| hydrogen – helium |
H
Li
|
Image:H-TableImage-BIG.png
|
|
| General |
| Name, Symbol, Number | Hydrogen, H, 1 |
| Chemical series | nonmetals |
| Group, Period, Block | 1 (IA), 1, s |
| Density, Hardness | 0.0899 kg/m3, NA |
| Appearance | colorless
Image:H,1.jpg |
| Atomic properties |
| Atomic weight | 1.00794 amu |
| Atomic radius (calc) | 25 (53) pm |
| Covalent radius | 37 pm |
| van der Waals radius | 120 pm |
| Electron configuration | 1s1 |
| e- 's per energy level | 1 |
| Oxidation states (Oxide) | 1 (amphoteric) |
| Crystal structure | hexagonal |
| Physical properties |
| State of matter | gas |
| Melting point | 14.025 K (−434.452 °F) |
| Boiling point | 20.268 K (−423.166 °F) |
| Critical temperature | 32.19 K |
| Critical pressure | 13.15 bar |
| Critical density | 30.12 g/l |
| Heat of vaporization | 0.44936 kJ/mol |
| Heat of fusion | 0.05868 kJ/mol |
| Vapor pressure | 209 Pa at 23 K |
| Speed of sound | 1270 m/s at 298.15 K |
| Miscellaneous |
| Electronegativity | 2.2 (Pauling scale) |
| Specific heat capacity | 14304 J/(kg
|
| Electrical conductivity | __ 106/(m·ohm) |
| Thermal conductivity | 0.1815 W/(m
|
| Ionization potential | 1312 kJ/mol |
| Most stable isotopes |
|
All hydrogen isotopes
|
SI units & STP are used except where noted. |
Hydrogen (
Latin:
hydrogenium, from
Greek:
hydro: water,
genes: forming) is a
chemical element in the
periodic table that has the symbol
H and
atomic number 1. At standard temperature and pressure it is a colorless, odorless, non-metallic,
univalent, highly
flammable diatomic gas. Hydrogen is the lightest and most
abundant element in the
universe. It is present in
water and in all organic compounds and living organisms. Hydrogen is able to react chemically with most other elements.
Stars in their
main sequence are overwhelmingly composed of hydrogen in its
plasma state. This element is used in
ammonia production, as a lifting gas, as an alternative
fuel, and more recently as a power source of
fuel cells.
In the
laboratory, hydrogen is prepared by reaction of
acids on metals such as
zinc. For production in large scale commercial bulk hydrogen is usually manufactured by
steam reforming natural gas.
Electrolysis of water is a simple method, but it is still economically inefficient for mass production. Scientists are now researching new methods for hydrogen production. One of them involves use of green
algae. Another promising method involves the conversion of biomass derivatives such as
glucose or
sorbitol, which can be done at low temperatures through the use of a new
catalyst.
Notable characteristics
Hydrogen is the lightest chemical element with its most common
isotope consisting of just a single
proton and
electron. At standard temperature and pressure conditions, hydrogen forms a diatomic gas, H
2, with a boiling point of only 20.27
K and a melting point of 14.02 K. Under exceedingly high pressures, like those found at the center of
gas giants, the molecules lose their identity and the hydrogen becomes a liquid
metal (see
metallic hydrogen). Under the exceedingly low pressure conditions found in space, hydrogen tends to exist as individual atoms, simply because there is no way for them to combine; clouds of H
2 form and are associated with
star formation.
This element plays a vital role in powering the
Universe through the proton-proton reaction and carbon-nitrogen cycle. (These are
nuclear fusion processes that release huge amounts of energy through combining hydrogen atoms into
helium.)
Hydrogen Atom
Main article: hydrogen atom.
A
hydrogen atom is an
atom of the element
hydrogen. It is composed of a single negatively charged
electron, distributed around the positively charged
proton which is the
nucleus of the hydrogen atom. The electron is bound to the proton by the Coulomb force.
Applications
Large quantities of hydrogen are needed industrially, notably in the
Haber process for the production of
ammonia, the
hydrogenation of
fats and
oils, and the production of
methanol. Hydrogen is used in hydrodealkylation, hydrodesulfurization, and hydrocracking. Other uses:
- The element is used in the manufacture of hydrochloric acid, welding, and the reduction of metallic ores.
- It is used in rocket fuels.
- Having the highest thermal conductivity of any gas, hydrogen is used as the rotor coolant in electrical generators at power stations.
- Liquid hydrogen is used to perform cryogenic research, including superconductivity studies.
- Since hydrogen is fourteen and a half times lighter than air, it was once widely used as a lifting agent in balloons and airships. However this use was curtailed when the Hindenburg disaster convinced the public that the gas was too dangerous for this purpose.
