Name: Hydrogen
Symbol: H
Atomic Number: 1
Atomic Weight: 1.007940
Family: Non Metals
CAS RN: 1333-74-0
Description: Colorless gas (the lightest gas known).
State (25°C): Gas
Oxidation states: +1, -1

Molar Volume: 14.1 cm3/mole
Valence Electrons: 1s1

Boiling Point:  20.418K, -252.732°C, -422.918°F
Melting Point:
14.175K, -258.975°C, -434°F
Electrons Energy Level: 1
Isotopes: 4 + 2 Stable
Heat of Vaporization: 0.44936 kJ/mol
Heat of Fusion: 0.05868 kJ/mol
Density: 0899 g/L @ 273°K & 1atm
Specific Heat: 14.304 J/g°K
Atomic Radius: 0.79Å
Ionic Radius: 0.012Å
Electronegativity: 2.2 (Pauling); 2.2 (Allrod Rochow)
Vapor Pressure: 1570 mmHg @ -250°C
Hydrogen gas, H2, was first artificially produced and formally described by T. Von Hohenheim (also known as Paracelsus, 1493 - 1541) via the mixing of metals with strong acids.  He was unaware that the flammable gas produced by this chemical reaction was a new chemical element.  In 1671, Robert Boyle rediscovered and described the reaction between iron filings and dilute acids,  which results in the production of hydrogen gas.  In 1766, Henry Cavendish was the first to recognize hydrogen gas as a discrete substance, by identifying the gas from a metal-acid reaction as "inflammable air", and further finding that the gas produces water when burned.   Cavendish had stumbled on hydrogen when experimenting with acids and mercury.   Although he wrongly assumed that hydrogen was a liberated component of the mercury rather than the acid, he was still able to accurately describe several key properties of hydrogen. He is usually given credit for its discovery as an element. In 1783, Antoine Lavoisier gave the element the name of hydrogen when he (with Laplace) reproduced Cavendish's finding that water is produced when hydrogen is burned. Lavoisier's name for the gas won out.

Composed of a single proton and a single electron, hydrogen is the simplest and most abundant element in the universe.  It is estimated that 90% of the visible universe is composed of hydrogen.

One of the first uses of H2 was for balloons.  The H2 was obtained by reacting sulfuric acid and metallic iron.  Infamously, H2 was used in the Hindenburg airship that was destroyed in a midair fire.

At standard temperature and pressure it is a colorless, odorless, nonmetallic, tasteless, highly flammable diatomic gas (H2). With an atomic mass of 1.00794 g/mol, hydrogen is the lightest element. 



Hydrogen, Latin: "hydrognium", is from Ancient Greek (hydro): "water" and (genes): "forming".  Ancient Greek (geinomai): "to beget or sire")

The word "hydrogen" has several different meanings;

  1. the name of an element.
  2. an atom, sometimes called "H dot", that is abundant in space but essentially absent on Earth, because it dimerizes.
  3. a diatomic molecule that occurs naturally in trace amounts in the Earth's atmosphere; chemists increasingly refer to H2 as dihydrogen to distinguish this molecule from atomic hydrogen and hydrogen found in other compounds.
  4. the atomic constituent within all organic compounds, water, and many other chemical compounds. 

The elemental forms of hydrogen should not be confused with hydrogen as it appears in chemical compounds.


Role in History of Quantum Theory

Because of its relatively simple atomic structure, consisting only of a proton and an electron, the hydrogen atom, together with the spectrum of light produced from it or absorbed by it, has been central to the development of the theory of atomic structure.   Furthermore, the corresponding simplicity of the hydrogen molecule and the corresponding cation H2+ allowed fuller understanding of the nature of the chemical bond, which followed shortly after the quantum mechanical treatment of the hydrogen atom had been developed in the mid-1920s.

