An actinide element incorporated in

An actinide element incorporated in a crystalline ceramic can
undergo a radioactive decay process during which it may
(depending upon the decay process) transform into a new radionuclide
by releasing a high-energy a-particle [14]. Because of this
decay, the crystalline host matrix could experience structural
damage from the recoil energy associated with the daughter
product radionuclide and/or from the highly energetic a-particle
[14]. Therefore, an issue surrounding actinide containing crystalline
ceramics is the tendency of these materials to undergo a radiationinduced
crystalline to amorphous transition in a process called
metamiction [4,14,15]. This process can have an adverse effect on
the chemical durability of the wasteform (i.e., an increase in the
leach rate of the sequestered elements) [5,16]. This transition can
also be accompanied by a swelling of the wasteform [4,5,14e19].
Naturally occurring mineral samples of monazite and xenotime are
known to contain significant amounts of UO2 and ThO2 [6,20].
Despite the presence of radioactive U and Th, the mineral monazite,
in particular, has been observed to maintain its structural integrity
over a geological timescale and it is because of this resistance to
radiation-induced structural damage that monazite-type ceramics
have been proposed as a solid-state repository for actinide elements
[1,21,22]. On the other hand, the structural stability of the amorphous regions in damaged monazite samples under the influence
of an electron beam [27]. A theoretical study of the radiation
resistance of xenotime (YPO4) by Urusov et al. shed light on
the ability of recoil atoms to bring about a cascade of atomic displacements
in this structure [23]. Immediately after the creation of
a cascade of atomic displacements, some of the displaced atoms
returned to their original crystallographic positions which led to
the partial recovery of the xenotime structure [23].