- Deuterium, an isotope (hydrogen-2) of hydrogen, is used in nuclear fission applications as a moderator to slow down neutrons, and is also used 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 to construct hydrogen bombs. It is also used as an isotopic label in the biosciences and as a radiation source in luminous paints.
Hydrogen can be burned in
internal combustion engines, and a fleet of hydrogen-burning
cars is maintained by Chrysler-BMW (see
Hydrogen car). Hydrogen
fuel cells are being looked into as a way to provide
power with lower emissions than hydrogen burning
internal combustion engines. The low emissions of hydrogen in
internal combustion engines and
fuel cells is currently offset by the pollution created by hydrogen production. This may change if in the future electricity for water
electrolysis can be generated primarily by solar, wind and nuclear power, giving a clean portable fuel cycle.
Research is being conducted on hydrogen as a possible major future fuel. It could become the link between diverse energy sources, carriers and storage. For instance, it can be converted to and from electricity (solving the electricity storage and transport issues), from bio-fuels, from and into
natural gas and
diesel fuel. All of this can theoretically be done with no emission of either CO
2 or toxic chemicals.
History
Hydrogen (
French for
water-maker, from
Greek hudôr, "water" and
gennen, "generate") was first recognized as a distinct substance in 1766 by
Henry Cavendish. Cavendish stumbled upon it when experimenting with acids and
mercury. Although he wrongly assumed that hydrogen was a compound of mercury (and not of the
acid), he was still able to describe many of hydrogen's properties quite accurately.
Antoine Lavoisier gave the element its name and proved that water was made of hydrogen and
oxygen. One of its first uses was for
balloons. The hydrogen was obtained by mixing
sulfuric acid and
iron.
Deuterium, an
isotope of hydrogen, was discovered by
Harold C. Urey by distilling a sample of water multiple times. Urey received a
Nobel prize for his discovery in 1934. In the same year, the third isotope,
tritium, was discovered.
Electron Energy Levels
The
ground state energy level of the electron in a Hydrogen atom is 13.6
eV which is equivilent to an ultra-violet photon of roughly 92
nm.
With the
Bohr Model the energy levels of Hydrogen can be calculated fairly accurately. This is done by modeling the electron as revolving around the proton much like the earth revolving around the sun. Except the sun holds earth in orbit with the force of
gravity, but the proton holds the electron in orbit with the force of
electromagnetism. Another difference between the Earth-Sun system and the Electron-Proton system is that, in this model, due to
quantum mechanics the electron is allowed to only be at very specific distances from the proton. Modeling the hydrogen atom in this fashion yields the correct energy levels and spectrum.
Occurrence
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. It is very rare in the
Earth's atmosphere (1 ppm by volume). The most common source for this element on Earth is
water, which is composed two parts hydrogen to one part
oxygen (H
2O). Other sources include most forms of organic matter (currently all known life forms) including
coal,
natural gas, and other
fossil fuels.
Methane (
CH4) is an increasingly important source of hydrogen.
Hydrogen can be prepared in several different ways:
steam on heated
carbon,
hydrocarbon decomposition with heat, reaction of a strong base in an aqueous solution with
aluminium, water
electrolysis, or displacement from
acids with certain
metals.
Commercial bulk hydrogen is usually produced by the
steam reforming of
natural gas. At high temperatures (700-1100 °C), steam reacts with methane to yield
carbon monoxide and hydrogen.
:
CH4 +
H2O →
CO + 3 H
2
Additional hydrogen can be recovered from the carbon monoxide through the water-gas shift reaction:
:
CO +
H2O →
CO2 + H
2
Compounds
The lightest of all gases, hydrogen combines with most other elements to form compounds. Hydrogen has an
electronegativity of 2.2, so it forms compounds where it is the more non-metallic and where it is the more metallic element. The former are called
hydrides, where hydrogen either exists as H
- ions or just as a solute within the other element (as in
palladium hydride). The latter tend to be
covalent, since the H
+ ion would be a bare nucleus and so has a strong tendency to pull electrons to itself. These both form acids. Thus even in an
acidic solution one sees ions like
hydronium (H
3O
+) as the protons latch on to something.
Hydrogen combines with oxygen to form
water, H
2O, and releases a lot of energy in doing so, burning
explosively in air. Deuterium oxide, or D
2O, is commonly referred to as
heavy water. Hydrogen also forms a vast array of compounds with
carbon. Because of their association with living things, these compounds are called
organic compounds, and the study of the properties of these compounds is called
organic chemistry.
First tracks observed in Liquid hydrogen bubble chamber.
Under normal conditions hydrogen gas is a mix of two different kinds of
molecules which differ from one another by the
relative
spin of the
nuclei. These two forms are
known as ortho- and para-hydrogen (this is different from
isotopes, see
below).
