A theoretical study of the defect formation (vacancy, interstitial and Frenkel

defects) energy, and vacancy migration energy in calcium fluoride was presented.

Calculations were conducted using the ab initio method with the plane-wave

pseudopotential and molecular-dynamics simulation to determine the energetic and

defect properties of the CaF2 crystal. For cation and anion vacancies, the relaxed

vacancy formation energies were calculated to be 13.75 and 8.34eV, respectively.

It was also found that only the octahedral positions were stable sites for Ca and F

interstitial atoms. For cation the second nearest neighbour Frenkel defects were

found to be stable within the simulation time (5ps) and the defect formation energy

was estimated to be 9.3eV, while the third nearest neighbour Frenkel defects for

anion were stable and the formation energy was only 2.49eV. The results were in

agreement with Ure’s experimental results. The migration energy of cation vacancy

in the direction of <110> was lower than that of <100> (3.93eV versus 4.62eV),

suggesting <110> was the most likely path for Ca vacancies to migrate, while most

anion vacancies may diffuse in the <100> directions due to a very low (0.33eV)

anion migration energy in the direction. The data were useful for better

understanding the formation of nano-scale void superlattice in calcium fluoride

under electron beam irradiation.

Computer Simulation Study of Defect Formation and Migration Energy in Calcium

Fluoride. K.D.Li, H.Y.Xiao, L.M.Wang: Nuclear Instruments and Methods in

Physics Research B, 2008, 266[12-13], 2698-701