One of the first quantum effects to be explicitly noticed (but not understood at the time) was Maxwell's observation, half a century before full quantum mechanaical theory arrived.  He observed that the specific heat capacity of H2 unaccountably departs from that of a diatomic gas below room temperature and begins to increasingly resemble that of a monatomic gas at cryogenic temperatures.  According to quantum theory, this behavior arises from the spacing of the (quantized) rotational energy levels, which are particularly wide-spaced in H2 because of its low mass.  These widely spaced levels inhibit equal partition of heat energy into rotational motion in hydrogen at low temperatures.  Diatomic gases composed of heavier atoms do not have such widely spaced levels and do not exhibit the same effect.


250px-Triangulum.nebula.full.jpg (24288 bytes)

NGC 640, a giant region of ionized hydrogen in the Triangulum Galaxy

Hydrogen is the raw fuel that most stars 'burn' to produce energy. The same process, known as fusion, is being studied as a possible power source for use on earth. The sun's supply of hydrogen is expected to last another 5 billion years.

Hydrogen is the most bundant of the chemical elements, constituting roughly 75% of the universe's elemental mass.  Stars in the main sequence are mainly composed of hydrogen in its plasma state.  Elemental hydrogen is relatively rare on Earth, and is industrially produced from hydrocarbons such as methane, after which most elemental hydrogen is used "captively" (meaning locally at the production site), with the largest markets about equally divided between fossil fuel upgrading (e.g., hydrocracking) and in Ammonia, NH3, production (mostly for the fertilizer market).   Hydrogen may be produced from water using the process of electrolysis, but this process is presently significantly more expensive commercially than hydrogen production from natural gas.

The most common naturally occurring isotope of hydrogen is known as protium, has a single proton and no neutrons.  In ionic compounds it can take on either a positive charge (becoming a cation composed of a bare proton) or a negative charge (becoming an anion known as a hydride).  Hydrogen can form compounds with most elements and is present in water and most organic compounds.  It plays a particularly important role in acid-base chemistry, in which many reactions involve the exchange of protons between soluble molecules. As the only neutral atom for which the Schrodinger Equation can be solved analytically, study of the energetics and bonding of the hydrogen atom has played a key role in the development of quantum mechanics.

Hydrogen is the most abundant element in the universe, making up 75% of normal matter by mass and over 90% by number of atoms.  This element is found in great abundance in stars and gas giant planets.  Molecular clouds of H2 are associated with star formation. Hydrogen plays a vital role in powering stars through proton-proton reaction nuclear fusion.

Throughout the universe, hydrogen is mostly found in the atomic and plasma states whose properties are quite different from molecular hydrogen. As a plasma, hydrogen's electron and proton are not bound together, resulting in very high electrical conductivity and high emissivity (producing the light from the sun and other stars).  The charged particles are highly influenced by magnetic and electric fields. For example, in the solar wind they interact with the Earth's magnetosphere giving rise to Birkeland Currents and the Auroa Borealis.  Hydrogen is found in the neutral atomic state in the Interstellar medium.   The large amount of neutral hydrogen found in the damped Lyman-alpha systems is thought to dominate the cosmological baryonic density of the Universe up to Redshift   z=4.

Under ordinary conditions on Earth, elemental hydrogen exists as the diatomic gas, H2.   However, hydrogen gas is very rare in the Earth's atmosphere (1 ppm by volume) because of its light weight, which enables it to escape from Earth's gravity more easily than heavier gases. Although H atoms and H2 molecules are abundant in interstellar space, they are difficult to generate, concentrate, and purify on Earth. Still, hydrogen is the third most abundant element on Earth. Most of the Earth's hydrogen is in the form of chemical compounds such as hydrocarbons and water.  Hydrogen gas is produced by some bacteria and algae and is a natural component of flatus.  Methane is a hydrogen source of increasing importance.

The Hydrogen Atom

Electron Energy Levels

200px-Hydrogen_atom.svg.jpg (5260 bytes)

Dipiction of a Hydrogen Atom Showing the Diameter as About Twice the Bohr Model Radius (Not to Scale).

The ground state energy level of the electron in a hydrogen atom is 13.6 eV, which is equivalent to an ultraviolet photon of roughly 92 nm.

