First-Principles Study on Structural Properties and 4f 鈫?5d Transitions of Locally Charge-Compensated Ce3+ in CaF2

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• 作者：Lixin Ning ; Changbao Wu ; Lanlan Li ; Lihua Lin ; Changkui Duan ; Yongfan Zhang ; Luis Seijo
• 刊名：The Journal of Physical Chemistry C
• 出版年：2012
• 出版时间：August 30, 2012
• 年：2012
• 卷：116
• 期：34
• 页码：18419-18426
• 全文大小：361K
• 年卷期：v.116,no.34(August 30, 2012)
• ISSN：1932-7455

文摘

The structural properties and 4f 鈫?5d transitions of Ce³⁺ in CaF₂, with local charge compensation by an interstitial fluoride (F_i鈥? or an oxygen substitution for fluoride (O_F鈥?, have been studied using the density functional theory (DFT) within the supercell model and the wave function-based embedded cluster calculations, respectively. The DFT results indicate that the incorporation of locally charge-compensated Ce³⁺ in CaF₂ induces an anisotropic distortion of the structure around the dopant site. On the basis of the DFT-optimized structures, the Ce-centered embedded clusters are constructed, on which the wave function-based CASSCF/CASPT2/RASSI鈥揝O calculations at the spin鈥搊rbit level are performed to obtain the Ce³⁺ 4f¹ and 5d¹ level energies. The calculated 4f鈥?d transition energies and relative intensities are in good agreement with available experimental results. From the present calculations, we conclude that the 5d¹ level missing in the low-temperature absorption spectrum of the tetragonal Ce center with F_i鈥?compensation is the second-lowest one, and the absorption at this level is overshadowed by an adjacent cluster band usually assigned to Ce clusters and thus was not observed in experiments. We also assign the two closely spaced absorption lines around 3118.5 脜 observed in experiments to the lowest two quasi-degenerated 4f 鈫?5d transitions of the monoclinic center with F_i鈥?compensation rather than those of the trigonal center as proposed earlier. Finally, we analyze the structural and electronic reasons for the large reduction (2000 cm^鈥?) of the lowest 4f 鈫?5d transition energy from a F_i鈥?to a nearest-neighbor O_F鈥?compensation, in terms of the changes in the centroid energy difference and crystal-field splitting.