In ortho-hydrogen the nuclear spins are parallel (form a triplet),
while in para they are antiparallel (form a singlet).
At standard conditions hydrogen is
composed of about 25% of the para form and 75% of the ortho form (the
so-called "normal" form). The equilibrium
ratio of these two forms depends on temperature, but since
the ortho form has higher energy (is an
excited state), it cannot be stable in its pure form.
In low temperatures (around boiling point), the equilibrium state is
comprised almost entirely of the para form.
The conversion process between the forms is slow, and if hydrogen is cooled down and condensed rapidly, it contains large quantities of the ortho form. It is important in preparation and storage of liquid hydrogen since the ortho-para conversion produces more heat than the heat of its evaporation and a lot of hydrogen can be lost by evaporation in this way during several days after liquifying. Therefore, some
catalysts of the ortho-para conversion process are used during hydrogen cooling. The two forms have also slightly different physical properties. For example, the melting and boiling points of parahydrogen are about 0.1 K lower than of the "normal" form.
Isotopes
Hydrogen is the only element that has different names for its isotopes.
(During the early study of radioactivity, various heavy radioactive isotopes were given names, but such names are no longer used, although one element,
radon, has a name that originally applied to only one of its isotopes.)
The symbols D and T (instead of
2H and
3H) are sometimes used for deuterium and tritium, although this is not officially sanctioned. (The symbol P is already in use for
phosphorus and is not available for protium.)
;
1H
The most common isotope of hydrogen, this stable isotope has a
nucleus consisting of a single
proton; hence the descriptive, although rarely used, name
protium.
;
2H
The other stable isotope is
deuterium, with an extra
neutron in the nucleus. Deuterium comprises 0.0184-0.0082% of all hydrogen (IUPAC); ratios of deuterium to protium are reported relative to the
VSMOW standard reference water.
;
3H
The third naturally-occurring hydrogen isotope is the radioactive
tritium. The tritium nucleus contains two neutrons in addition to the proton. It decays through
beta decay and has a half-life of 12.32 years.
;
4H
Hydrogen-4 was synthesised by bombarding tritium with fast-moving deuterium nuclei. It decays through
neutron emission and has a half-life of 9.93696x10
-23 seconds.
;
5H
In 2001 scientists detected
hydrogen-5 by bombarding a hydrogen target with heavy ions. It decays through
neutron emission and has a half-life of 8.01930x10
-23 seconds.
;
6H
Hydrogen-6 decays through triple
neutron emission and has a half-life of 3.26500
-22 seconds.
;
7H
In 2003
hydrogen-7 was created (
article) at the RIKEN laboratory in Japan by colliding a high-energy beam of helium-8 atoms with a cryogenic hydrogen target and detecting tritons—the nuclei of tritium atoms—and neutrons from the break up of hydrogen-7, the same method used to produce and detect hydrogen-5.
Precautions
Hydrogen is a highly
flammable gas burning at concentrations as low as 4%. It also reacts violently with
chlorine and
fluorine, forming hydrohalic
acids that can cause damage to the
lungs and other
tissues. When mixed with oxygen, hydrogen explodes on ignition. Hydrogen also has the unique property that a hydrogen flame in air is completely clear. This makes it difficult to tell if a leak is burning or not, and carries the added risk that one can walk into a hydrogen fire without noticing until too late.
See also
References
External links
Category:Nonmetals
Category:Fuels
af:Waterstof
ar:هيدروجين
bg:Водород
ca:Hidrogen
cs:Vodík
cy:Hydrogen
da:Brint
de:Wasserstoff
et:Vesinik
el:Υδρογόνο
es:Hidrógeno
eo:Hidrogeno
eu:Hidrogeno
fa:هیدروژن
fr:Hydrogène
ga:Hidrigin
gd:Haidreagain
gl:H (elemento)
gu:હાઈડ્રોજન
ko:수소
hr:Vodik
io:Hidrogeno
id:Hidrogen
ia:Hydrogeno
is:Vetni
it:Idrogeno
he:מימן
ku:Hîdrojen
la:Hydrogenium
lv:Ūdeņradis
lt:Vandenilis
li:Waterstof
hu:Hidrogén
mk:Водород
mi:Hauwai
ms:Hidrogen
nl:Waterstof
nds:Waterstoff
ja:水素
nb:Hydrogen
nn:Hydrogen
pl:Wodór
pt:Hidrogénio
ro:Hidrogen
ru:Водород
simple:Hydrogen
sk:Vodík
sl:Vodik
sr:Водоник
fi:Vety
sv:Väte
th:ไฮโดรเจน
vi:Hiđrô
tr:Hidrojen
uk:Водень
zh:氢