rd ed.). CRC Press. p. 88. ISBN 978-0-8493-2022-4.
- Lide, David R. (2003). "Section 4, Properties of the Elements and Inorganic Compounds; Melting, boiling, and critical temperatures of the elements". CRC Handbook of Chemistry and Physics (84th ed.). Boca Raton, Florida: CRC Press. ISBN 978-0-8493-0595-5.
- "Overview of Cryogenic Air Separation and Liquefier Systems". Universal Industrial Gases, Inc. Archived from the original on October 21, 2018. Retrieved December 15, 2007.
- "Liquid Oxygen Material Safety Data Sheet" (PDF). Matheson Tri Gas. Archived from the original (PDF) on February 27, 2008. Retrieved December 15, 2007.
- Krupenie, Paul H. (1972). "The Spectrum of Molecular Oxygen". Journal of Physical and Chemical Reference Data. 1 (2): 423–534. Bibcode:1972JPCRD...1..423K. doi:10.1063/1.3253101. S2CID 96242703. Archived from the original on October 1, 2021. Retrieved January 11, 2020.
- Guy P. Brasseur; Susan Solomon (January 15, 2006). Aeronomy of the Middle Atmosphere: Chemistry and Physics of the Stratosphere and Mesosphere. Springer Science & Business Media. pp. 220–. ISBN 978-1-4020-3824-2. Archived from the original on February 2, 2017. Retrieved July 2, 2015.
- Kearns, David R. (1971). "Physical and chemical properties of singlet molecular oxygen". Chemical Reviews. 71 (4): 395–427. doi:10.1021/cr60272a004.
- "Oxygen Nuclides / Isotopes". EnvironmentalChemistry.com. Archived from the original on August 18, 2020. Retrieved December 17, 2007.
- Meyer, B. S. (September 19–21, 2005). Nucleosynthesis and Galactic Chemical Evolution of the Isotopes of Oxygen (PDF). Workgroup on Oxygen in the Earliest Solar System. Proceedings of the NASA Cosmochemistry Program and the Lunar and Planetary Institute. Gatlinburg, Tennessee. 9022. Archived (PDF) from the original on December 29, 2010. Retrieved January 22, 2007.
- "NUDAT 13O". Archived from the original on July 28, 2012. Retrieved July 6, 2009.
- "NUDAT 14O". Archived from the original on July 28, 2012. Retrieved July 6, 2009.
- "NUDAT 15O". Archived from the original on July 28, 2012. Retrieved July 6, 2009.
- Croswell, Ken (1996). Alchemy of the Heavens. Anchor. ISBN 978-0-385-47214-2. Archived from the original on May 13, 2011. Retrieved December 2, 2011.
- Emsley 2001, p. 297
- "Oxygen". Los Alamos National Laboratory. Archived from the original on October 26, 2007. Retrieved December 16, 2007.
- Emsley 2001, p. 298
- Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Butterworth-Heinemann. p. 602. ISBN 978-0-08-037941-8.
- From The Chemistry and Fertility of Sea Waters by H.W. Harvey, 1955, citing C.J.J. Fox, "On the coefficients of absorption of atmospheric gases in sea water", Publ. Circ. Cons. Explor. Mer, no. 41, 1907. Harvey notes that according to later articles in Nature, the values appear to be about 3% too high.
- Emsley 2001, p. 301
- Emsley 2001, p. 304
- Hand, Eric (March 13, 2008). "The Solar System's first breath". Nature. 452 (7185): 259. Bibcode:2008Natur.452..259H. doi:10.1038/452259a. PMID 18354437. S2CID 789382.
- Miller, J. R.; Berger, M.; Alonso, L.; Cerovic, Z.; et al. Progress on the development of an integrated canopy fluorescence model. Geoscience and Remote Sensing Symposium, 2003. IGARSS '03. Proceedings. 2003 IEEE International. CiteSeerX 10.1.1.473.9500. doi:10.1109/IGARSS.2003.1293855.
- Fenical, William (September 1983). "Marine Plants: A Unique and Unexplored Resource". Plants: the potentials for extracting protein, medicines, and other useful chemicals (workshop proceedings). DianePublishing. p. 147. ISBN 978-1-4289-2397-3. Archived from the original on March 25, 2015. Retrieved August 23, 2020.
