Occurring as a minor accessory mineral, xenotime is found in
pegmatites and other
igneous rocks, as well as
gneisses rich in
mica and
quartz. Associated minerals include
biotite and other micas,
chlorite group minerals, quartz, zircon, certain
feldspars,
analcime,
anatase,
brookite,
rutile,
siderite and
apatite. Xenotime is also known to be
diagenetic: It may form as minute grains or as extremely thin (less than 10
μ) coatings on detrital zircon grains in siliciclastic
sedimentary rocks. The importance of these diagenetic xenotime deposits in the
radiometric dating of sedimentary rocks is only beginning to be realized. The formation of uranium and lead in xenotime ores classifies xenotime as a U-Pb chronometer, meaning it can be used for geological dating using U-Th-Pb
geochronology techniques. The spectrometry used in geochronology necessitates larger crystals of at least 10 μm, therefore SEM imaging is applied to identify crystals that meet the appropriate dimensions. After identification, there are various spectroscopy approaches and microprobes for geochronology: SIMS, EMPA, LA-ICP-MS, and ID-TIMS. Xenotime can be found in geological formations that formed from the mid-Archean age to the Mesozoic age, so geological dating using xenotime in sedimentary rocks is extensive and a useful application. Discovered in 1824, xenotime's type locality is
Hidra (Hitterø),
Flekkefjord,
Vest-Agder,
Norway. Other notable localities include:
Arendal and
Tvedestrand, Norway;
Novo Horizonte, São Paulo,
Novo Horizonte, Bahia and
Minas Gerais,
Brazil;
Madagascar and
California,
Colorado,
Georgia,
North Carolina and
New Hampshire, United States. A new discovery of gemmy, colour change (brownish to yellow) xenotime has been reported from
Afghanistan and been found in
Pakistan. Due to their isostructural nature, it is common for xenotime and zircon to co-crystallize together as composites; either forming crystal twins or growths over one another. North of
Mount Funabuse in
Gifu Prefecture,
Japan, a notable
basaltic
rock is quarried at a hill called Maru-Yama: crystals of xenotime and zircon arranged in a radiating, flower-like pattern are visible in polished slices of the rock, which is known as
chrysanthemum stone (translated from the
Japanese 菊石
kiku-ishi). This stone is widely appreciated in Japan for its ornamental value. Small tonnages of xenotime sand are recovered in association with Malaysian
tin mining, etc. and are processed commercially. The lanthanide content is typical of "yttrium earth" minerals and runs about two-thirds yttrium, with the remainder being mostly the heavy lanthanides, where the even-numbered lanthanides (such as Gd, Dy, Er, or Yb) each being present at about the 5% level, and the odd-numbered lanthanides (such as Tb, Ho, Tm, Lu) each being present at about the 1% level. Dysprosium is usually the most abundant of the even-numbered heavies, and holmium is the most abundant of the odd-numbered heavies. The lightest lanthanides are generally better represented in monazite while the heaviest lanthanides are in xenotime. Xenotime ores have to undergo chemical treatments to separate the rare earth elements (RREs) that make up its composition. Firstly, leaching, or dissolving of the phosphate shell is performed using
sulfuric acid (H2SO4) or
sodium hydroxide (NaOH), leaving behind the mixed RREs. Various techniques can be applied next to further separate the individual elements. One is the use of
ion exchange methods, which encourages different elution times for different lanthanides based on ionic bonding. The quaternary ammonium anion salt trioctyl methylammonium nitrate, or commonly referred to as
Aliquat 336, is used to extract the lighter REEs from the heavier REEs. Yttrium is then extracted from the heavier REEs with thiocyanate salts. The remaining heavy RREs are further separated using various treatments of Aliquat 336 and nitrate salts. == See also ==