The energy levels of hydrogen can be calculated fairly accurately using the Bohr model of the atom, which conceptualizes the electron as "orbiting" the proton in analogy to the Earth's orbit of the sun. However, the electromagnetic force attracts electrons and protons to one another, while planets and celestial objects are attracted to each other by gravity.  Because of the discretization of angular momentum postulated in early quantum mechanics by Bohr, the electron in the Bohr model can only occupy certain allowed distances from the proton, and therefore only certain allowed energies. A more accurate description of the hydrogen atom comes from a purely quantum mechanical treatment that uses the Schrodinger Equation or the equivalent Feynman Path Integral Formulation to calculate the probability density of the electron around the proton.  Treating the electron as a matter wave reproduces chemical results such as shape of the hydrogen atom more naturally than the particle-based Bohr model, although the energy and spectral results are the same. Modeling the system fully using the reduced mass of nucleus and electron (as one would do in the two-body problem in celestial mechanics) yields an even better formula for the hydrogen spectra, and also the correct spectral shifts for the isotopes deuterium and tritium.  Very small adjustments in energy levels in the hydrogen atom, which correspond to actual spectral effects, may be determined by using a full quantum mechanical theory which corrects for the effects of special relativity, and by accounting for quantum effects arising from production of virtual particles in the vacuum and as a result of electric fields.

In hydrogen gas, the electronic ground state energy level is split into hyperfine structure levels because of magnetic effects of the quantum mechanical spin of the electron and proton.  The energy of the atom when the proton and electron spins are aligned is higher than when they are not aligned.  The transition between these two states can occur through emission of a photon through a magnetic dipole transition.   Radio telescopes can detect the radiation produced in this process, which is used to map the distribution of hydrogen in the galaxy.


150px-Hydrogen.svg.jpg (2844 bytes)

Protium, the Most Common Isotope of Hydrogen, has One Proton and One Electron.  Unique Among All Stable Isotopes, it has no Neutrons.

Hydrogen has three naturally occurring isotopes, denoted 1H, 2H, and 3H. Other, highly unstable nuclei (4H to 7H) have been synthesized in the laboratory but not observed in nature. The simplest isotope, called protium, is just ordinary hydrogen.  The second, a stable isotope called deuterium, was discovered in 1932. The third isotope, tritium, was discovered in 1934.

atom.gif (700 bytes)

Isotope Atomic Mass Half-Life
H1 1.0078 Stable
H2 2.0141 Stable
H3 3.016 12.33 years
H4 4.028 9.93696×10-23 seconds
H5 5.04 8.01930×10-23 seconds
H6 6.045 3.26500×10-22 seconds

Hydrogen is the only element that has different names for its isotopes in common use today. (During the early study of radioactivity, various heavy radioactive isotopes were given names, but such names are no longer used).  The symbols D and T (instead of 2H and 3H) are sometimes used for deuterium and tritium, but the corresponding symbol P is already in use for phosphorus and thus is not available for protium.   IUPAC states that while this use is common it is not preferred.

Elemental Molecular Forms

300px-Liquid_hydrogen_bubblechamber.jpg (19418 bytes)

First Tracks Observed in Liquid Hydrogen Bubble Chamber

There are two different types of diatomic hydrogen molecules that differ by the relative spin of their nuclei.  In the orthohydrogen form, the spins of the two protons are parallel and form a triplet state; in the parahydrogen form the spins are antiparallel and form a singlet. At standard temperature and pressure, hydrogen gas contains about 25% of the para form and 75% of the ortho form, also known as the "normal form".  The equilibrium ratio of orthohydrogen to parahydrogen depends on temperature, but since the ortho form is an excited state and has a higher energy than the para form, it is unstable and cannot be purified.  At very low temperatures, the equilibrium state is composed almost exclusively of the para form.   The physical properties of pure parahydrogen differ slightly from those of the normal form.  The ortho/para distinction also occurs in other hydrogen-containing molecules or functional groups, such as water and methylene.