- Walker, J. C. G. (1980). The oxygen cycle in the natural environment and the biogeochemical cycles. Berlin: Springer-Verlag.
- Brown, Theodore L.; LeMay, Burslen (2003). Chemistry: The Central Science. Prentice Hall/Pearson Education. p. 958. ISBN 978-0-13-048450-5.
- Raven 2005, 115–27
- Danovaro R; Dell'anno A; Pusceddu A; Gambi C; et al. (April 2010). "The first metazoa living in permanently anoxic conditions". BMC Biology. 8 (1): 30. doi:10.1186/1741-7007-8-30. PMC 2907586. PMID 20370908.
- Ward, Peter D.; Brownlee, Donald (2000). Rare Earth: Why Complex Life is Uncommon in the Universe. Copernicus Books (Springer Verlag). p. 217. ISBN 978-0-387-98701-9.
- "NASA Research Indicates Oxygen on Earth 2.5 Billion Years ago" (Press release). NASA. September 27, 2007. Archived from the original on March 13, 2008. Retrieved March 13, 2008.
- Zimmer, Carl (October 3, 2013). "Earth's Oxygen: A Mystery Easy to Take for Granted". The New York Times. Archived from the original on May 16, 2020. Retrieved October 3, 2013.
- "Flow restrictor for measuring respiratory parameters". Archived from the original on May 8, 2020. Retrieved August 4, 2019.
- Derived from mmHg values using 0.133322 kPa/mmHg
- Normal Reference Range Table Archived December 25, 2011, at the Wayback Machine from The University of Texas Southwestern Medical Center at Dallas. Used in Interactive Case Study Companion to Pathologic basis of disease.
- The Medical Education Division of the Brookside Associates--> ABG (Arterial Blood Gas) Archived August 12, 2017, at the Wayback Machine Retrieved on December 6, 2009
- Charles Henrickson (2005). Chemistry. Cliffs Notes. ISBN 978-0-7645-7419-1.
- Crowe, S. A.; Døssing, L. N.; Beukes, N. J.; Bau, M.; Kruger, S. J.; Frei, R.; Canfield, D. E. (2013). "Atmospheric oxygenation three billion years ago". Nature. 501 (7468): 535–38. Bibcode:2013Natur.501..535C. doi:10.1038/nature12426. PMID 24067713. S2CID 4464710.
- Iron in primeval seas rusted by bacteria Archived March 11, 2020, at the Wayback Machine, ScienceDaily, April 23, 2013
- Campbell, Neil A.; Reece, Jane B. (2005). Biology (7th ed.). San Francisco: Pearson – Benjamin Cummings. pp. 522–23. ISBN 978-0-8053-7171-0.
- Freeman, Scott (2005). Biological Science, 2nd. Upper Saddle River, NJ: Pearson – Prentice Hall. pp. 214, 586. ISBN 978-0-13-140941-5.
- Berner, Robert A. (1999). "Atmospheric oxygen over Phanerozoic time". Proceedings of the National Academy of Sciences of the USA. 96 (20): 10955–57. Bibcode:1999PNAS...9610955B. doi:10.1073/pnas.96.20.10955. PMC 34224. PMID 10500106.
- Butterfield, N. J. (2009). "Oxygen, animals and oceanic ventilation: An alternative view". Geobiology. 7 (1): 1–7. doi:10.1111/j.1472-4669.2009.00188.x. PMID 19200141.
- Poulsen, Christopher J.; Tabor, Clay; White, Joseph D. (2015). "Long-term climate forcing by atmospheric oxygen concentrations". Science. 348 (6240): 1238–41. Bibcode:2015Sci...348.1238P. doi:10.1126/science.1260670. PMID 26068848. S2CID 206562386. Archived from the original on July 13, 2017. Retrieved June 12, 2015.
- Dole, Malcolm (1965). "The Natural History of Oxygen". The Journal of General Physiology. 49 (1): 5–27. doi:10.1085/jgp.49.1.5. PMC 2195461. PMID 5859927.
- Paul Scott Anderson (January 3, 2019). "Oxygen and life: a cautionary tale". Archived from the original on January 22, 2021. Retrieved December 29, 2020.
