Physical properties Californium is a silvery-white
actinide metal with a
melting point of and an estimated
boiling point of . The pure metal is malleable and is easily cut with a knife. Californium metal starts to vaporize above when exposed to a vacuum. Below californium metal is either
ferromagnetic or
ferrimagnetic (it acts like a magnet), between 48 and 66 K it is
antiferromagnetic (an intermediate state), and above it is
paramagnetic (external magnetic fields can make it magnetic). It forms
alloys with
lanthanide metals but little is known about the resulting materials. The element has two
crystalline forms at
standard atmospheric pressure: a double-
hexagonal close-packed form dubbed alpha (α) and a
face-centered cubic form designated beta (β). The α form exists below 600–800 °C with a density of 15.10 g/cm3 and the β form exists above 600–800 °C with a density of 8.74 g/cm. At 48
GPa of pressure the β form changes into an
orthorhombic crystal system due to delocalization of the atom's
5f electrons, which frees them to bond. The
bulk modulus of a material is a measure of its resistance to uniform pressure. Californium's bulk modulus is , which is similar to trivalent lanthanide metals but smaller than more familiar metals, such as aluminium (70 GPa).
Chemical properties and compounds Californium exhibits oxidation states of 4, 3, or 2. It typically forms eight or nine bonds to surrounding atoms or ions. Its chemical properties are predicted to be similar to other primarily 3+ valence actinide elements and the element
dysprosium, which is the lanthanide above californium in the periodic table. Compounds in the +4 oxidation state are strong
oxidizing agents and those in the +2 state are strong
reducing agents. The element slowly tarnishes in air at room temperature, with the rate increasing when moisture is added. Californium reacts when heated with
hydrogen,
nitrogen, or a
chalcogen (oxygen family element); reactions with dry hydrogen and aqueous
mineral acids are rapid. Californium is only
water-soluble as the californium(III)
cation. Attempts to
reduce or oxidize the +3 ion in solution have failed. The element forms a water-soluble
chloride,
nitrate,
perchlorate, and
sulfate and is precipitated as a
fluoride,
oxalate, or
hydroxide. Californium is the heaviest actinide to exhibit covalent properties, as is observed in the californium borate.
Isotopes :
All nuclear data not otherwise stated is from the standard source: Twenty
isotopes of californium are known with
mass number ranging from 237 to 256; the most stable are Cf with
half-life 898 years, Cf with half-life 351 years, Cf at 13.08 years, and Cf at 2.645 years. All other isotopes have half-life shorter than a year, and most of these have half-lives less than 20 minutes. Cf is formed by
beta decay of berkelium-249, and heavier californium isotopes are made by subjecting berkelium to intense neutron radiation in a
nuclear reactor. Though californium-251 has the longest half-life, its production yield is relatively low due to its rapid depletion by reaction with another neutron (high
neutron cross section). Cf is a very strong
neutron emitter, which makes it an extremely hazardous
radioactive isotope. Cf, 96.9% of the time,
alpha decays to
curium-248; the other 3.1% of decays are
spontaneous fission. One
microgram of Cf emits 2.3 million neutrons per second (about 3.7 neutrons per fission). The other main isotopes of californium (248-251) also alpha decay to those of
curium, with a much smaller fraction of fission. == History ==