The uncatalyzed interconversion between para and ortho H2 increases with increasing temperature; thus rapidly condensed H2 contains large quantities of the high-energy ortho form that convert to the para form very slowly.  The ortho/para ratio in condensed H2 is an important consideration in the preparation and storage of liquid hydrogen: the conversion from ortho to para is exothermic and produces enough heat to evaporate the hydrogen liquid, leading to loss of the liquefied material.   Catalysts for the ortho-para interconversion, such as iron compounds, are used during hydrogen cooling.

A molecular form called protonated molecular hydrogen, or H3+, is found in the interstellar medium (ISM), where it is generated by ionization of molecular Hydrogen from cosmic rays.  It has also been observed in the upper atmosphere of the planet Jupiter.  This molecule is relatively stable in the environment of outer space due to the low temperature and density. H3+ is one of the most abundant ions in the Universe, and it plays a notable role in the chemistry of the ISM.

Chemical and Physical Properties

The solubility and adsorption characteristics of hydrogen with various metals are very important in metallurgy (as many metals can suffer hydrogen embrittlement) and in developing safe ways to store it for use as a fuel. Hydrogen is highly soluble in many compounds composed of rare earth metals and transition metals and can be dissolved in both crystalline and amorphous metals.  Hydrogen solubility in metals is influenced by local distortions or impurities in the metal crystal lattice.


250px-Hindenburg_burning.jpg (9044 bytes)

Hydrogen Can Combust Rapidly in Air. It Burned Rapidly in the Hindenburg Disaster on May 6, 1937.

80px-Flammable.jpg (2186 bytes) Hydrogen gas is highly flammable and will burn at concentrations as low as 4% H2 in air. The enthalpy of combustion for hydrogen is –286 kJ/mol; it combusts according to the following balanced equation.

2H2(g) + O2(g) rarrow.gif (63 bytes) 2H2O(l) + 572 kJ

When mixed with oxygen across a wide range of proportions, hydrogen explodes upon ignition. Hydrogen burns violently in air. Pure hydrogen-oxygen flames are nearly invisible to the naked eye, as illustrated by the faintness of flame from the main Space Shuttle engines (as opposed to the easily visible flames from the shuttle boosters). Thus it is difficult to visually detect if a hydrogen leak is burning.  The Hindenburg Zeppelin flames seen in the adjacent picture are hydrogen flames colored with material from the covering skin of the zeppelin which contained carbon and pyrophoric aluminum powder.  (Regardless of the cause of this fire, this was clearly primarily a hydrogen fire since skin of the Zeppelin alone would have taken many hours to burn).  Another characteristic of hydrogen fires is that the flames tend to ascend rapidly with the gas in air, as illustrated by the Hindenberg flames, causing less damage than hydrocarbon fires. For example, two-thirds of the Hindenburg passengers survived that hydrogen fire, and many of the deaths which occurred were from falling or from gasoline burns.

H2 reacts directly with other oxidizing elements. A violent and spontaneous reaction can occur at room temperature with chlorine and fluorine, forming the corresponding hydrogen halides: hydrogen chloride and hydrogen fluoride.


Covalent and Organic Compounds

While H2 is not very reactive under standard conditions, it does form compounds with most elements.  Millions of hydrocarbons are known, but they are not formed by the direct reaction of elementary hydrogen and carbon (although synthesis gas production followed by the Fischer-Tropsch Process to make hydrocarbons comes close to being an exception, as this begins with coal and the elemental hydrogen is generated in situ). Hydrogen can form compounds with elements that are more electronegative, such as halogens (e.g., F, Cl, Br, I) and chalogens (O, S, Se); in these compounds hydrogen takes on a partial positive charge. When bonded to fluorine, oxygen, or nitrogen, hydrogen can participate in a form of strong noncovalent bonding called hydrogen bonding, which is critical to the stability of many biological molecules. Hydrogen also forms compounds with less electronegative elements, such as the metals and metalloids, in which it takes on a partial negative charge. These compounds are often known as hydrides.