- Luger R, Barnes R (February 2015). "Extreme water loss and abiotic O2 buildup on planets throughout the habitable zones of M dwarfs". Astrobiology. 15 (2): 119–43. arXiv:1411.7412. Bibcode:2015AsBio..15..119L. doi:10.1089/ast.2014.1231. PMC 4323125. PMID 25629240.
- Wordsworth, Robin; Pierrehumbert, Raymond (April 1, 2014). "Abiotic oxygen-dominated atmospheres on terrestrial habitable zone planets". The Astrophysical Journal. 785 (2): L20. arXiv:1403.2713. Bibcode:2014ApJ...785L..20W. doi:10.1088/2041-8205/785/2/L20. S2CID 17414970.
- Hall, D.T.; Feldman, P.D.; et al. (1998). "The Far-Ultraviolet Oxygen Airglow of Europa and Ganymede". The Astrophysical Journal. 499 (1): 475–81. Bibcode:1998ApJ...499..475H. doi:10.1086/305604.
- "Non-Cryogenic Air Separation Processes". UIG Inc. 2003. Archived from the original on October 3, 2018. Retrieved December 16, 2007.
- Cook & Lauer 1968, p. 510
- Sim MA; Dean P; Kinsella J; Black R; et al. (2008). "Performance of oxygen delivery devices when the breathing pattern of respiratory failure is simulated". Anaesthesia. 63 (9): 938–40. doi:10.1111/j.1365-2044.2008.05536.x. PMID 18540928. S2CID 205248111.
- Stephenson RN; Mackenzie I; Watt SJ; Ross JA (1996). "Measurement of oxygen concentration in delivery systems used for hyperbaric oxygen therapy". Undersea Hyperb Med. 23 (3): 185–88. PMID 8931286. Archived from the original on August 11, 2011. Retrieved September 22, 2008.
- Undersea and Hyperbaric Medical Society. "Indications for hyperbaric oxygen therapy". Archived from the original on September 12, 2008. Retrieved September 22, 2008.
- Undersea and Hyperbaric Medical Society. "Carbon Monoxide". Archived from the original on July 25, 2008. Retrieved September 22, 2008.
- Piantadosi CA (2004). "Carbon monoxide poisoning". Undersea Hyperb Med. 31 (1): 167–77. PMID 15233173. Archived from the original on February 3, 2011. Retrieved September 22, 2008.
- Hart GB; Strauss MB (1990). "Gas Gangrene – Clostridial Myonecrosis: A Review". J. Hyperbaric Med. 5 (2): 125–44. Archived from the original on February 3, 2011. Retrieved September 22, 2008.
- Zamboni WA; Riseman JA; Kucan JO (1990). "Management of Fournier's Gangrene and the role of Hyperbaric Oxygen". J. Hyperbaric Med. 5 (3): 177–86. Archived from the original on February 3, 2011. Retrieved September 22, 2008.
- Undersea and Hyperbaric Medical Society. "Decompression Sickness or Illness and Arterial Gas Embolism". Archived from the original on July 5, 2008. Retrieved September 22, 2008.
- Acott, C. (1999). "A brief history of diving and decompression illness". South Pacific Underwater Medicine Society Journal. 29 (2). Archived from the original on September 5, 2011. Retrieved September 22, 2008.
- Longphre, JM; Denoble, PJ; Moon, RE; Vann, RD; Freiberger, JJ (2007). "First aid normobaric oxygen for the treatment of recreational diving injuries" (PDF). Undersea & Hyperbaric Medicine. 34 (1): 43–49. PMID 17393938. S2CID 3236557. Archived from the original (PDF) on October 1, 2018 – via Rubicon Research Repository.
- "Emergency Oxygen for Scuba Diving Injuries". Divers Alert Network. Archived from the original on April 20, 2020. Retrieved October 1, 2018.
- "Oxygen First Aid for Scuba Diving Injuries". Divers Alert Network Europe. Archived from the original on June 10, 2020. Retrieved October 1, 2018.
- Morgenthaler GW; Fester DA; Cooley CG (1994). "As assessment of habitat pressure, oxygen fraction, and EVA suit design for space operations". Acta Astronautica. 32 (1): 39–49. Bibcode:1994AcAau..32...39M. doi:10.1016/0094-5765(94)90146-5. PMID 11541018.
