Determining the Hyperfine Structure and Clock Transitions for Kramers Rare-Earth Ions in a Crystal under a Magnetic Field: Beyond Spin Hamiltonian

Abstract: Clock transitions play an important role in extending the coherence time of rare-earth (RE) ion-doped crystals. It is still a challenge to accurately obtain the hyperfine structure of these crystals to determine their clock transitions and establish a proper solid-state quantum memory system. In this work, a nonspin-Hamiltonian method combining density functional theory (DFT)-based geometric optimization and effective Hamiltonian is utilized to obtain the hyperfine sublevels and clock transitions under an exte… Show more

“…The four emission bands around 978, 999, 1033, and 1074 nm can roughly be attributed to the 5 → 1, 5 → 2, 5 → 3, and 5 → 4 transitions, respectively. The sublevel positions of the 2 F 7/2 and 2 F 5/2 of Yb 3+ :YScSi 2 O 7 and those of Yb 3+ :Lu 2 Si 2 O 7 , reported are listed in Table .…”

“…In the SPM, the crystal field parameters B q k can be written as , Re B q k = A̅ k ( R 0 ) ∑ i false( R 0 R i false) t k K q k ( θ i , ϕ i ) / α k , q Im .25em B q k = A̅ k ( R 0 ) ∑ i false( R 0 R i false) t k K − q k ( θ i , ϕ i ) / α k , q where notation i means the i th ligand, A̅ k ( R 0 ) is the intrinsic crystal field parameter, R 0 is the reference distance between central and ligand ions and is taken as 2.4 Å, , R i is the distance between the doped ion and ligand i , K ± q k (θ i ,ϕ i ) is the purely geometric coefficient expressed in spherical polar coordinates as given in ref with polar angle θ i and azimuthal angle ϕ i of ligand i , t k is the power-law exponent, and α k , q is the conversion factor between the extended Stevens operator and Wybourne notation. For the Yb 3+ :YScSi 2 O 7 crystal, t 2 = 6, t 4 = 5...…”

“…17 In the Yb 3+ :YScSi 2 O 7 crystal, as discussed above, the average cation field strength CFS of Y 3+ / Sc 3+ is larger than that of Lu 3+ in Yb 3+ :Lu 2 Si 2 O 7 , which would lead to the finding that more electron cloud of the coordinated oxygen ion O 2− of Yb 3+ is polarized to Y 3+ /Sc 3+ . Therefore, the electrostatic and covalent interactions to Yb 3+ in YScSi 2 O 7 decrease, and the intrinsic crystal field parameters and ξ 4f of Yb 3+ :YScSi 2 O 7 are generally smaller than those of Yb 3+ :Lu 2 Si 2 O 7 33 whose intrinsic crystal field parameters and ξ 4f are A̅ 2 (R 0 ) = 401 cm −1 , A̅ 4 (R 0 ) = 61 cm −1 , A̅ 6 (R 0 ) = 14 cm −1 , and 2902 cm −1 , respectively.…”

“…For the Yb 3+ :YScSi 2 O 7 crystal, t 2 = 6, t 4 = 5, and t 6 = 6.1 were adopted for the power-law exponents t k as for Yb 3+ :Lu 2 Si 2 O 7 . 33 The Yb 3+ −O 2− distance R i can be estimated by the empirical relation 41…”

Growth, Elastic, Thermal, and Crystal Field Analysis of the Yb³⁺:YScSi₂O₇ Laser Crystal

“…The four emission bands around 978, 999, 1033, and 1074 nm can roughly be attributed to the 5 → 1, 5 → 2, 5 → 3, and 5 → 4 transitions, respectively. The sublevel positions of the 2 F 7/2 and 2 F 5/2 of Yb 3+ :YScSi 2 O 7 and those of Yb 3+ :Lu 2 Si 2 O 7 , reported are listed in Table .…”

“…In the SPM, the crystal field parameters B q k can be written as , Re B q k = A̅ k ( R 0 ) ∑ i false( R 0 R i false) t k K q k ( θ i , ϕ i ) / α k , q Im .25em B q k = A̅ k ( R 0 ) ∑ i false( R 0 R i false) t k K − q k ( θ i , ϕ i ) / α k , q where notation i means the i th ligand, A̅ k ( R 0 ) is the intrinsic crystal field parameter, R 0 is the reference distance between central and ligand ions and is taken as 2.4 Å, , R i is the distance between the doped ion and ligand i , K ± q k (θ i ,ϕ i ) is the purely geometric coefficient expressed in spherical polar coordinates as given in ref with polar angle θ i and azimuthal angle ϕ i of ligand i , t k is the power-law exponent, and α k , q is the conversion factor between the extended Stevens operator and Wybourne notation. For the Yb 3+ :YScSi 2 O 7 crystal, t 2 = 6, t 4 = 5...…”

“…17 In the Yb 3+ :YScSi 2 O 7 crystal, as discussed above, the average cation field strength CFS of Y 3+ / Sc 3+ is larger than that of Lu 3+ in Yb 3+ :Lu 2 Si 2 O 7 , which would lead to the finding that more electron cloud of the coordinated oxygen ion O 2− of Yb 3+ is polarized to Y 3+ /Sc 3+ . Therefore, the electrostatic and covalent interactions to Yb 3+ in YScSi 2 O 7 decrease, and the intrinsic crystal field parameters and ξ 4f of Yb 3+ :YScSi 2 O 7 are generally smaller than those of Yb 3+ :Lu 2 Si 2 O 7 33 whose intrinsic crystal field parameters and ξ 4f are A̅ 2 (R 0 ) = 401 cm −1 , A̅ 4 (R 0 ) = 61 cm −1 , A̅ 6 (R 0 ) = 14 cm −1 , and 2902 cm −1 , respectively.…”

“…For the Yb 3+ :YScSi 2 O 7 crystal, t 2 = 6, t 4 = 5, and t 6 = 6.1 were adopted for the power-law exponents t k as for Yb 3+ :Lu 2 Si 2 O 7 . 33 The Yb 3+ −O 2− distance R i can be estimated by the empirical relation 41…”

Growth, Elastic, Thermal, and Crystal Field Analysis of the Yb³⁺:YScSi₂O₇ Laser Crystal

“…4B, Table S3 †). Thus, the arrangement of the Yb(III) energy levels 60,61 facilitates efficient energy transfer from the triplet level of the complex 6 to the emitting level of Yb(III) ion in the complex 11 Yb . This finding is in agreement with the observed emission lifetime.…”

Organometallic Ir(iii) complexes: post-synthetic modification, photophysical properties and binuclear complex construction

Multiprocessing Quantum Computing through Hyperfine Couplings in Endohedral Fullerene Derivatives