Hydrogen forms a vast array of compounds with carbon.  Because of their general association with living things, these compounds came to be called organic compounds; the study of their properties is known as organic chemistry and their study in the context of living organisms is known as biochemistry.  By some definitions, "organic" compounds are only required to contain carbon (as a classic historical example, urea).   However, most of them also contain hydrogen, and since it is the carbon-hydrogen bond which gives this class of compounds most of its particular chemical characteristics, carbon-hydrogen bonds are required in some definitions of the word "organic" in chemistry. (This latter definition is not perfect, however, as in this definition urea would not be included as an organic compound).

In inorganic chemistry, hydrides can also serve as bridging ligands that link two metal centers in a coordination complex.  This function is particularly common in group 13 elements, especially in boranes (boron hydrides) and aluminum complexes, as well as in clustered carborances.


Compounds of hydrogen are often called hydrides, a term that is used fairly loosely. To chemists, the term "hydride" usually implies that the H atom has acquired a negative or anionic character, denoted H-. The existence of the hydride anion, suggested by G.N. Lewis in 1916 for group I and II salt-like hydrides, was demonstrated by Moers in 1920 with the electrolysis of molten lithium hydride (LiH), that produced a stoichiometric quantity of hydrogen at the anode.  For hydrides other than group I and II metals, the term is quite misleading, considering the low electronegativity of hydrogen. An exception in group II hydrides is BeH2, which is polymeric. In lithium aluminum hydride, the AlH4- anion carries hydridic centers firmly attached to the Al(III).  Although hydrides can be formed with almost all main-group elements, the number and combination of possible compounds varies widely; for example, there are over 100 binary borane hydrides known, but only one binary aluminum hydride.  Binary indium hydride has not yet been identified, although larger complexes exist.

"Protons" and Acids

Oxidation of H2 formally gives the proton, H+. This species is central to discussion of acids, though the term proton is used loosely to refer to positively charged or cationic hydrogen, denoted H+. A bare proton H+ cannot exist in solution because of its strong tendency to attach itself to atoms or molecules with electrons. To avoid the convenient fiction of the naked "solvated proton" in solution, acidic aqueous solutions are sometimes considered to contain the hydronium ion (H3O+) organized into clusters to form H9O4+.   Other oxonium ions are found when water is in solution with other solvents.

Although exotic on earth, one of the most common ions in the universe is the H3+ ion, known as protonated molecular hydrogen or the triatomic hydrogen cation.

Water (H2O) Ammonia (NH3)
Methane (CH4) Sucrose or Table Sugar (C12H22O11)
Hydrogen Peroxide (H2O2) Hydrochloric acid (HCl)


Hydrogen is a commercially important element.  Large amounts of hydrogen are combined with nitrogen from the air to produce ammonia (NH3) through a process called the Haber process.  Hydrogen is also added to fats and oils, such as peanut oil, through a process called hydrogenation. Liquid hydrogen is used in the study of superconductors and, when combined with liquid oxygen, makes an excellent rocket fuel.

H2 is produced in chemistry and biology laboratories, often as a by-product of other reactions; in industry for the hydrogenation of unsaturated substrates; and in nature as a means of expelling reducing equivalents in biochemical reactions.

Laboratory Synthesis

In the laboratory, H2 is usually prepared by the reaction of acids on metals such as zinc. 

Zn + 2H+ rarrow.gif (63 bytes) Zn2+ + H2

Aluminum produces H2 upon treatment with acids but also with base:

2Al + 6H2O rarrow.gif (63 bytes) 2Al(OH)3 + 3H2

The electrolysis of water is a simple method of producing hydrogen, although the resulting hydrogen necessarily has less energy content than was required to produce it. A low voltage current is run through the water, and gaseous oxygen forms at the anode while gaseous hydrogen forms at the cathode.  Typically the cathode is made from platinum or another inert metal when producing hydrogen for storage. If, however, the gas is to be burnt on site, oxygen is desirable to assist the combustion, and so both electrodes would be made from inert metals. (Iron, for instance, would oxidize, and thus decrease the amount of oxygen given off.) The theoretical maximum efficiency (electricity used vs. energetic value of hydrogen produced) is between 80–94%.