- Webb JT; Olson RM; Krutz RW; Dixon G; Barnicott PT (1989). "Human tolerance to 100% oxygen at 9.5 psia during five daily simulated 8-hour EVA exposures". Aviat Space Environ Med. 60 (5): 415–21. doi:10.4271/881071. PMID 2730484.
- Acott, C. (1999). "Oxygen toxicity: A brief history of oxygen in diving". South Pacific Underwater Medicine Society Journal. 29 (3). Archived from the original on December 25, 2010. Retrieved September 21, 2008.
- Longphre, J. M.; Denoble, P. J.; Moon, R. E.; Vann, R. D.; et al. (2007). "First aid normobaric oxygen for the treatment of recreational diving injuries". Undersea Hyperb. Med. 34 (1): 43–49. PMID 17393938. Archived from the original on June 13, 2008. Retrieved September 21, 2008.
- Bren, Linda (November–December 2002). "Oxygen Bars: Is a Breath of Fresh Air Worth It?". FDA Consumer Magazine. U.S. Food and Drug Administration. 36 (6): 9–11. PMID 12523293. Archived from the original on October 18, 2007. Retrieved December 23, 2007.
- "Ergogenic Aids". Peak Performance Online. Archived from the original on September 28, 2007. Retrieved January 4, 2008.
- "George Goble's extended home page (mirror)". Archived from the original on February 11, 2009. Retrieved March 14, 2008.
- Guseinova, E. A.; Adzhamov, K. Yu.; Safarova, S. R. (April 1, 2020). "Kinetic parameters of the formation of oxygen-containing compounds in the vacuum gas oil oxycracking process". Reaction Kinetics, Mechanisms and Catalysis. 129 (2): 925–39. doi:10.1007/s11144-020-01725-8. ISSN 1878-5204. S2CID 211074899.
- Hävecker, Michael; Wrabetz, Sabine; Kröhnert, Jutta; Csepei, Lenard-Istvan; Naumann d'Alnoncourt, Raoul; Kolen'Ko, Yury V.; Girgsdies, Frank; Schlögl, Robert; Trunschke, Annette (2012). "Surface chemistry of phase-pure M1 MoVTeNb oxide during operation in selective oxidation of propane to acrylic acid". J. Catal. 285: 48–60. doi:10.1016/j.jcat.2011.09.012. hdl:11858/00-001M-0000-0012-1BEB-F. Archived from the original on July 13, 2020. Retrieved July 25, 2020.
- Rodikova, Yulia; Zhizhina, Elena (June 1, 2020). "Catalytic oxidation of 5-hydroxymethylfurfural into 2,5-diformylfuran using V-containing heteropoly acid catalysts". Reaction Kinetics, Mechanisms and Catalysis. 130 (1): 403–15. doi:10.1007/s11144-020-01782-z. ISSN 1878-5204. S2CID 218512746.
- Amakawa, Kazuhiko; Kolen'Ko, Yury V.; Villa, Alberto; Schuster, Manfred E/; Csepei, Lénárd-István; Weinberg, Gisela; Wrabetz, Sabine; Naumann d'Alnoncourt, Raoul; Girgsdies, Frank; Prati, Laura; Schlögl, Robert; Trunschke, Annette (2013). "Multifunctionality of Crystalline MoV(TeNb) M1 Oxide Catalysts in Selective Oxidation of Propane and Benzyl Alcohol". ACS Catal. 3 (6): 1103–13. doi:10.1021/cs400010q. Archived from the original on October 22, 2018. Retrieved July 25, 2020.
- Elizalde-Martínez, I.; Ramírez-López, R.; Mederos-Nieto, F. S.; Monterrubio-Badillo, M. C.; Vázquez Medina, R.; Manríquez-Ramírez, M. E. (October 1, 2019). "Optimization of O2/CH4 to oxide methane at 823 K by alumina-ceria supported Pt catalysts". Reaction Kinetics, Mechanisms and Catalysis. 128 (1): 149–61. doi:10.1007/s11144-019-01641-6. ISSN 1878-5204. S2CID 199652341.
- Todorova, Silviya; Barbov, Borislav; Todorova, Totka; Kolev, Hristo; Ivanova, Ivanka; Shopska, Maya; Kalvachev, Yuri (April 1, 2020). "CO oxidation over Pt-modified fly ash zeolite X". Reaction Kinetics, Mechanisms and Catalysis. 129 (2): 773–86. doi:10.1007/s11144-020-01730-x. ISSN 1878-5204. S2CID 210986130.
