Isotopes of lithium
Significant variation occurs in commercial samples because of the wide distribution of samples depleted in 6Li. | |||||||||||||||||||||
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Naturally occurring lithium (3Li) is composed of two stable isotopes, lithium-6 (6Li) and lithium-7 (7Li), with the latter being far more abundant on Earth. Radioisotopes are short-lived: the particle-bound ones, 8Li, 9Li, and 11Li, have half-lives of 838.7, 178.2, and 8.75 milliseconds respectively.
Both of the natural isotopes have anomalously low nuclear binding energy per nucleon (5332.3312(3) keV for 6Li and 5606.4401(6) keV for 7Li) when compared with the adjacent lighter and heavier elements, helium (7073.9156(4) keV for helium-4) and beryllium (6462.6693(85) keV for beryllium-9), and so their synthesis requires non-equilibrium conditions.
Both 7Li and 6Li were produced in the Big Bang, with 7Li estimated to be 5×10−10 of all primordial matter, and 6Li around 10−14 (undetectable). This difference is significant because both isotopes of lithium are efficiently destroyed by protons, while beryllium-7 is not and subsequently decays to lithium. A portion of 7Li is also known to be formed in certain stars (red giants), called the Cameron–Fowler mechanism; while beryllium-7 is a normal product of nuclear burning, it can only contribute to lithium production if it is convected to the surface before it decays. Thus, it is considered that almost all 6Li, like much 7Li, is cosmogenic and produced by spallation.
The isotopes of lithium separate somewhat during a variety of geological processes, including mineral formation (chemical precipitation and ion exchange) – for example, lithium ions replace magnesium or iron in certain octahedral locations in clays, and 6Li is sometimes preferred over 7Li, resulting in enrichment of the clays. It is considered that an accurate relative atomic mass for samples of lithium cannot be measured for all sources of lithium.
In nuclear physics, 6Li is an important isotope, because when it is exposed to slow neutrons, tritium is produced with nearly 100% yield; contrarily, 7Li is almost unreactive with slow neutrons.
Both 6Li and 7Li isotopes show nuclear magnetic resonance, despite being quadrupolar (with nuclear spins of 1+ and 3/2−). 6Li has sharper lines, but due to its lower abundance requires a more sensitive NMR-spectrometer. 7Li is more abundant, but has broader lines because of its larger nuclear spin and quadrupole. The range of chemical shifts is the same of both nuclei and lies within +10 (for LiNH2 in liquid NH3) and −12 (for Li+ in fulleride).