2H2O(aq) rarrow.gif (63 bytes) 2H2(g) + O2(g)

Industrial Synthesis

Hydrogen can be prepared in several different ways but the economically most important processes involve removal of hydrogen from hydrocarbons. Commercial bulk hydrogen is usually produced by the steam reforming of natural gas.  At high temperatures (700–1100 °C; 1,300–2,000 °F), steam (water vapor) reacts with methane to yield carbon monoxide and H2.

CH4 + H2O rarrow.gif (63 bytes) CO + 3H2

This reaction is favored at low pressures but is nonetheless conducted at high pressures (20 atm; 600 inHg) since high pressure H2 is the most marketable product.  The product mixture is known as "synthesis gas" because it is often used directly for the production of methanol and related compounds.   Hydrocarbons other than methane can be used to produce synthesis gas with varying product ratios. One of the many complications to this highly optimized technology is the formation of coke or carbon:

CH4 rarrow.gif (63 bytes) C + 2H2

Consequently, steam reforming typically employs an excess of H2O.

Additional hydrogen from steam reforming can be recovered from the carbon monoxide through the water gas shift reaction, especially with an iron oxide catalyst.  This reaction is also a common industrial source of carbon dioxide:

CO  + H2O rarrow.gif (63 bytes) CO2 + H2

Other important methods for H2 production include partial oxidation of hydrocarbons:

CH4 + 0.5O2 rarrow.gif (63 bytes) CO + 2H2

and the coal reaction, which can serve as a prelude to the shift reaction above:

C + H2O rarrow.gif (63 bytes) CO + H2

Hydrogen is sometimes produced and consumed in the same industrial process, without being separated.  In the Haber Process for the production of ammonia (the world's fifth most produced industrial compound), hydrogen is generated from natural gas.

Biological Synthesis

H2 is a product of some types of anaerobic metabolism and is produced by several microorganisms, usually via reactions catalyzed by iron or nickel contining enzymes called hydrogenases.  These enzymes catalyze the reversible redox reaction between H2 and its component two protons and two electrons. Evolution of hydrogen gas occurs in the transfer of reducing equivalents produced during pyruvate fermentation to water.

Water splitting, in which water is decomposed into its component protons, electrons, and oxygen, occurs in the light reactions in in all photosynthetic organisms.   organisms. Some such organisms — including the alga Chlamydomonas reinhardtii and cyanobacteria — have evolved a second step in the dark reactions in which protons and electrons are reduced to form H2 gas by specialized hydrogenases in the chloroplast.  Efforts have been undertaken to genetically modify cyanobacterial hydrogenases to efficiently synthesize H2 gas even in the presence of oxygen.

Other rarer but mechanistically interesting routes to H2 production also exist in nature.  Nitrogenase produces approximately one equivalent of H2 for each equivalent of N2 reduced to ammonia. Some phosphatases reduce phosphite to H2.


Large quantities of H2 are needed in the petroleum and chemical industries. The largest application of H2 is for the processing ("upgrading") of fossil fuels, and in the production of ammonia. The key consumers of H2 in the petrochemical plant include hydrodealkylation, hydrosulfurization, and hydrocracking.   H2 has several other important uses. H2 is used as a hydrogenating agent, particularly in increasing the level of saturation of unsaturated fats and oils (found in items such as margarine), and in the production of methanol.   It is similarly the source of hydrogen in the manufacture of hydrochloric acid.   H2 is also used as a reducing agent of metallic ores.

Apart from its use as a reactant, H2 has wide applications in physics and engineering. It is used as a shielding gas in welding methods such as atomic hydrogen welding.  H2 is used as the rotor coolant in electrical generators at power stations, because it has the highest thermal conductivity of any gas.  Liquid H2 is used in cryogenic research, including superconductivity studies. Since H2 is lighter than air, having a little more than 1/15th of the density of air, it was once widely used as a lifting agent in balloons and airships.   However, this use was curtailed after the Hindenburg disaster convinced the public that the gas was too dangerous for this purpose. Hydrogen is still regularly used for the inflation of weather balloons.