- Cook & Lauer 1968, p. 508
- Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Butterworth-Heinemann. ISBN 978-0-08-037941-8., p. 28
- IUPAC: Red Book. Archived July 9, 2018, at the Wayback Machine pp. 73, 320.
- Maksyutenko, P.; Rizzo, T. R.; Boyarkin, O. V. (2006). "A direct measurement of the dissociation energy of water". J. Chem. Phys. 125 (18): 181101. Bibcode:2006JChPh.125r1101M. doi:10.1063/1.2387163. PMID 17115729.
- Chaplin, Martin (January 4, 2008). "Water Hydrogen Bonding". Archived from the original on October 10, 2007. Retrieved January 6, 2008.
- Smart, Lesley E.; Moore, Elaine A. (2005). Solid State Chemistry: An Introduction (3rd ed.). CRC Press. p. 214. ISBN 978-0-7487-7516-3.
- Cook & Lauer 1968, p. 507
- Crabtree, R. (2001). The Organometallic Chemistry of the Transition Metals (3rd ed.). John Wiley & Sons. p. 152. ISBN 978-0-471-18423-2.
- Cook & Lauer 1968, p.505
- Cook & Lauer 1968, p. 506
- "NFPA 704 ratings and id numbers for common hazardous materials" (PDF). Riverside County Department of Environmental Health. Archived (PDF) from the original on July 11, 2019. Retrieved August 22, 2017.
- Dharmeshkumar N Patel; Ashish Goel; SB Agarwal; Praveenkumar Garg; et al. (2003). "Oxygen Toxicity" (PDF). Indian Academy of Clinical Medicine. 4 (3): 234. Archived from the original (PDF) on September 22, 2015. Retrieved April 26, 2009.
- Cook & Lauer 1968, p. 511
- Wade, Mark (2007). "Space Suits". Encyclopedia Astronautica. Archived from the original on December 13, 2007. Retrieved December 16, 2007.
- Martin, Lawrence. "The Four Most Important Equations In Clinical Practice". GlobalRPh. David McAuley. Archived from the original on September 5, 2018. Retrieved June 19, 2013.
- Wilmshurst P (1998). "Diving and oxygen". BMJ. 317 (7164): 996–99. doi:10.1136/bmj.317.7164.996. PMC 1114047. PMID 9765173.
- Donald, Kenneth (1992). Oxygen and the Diver. England: SPA in conjunction with K. Donald. ISBN 978-1-85421-176-7.
- Donald K. W. (1947). "Oxygen Poisoning in Man: Part I". Br Med J. 1 (4506): 667–72. doi:10.1136/bmj.1.4506.667. PMC 2053251. PMID 20248086.
- Donald K. W. (1947). "Oxygen Poisoning in Man: Part II". Br Med J. 1 (4507): 712–17. doi:10.1136/bmj.1.4507.712. PMC 2053400. PMID 20248096.
- Werley, Barry L., ed. (1991). ASTM Technical Professional training. Fire Hazards in Oxygen Systems. Philadelphia: ASTM International Subcommittee G-4.05.
- Report of Apollo 204 Review Board NASA Historical Reference Collection, NASA History Office, NASA HQ, Washington, DC
- Chiles, James R. (2001). Inviting Disaster: Lessons from the edge of Technology: An inside look at catastrophes and why they happen. New York: HarperCollins Publishers Inc. ISBN 978-0-06-662082-4.
- Cook, Gerhard A.; Lauer, Carol M. (1968). "Oxygen". In Clifford A. Hampel (ed.). The Encyclopedia of the Chemical Elements. New York: Reinhold Book Corporation. pp. 499–512. LCCN 68-29938.
- Emsley, John (2001). "Oxygen". Nature's Building Blocks: An A–Z Guide to the Elements. Oxford, England: Oxford University Press. pp. 297–304. ISBN 978-0-19-850340-8.
- Raven, Peter H.; Evert, Ray F.; Eichhorn, Susan E. (2005). Biology of Plants (7th ed.). New York: W. H. Freeman and Company Publishers. pp. 115–27. ISBN 978-0-7167-1007-3.
