Isotopes There are 22 known
isotopes of phosphorus, ranging from {{chem2|^{26}P}} to {{chem2|^{47}P}}. Only {{chem2|^{31}P}} is stable and, therefore, has 100% abundance. The
nuclear spin of 1/2 and high abundance of {{chem2|^{31}P}} make
phosphorus-31 nuclear magnetic resonance spectroscopy a very useful analytical tool in studies of phosphorus-containing samples. Two
radioactive isotopes of phosphorus have half-lives suitable for biological scientific experiments, and are used as radioactive tracers in biochemical laboratories. These are: • {{chem2|^{32}P|link=phosphorus-32}}, a
beta-emitter (1.71 MeV) with a
half-life of 14.3 days, which is used routinely in life-science laboratories, primarily to produce
radiolabeled DNA and RNA
probes, e.g. for use in
Northern blots or
Southern blots. • {{chem2|^{33}P}}, a beta-emitter (0.25 MeV) with a half-life of 25.4 days. It is used in life-science laboratories in applications in which lower energy beta emissions are advantageous such as
DNA sequencing. The high-energy beta particles from {{chem2|^{32}P}} penetrate skin and
corneas and any {{chem2|^{32}P}} ingested, inhaled, or absorbed is readily incorporated into bone and
nucleic acids. For these reasons, personnel working with {{chem2|^{32}P}} is required to wear lab coats, disposable gloves, and safety glasses, and avoid working directly over open containers.
Monitoring personal, clothing, and surface contamination is also required. The high energy of the beta particles gives rise to secondary emission of
X-rays via
Bremsstrahlung (braking radiation) in dense shielding materials such as lead. Therefore, the radiation must be
shielded with low density materials such as water, acrylic or other plastic.
Atomic properties A phosphorus atom has 15 electrons, 5 of which are
valence electrons. This results in the
electron configuration 1s22s22p63s23p3, often simplified as [Ne]3s23p3, omitting the
core electrons which have a configuration equivalent to the
noble gas of the preceding
period, in this case
neon. The molar
ionisation energies of these five electrons are 1011.8, 1907, 2914.1, 4963.6 and 6273.9 k
J⋅mol−1. Phosphorus is a member of the
pnictogens (also called
group 15) and
period 3 elements, and many of its chemical properties can be inferred from its position on the
periodic table as a result of
periodic trends. Like
nitrogen,
arsenic and
antimony, its main
oxidation states are −3, +3 and +5, with every one in-between less common but known. Phosphorus shows as expected more
electronegativity than
silicon and arsenic, less than
sulfur and nitrogen, but also notably less than
carbon, affecting the nature and properties of P–C bonds. It is the element with the lowest
atomic number to exhibit
hypervalence, meaning that it can form more
bonds per atom that would normally be permitted by the
octet rule.
Allotropes Phosphorus has several
allotropes that exhibit very diverse properties. The most useful and therefore common is
white phosphorus, followed by
red phosphorus. The two other main allotropes, violet and black phosphorus, have either a more fundamental interest or specialised applications. Many other allotropes have been theorised and synthesised, with the search for new materials an active area of research. Commonly mentioned "yellow phosphorus" is not an allotrope, but a result of the gradual degradation of white phosphorus into red phosphorus, accelerated by light and heat. This causes white phosphorus that is aged or otherwise impure (e.g. weapons-grade) to appear yellow. White phosphorus is a soft, waxy
molecular solid that is insoluble in water. It is also very toxic, highly
flammable and
pyrophoric, igniting in air at about . Structurally, it is composed of
tetrahedra. The nature of bonding in a given tetrahedron can be described by
spherical aromaticity or cluster bonding, that is the electrons are highly
delocalized. This has been illustrated by calculations of the magnetically induced currents, which sum up to 29 nA/T, much more than in the archetypical
aromatic molecule
benzene (11 nA/T). The molecule in the gas phase has a P-P bond length of 2.1994(3) Å as determined by
gas electron diffraction. White phosphorus exists in two crystalline forms named α (alpha) and β (beta), differing in terms of the relative orientation of the constituent tetrahedra. The α-form is most stable at room temperature and has a
cubic crystal structure. When cooled down to it transforms into the β-form, turning into an
hexagonal crystal structure. When heated up, the tetrahedral structure is conserved after melting at and boiling at , before facing
thermal decomposition at where it turns into gaseous
diphosphorus (). This molecule contains a triple bond and is analogous to ; it can also be generated as a transient intermediate in solution by thermolysis of organophosphorus precursor reagents. At still higher temperatures, dissociates into atomic P. When exposed to air, white phosphorus faintly glows green and blue due to
oxidation, a phenomenon best visible in the dark. This reaction with oxygen takes place at the surface of the solid (or liquid) phosphorus, forming the short-lived molecules and that both emit visible light. However, in a pure-oxygen environment phosphorus does not glow at all, with the oxidation happening only in a range of
partial pressures. Derived from this phenomenon, the terms
phosphors and
phosphorescence have been loosely used to describe substances that shine in the dark. However, phosphorus itself is not phosphorescent but
chemiluminescent, since it glows due to a chemical reaction and not the progressive reemission of previously absorbed light. Red phosphorus is
polymeric in structure. It can be viewed as a derivative of wherein one P-P bond is broken and one additional bond is formed with the neighbouring tetrahedron, resulting in chains of molecules linked by
van der Waals forces. Red phosphorus may be formed by heating white phosphorus to in the absence of air or by exposing it to sunlight. In this form phosphorus is
amorphous, but can be crystallised upon further heating into violet phosphorus or fibrous red phosphorus depending on the reaction conditions. Red phosphorus is therefore not an allotrope in the strictest sense of the term, but rather an intermediate between other crystalline allotropes of phosphorus, and consequently most of its properties have a range of values. Freshly prepared, bright red phosphorus is highly reactive and ignites at about . After prolonged heating or storage, the color darkens; the resulting product is more stable and does not spontaneously ignite in air. Violet phosphorus or α-metallic phosphorus can be produced by day-long annealing of red phosphorus above . In 1865,
Johann Wilhelm Hittorf discovered that when phosphorus was recrystallised from molten
lead, a red/purple form is obtained. Therefore, this form is sometimes known as "Hittorf's phosphorus" . Black phosphorus or β-metallic phosphorus is the least reactive allotrope and the thermodynamically stable form below . In appearance, properties, and structure, it resembles
graphite, being black and flaky, a conductor of electricity, and having puckered sheets of linked atoms. It is obtained by heating white phosphorus under high pressures (about ). It can also be produced at ambient conditions using metal salts, e.g. mercury, as catalysts. Single-layer black phosphorus is called
phosphorene, and is therefore predictably analogous to
graphene.
Natural occurrence Phosphorus has a concentration in the
Earth's crust of about one gram per kilogram (for comparison, copper is found at about 0.06 grams per kilogram). It is not found free in nature, but is widely distributed in many
minerals, usually as phosphates. Inorganic
phosphate rock, which is partially made of
apatite, is today the chief commercial source of this element. In 2013, astronomers detected phosphorus in
Cassiopeia A, which confirmed that this element is produced in
supernovae as a byproduct of
supernova nucleosynthesis. The phosphorus-to-
iron ratio in material from the
supernova remnant could be up to 100 times higher than in the
Milky Way in general. In 2020, astronomers analysed
ALMA and
ROSINA data from the massive
star-forming region AFGL 5142, to detect phosphorus-bearing molecules and how they could have been carried in comets to the early Earth. ==Compounds==