Hydrogen's rarer isotopes also each have specific applications.  Deuterium (hydrogen-2) is used in nuclear fission applications as a moderator to slow neutrons, and in nuclear fusion reactions.  Deuterium compounds have applications in chemistry and biology in studies of reaction isotope effects.  Tritium (hydrogen-3), produced in nuclear reactors, is used in the production of hydrogen bombs, as an isotopic label in the biosciences, and as a radiation source in luminous paints.

The triple point temperature of equilibrium hydrogen is a defining fixed point on the ITS-90 temperature scale.

Hydrogen as an Energy Source

Elemental hydrogen has been widely discussed in the context of energy, as a possible carrier of energy on an economy-wide scale. A theoretical advantage of using H2 as an energy carrier, is the localization and concentration of environmentally unwelcome aspects of hydrogen manufacture from fossil fuel energy sources. For example, CO2 sequestration followd by carbon capture and storage could be conducted at the point of H2 production from methane.  Hydrogen used in transportation would burn cleanly, without carbon emmissions.  However, the infrastructure costs associated with full conversion to a hydrogen economy would be substantial.

atom.gif (700 bytes)

Hydrogen Data


Atomic Structure

Atomic Radius (Å): 0.79Å
Atomic Volume cm3/mol : 14.4cm3/mol
Covalent Radius: 0.32Å
Crystal Structure: Hexagonal
Ionic Radius: 0.012Å

Chemical Properties

Electrochemical Equivalents: 0.037605g/amp-hr
Electron Work Function: unknown
Electronegativity: 2.2 (Pauling); 2.2 (Allrod Rochow)
Heat of Fusion: 0.05868 kJ/mol
Incompatibilities: metals, oxidizing materials, metal oxides, combustible materials, halogens, metal salts, halo carbons
First Ionization Potential: 13.598
Second Ionization Potential: unknown
Third Ionization Potential: unknown
Valence Electron Potential(-eV): 1200
Ionization Energy (eV): 13.598 eV

Physical Properties

Atomic Mass Average: 1.00794
Boiling Point: 20.418°K, -252.732°C, -422.918°F
Melting Point: 14.175°K, -258.975°C, -434°F
Heat of Vaporization: 0.44936 kJ/mol
Coefficient of Lineal Thermal Expansion/K-1: N/A
Electrical Conductivity: unknown
Thermal Conductivity: 0.001815 W/cmK
Density: 0899 g/L @ 273°K & 1atm
Elastic Modulus (Bulk): unknown
Elastic Modulus (Rigidity): unknown
Elastic Modulus Youngs: unknown
Enthalpy of Atomization: 217.6 kJ/mole @ 25°C
Enthalpy of Fusion: 0.059 kJ/mole
Enthalpy of Vaporization: 0.449 kJ/mole
Hardness Scale (Brinell): unknown
Hardness Scale (Mohs): unknown
Hardness Scale (Vickers): unknown
Flammability Class: Highly flammable gas
Auto Ignition Temperature:
773°K, 500°C, 932°F
Explosive Limits - Lower (LEL): 17%
Explosive Limits - Upper (UEL): 56%
Flash Point:
20K, -253°C, -423°F - Theoretical (there are no oxidizing materials i.e. oxygen in the gas state at this temperature, which is necessary to support combustion.)
Molar Volume: 14.1 cm3/mole
Optical Reflectivity: unknown
Optical Refractive Index: 1.000132 (gas) 1.12 (liquid)
Relative Gas Density (Air=1): 0.0694
Specific Heat: 14.304 J/g°K
Vapor Pressure: 1570 mmHg @ -250°C
Estimated Crustal Abundance: 1.40×103 milligrams per kilogram
Estimated Oceanic Abundance:
1.08×105 milligrams per liter