Media files used on this page
Oxygen and MAPP gas compresed gas cylinders with regulators. The high pressure side of the oxygen regulator reads 1,000 PSI (69 bar). The tremendous pressure inside the oxygen cylinder (over 2,200 PSI (152 bar) in a full tank) requires extrusion as a manufacturing process and these tanks may never be welded. The lower pressure MAPP cylinder was welded together and the seam is visible where the yellow and white paint meet.
Author/Creator: The original uploader was GiollaUidir at English Wikipedia., Licence: CC BY-SA 2.0 uk
A picture I took on 2nd of July, 2007 showing a home en:oxygen concentrator. As stated in the license attribution for the picture must be given to me, Patrick McAleer for use outside of Wikipedia.
Author/Creator: Askeuhd, Licence: CC BY-SA 4.0
STS057-89-67 - Against the blackness of space, Mission Specialist Peter J.K. Wisoff, wearing an extravehicular mobility unit, stands on a Portable Foot Restraint (PFR), Manipulator Foot Restraint (MFR) attached to the End Effector of the Remote Manipulator System (RMS), colloquially known as the "robot arm". Wisoff is being maneuvered above the payload bay of Endeavour as part of Detailed Test Objective (DTO) extravehicular activity procedures. DTO results will assist in refining several procedures being developed to service the Hubble Space Telescope on mission STS-61 in December 1993. The Earth's surface and the Endeavour payload bay are reflected in Wisoff's helmet visor.
Officially designated Apollo/Saturn 204, but more commonly known as Apollo 1, this close-up view of the interior of the Command Module shows the effects of the intense heat of the flash fire which killed the prime crew during a routine training exercise. While strapped into their seats inside the Command Module atop the giant Saturn rocket, a wire bundle that was worn due to misplacement and a sharp-edged access door, sparked and ignited flammable material. This quickly grew into a large fire in the pure oxygen environment. The speed and intensity of the fire quickly exhausted the oxygen supply inside the crew cabin. Unable to deploy the hatch due to its cumbersome design and lack of breathable oxygen, the crew lost consciousness and perished. They were: astronauts Virgil I. "Gus" Grissom, (the second American to fly into space) Edward H. White II, (the first American to "walk" in space) and Roger B. Chaffee, (a "rookie" on his first space mission).
Dr. Robert H. Goddard and a liquid oxygen-gasoline rocket at Auburn, Massachusetts.
Author/Creator: Bob Burk, work supported by the National Science Foundation under grant numbers: 1246120, 1525057, and 1413739, Licence: CC BY 3.0
A chemical demonstration of the paramagnetism of molecular oxygen, as shown by the attraction of liquid oxygen to magnets.
Author/Creator: User:Rursus, Licence: CC BY 2.5
This diagram shows a simplified (not to scale) cross-section of a massive, evolved star (with a mass greater than eight times the Sun.) Where the pressure and temperature permit, concentric shells of Hydrogen (H), Helium (He), Carbon (C), Neon/Magnesium (Ne), Oxygen (O) and Silicon (Si) plasma are burning inside the star. The resulting fusion by-products rain down upon the next lower layer, building up the shell below. As a result of Silicon fusion, an inert core of Iron (Fe) plasma is steadily building up at the center. Once this core reaches the Chandrasekhar mass, the iron can no longer sustain its own mass and it undergoes a collapse. This can result in a supernova explosion.
Author/Creator: Heinrich D. Holland, Licence: CC-BY-SA-3.0
Estimated evolution of atmospheric . The upper red and lower green lines represent the range of the estimates. The stages are: stage 1 (3.85–2.45Gyr ago (Ga)), stage 2 (2.45–1.85Ga), stage 3 (1.85–0.85Ga), Stage 4 (0.85–0.54Ga )and stage 5 (0.54Ga–present)
This is an experiment setup with a test tube, a burner, a glass pipe, a glass jar, and a glass container to generate and collect oxygen by heating the potassium chlorate mixed with a small portion of manganese oxide.
U.S. Air Force Staff Sgt. Dustin Volpi tests liquid oxygen for purity at Eielson Air Force Base, Alaska. Quality liquid oxygen is used to provide oxygen to pilots and aircrews at altitudes above 10,000 feet.