Band Gap Calculations for Thorium‐Doped LiCAF

Pimon, Martin; Mohn, P.; Schumm, Thorsten

doi:10.1002/adts.202200185

Cited by 3 publications

(2 citation statements)

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“…Presently, the reported research attempts on solid-state nuclear clock materials mainly include Th:LiF, Th:CaF 2 , Th:LiCaAlF 6 /LiSrAlF 6 , and Th:MgF 2 , − among which, Th:CaF 2 single crystal can easily achieve high concentration doping, because its cation radius and electronegativity are very close to Th ions. In addition, it has good VUV transmittance and low background luminescence in the nuclear transition band, making it a very promising solid nuclear clock material. − However, according to the latest report of Beeks et al, the VUV transmittance of their highly doped 232 Th:CaF 2 crystals with doping concentrations of 4.0 × 10 19 and 2.6 × 10 20 cm –3 are ∼35% and ∼5% at 150 nm, respectively.…”

Section: Introductionmentioning

confidence: 99%

Structures and Properties of High-Concentration Doped Th:CaF₂ Single Crystals for Solid-State Nuclear Clock Materials

Gong,

Tao,

Zhao

et al. 2024

Inorg. Chem.

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Thorium-doped vacuum ultraviolet (VUV) transparent crystals is a promising candidate for establishing a solid-state nuclear clock. Here, we report the research results on highconcentration doping of 232 Th:CaF 2 single crystals. The structures, defects, and VUV transmittance performances of highly doped Th:CaF 2 crystals are investigated by theoretical and experimental methods. The defect configurations formed by Th and the charge compensation mechanism (Ca vacancy or interstitial F atoms) located at its first nearest neighbor position are mainly considered and studied. The preferred defect configuration is identified according to the doping concentration dependence of structural changes caused by the defects and the formation energies of the defects at different Ca or F chemical potentials. The cultivated Th:CaF 2 crystals maintain considerable high VUV transmittance levels while accommodating high doping concentrations, showcasing an exceptional comprehensive performance. The transmittances of 1-mm-thick samples with doping concentrations of 1.91 × 10 20 and 2.76 × 10 20 cm −3 can reach ∼62% and 53% at 150 nm, respectively. The VUV transmittance exhibits a weak negative doping concentration dependence. The system factors that may cause distortion and additional deterioration of the VUV transmittance are discussed. Balancing and controlling the impacts of various factors will be of great significance for fully exploiting the advantages of Th:CaF 2 and other Th-doped crystals for a solidstate nuclear optical clock.

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Section: Introductionmentioning

confidence: 99%

Structures and Properties of High-Concentration Doped Th:CaF₂ Single Crystals for Solid-State Nuclear Clock Materials

Gong,

Tao,

Zhao

et al. 2024

Inorg. Chem.

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“…[2] Currently, Th-doped or Th-based crystals reported experimentally or theoretically mainly include NaYF 4 , LiYF 4 , LiCaAlF 6 , Na 2 ThF 6 , LiSrAlF 6 , CaF 2 , and MgF 2 , most of which used 232 Th as a dopant, while only LiSrAlF 6 , MgF 2 , and CaF 2 crystals used 229 Th. [4,5,[9][10][11][12][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30] Because of extranuclear electron nature determines the chemical properties of elements, the 232 Th and 229 Th can be considered to have the same chemical properties; therefore, 232 Th, which is very low radioactive and easy to obtain, was used as a dopant in most experimental studies of host materials, while 229 Th, which is highly radioactive and difficult to obtain, was used more in the formal study of nuclear spectroscopy experiments. Certainly, if 232 Th can be converted to 229 Th by means of a 232 Th(p,p3n) 229 Th light-ion-induced fusion-evaporation reaction, it will greatly promote the research and development of 229Th -doped crystals.…”

Section: Introductionmentioning

confidence: 99%

Thorium‐Doped Lithium Fluoride Single Crystal: A Potential Promising Candidate for Solid State Nuclear Optical Clock Materials

Gong

Zhao

Tao

et al. 2023

Advanced Optical Materials

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The solid‐state nuclear optical clock based on 229Th‐doped crystal has great advantages in frequency stability, excitation and detection of nuclear transition, miniaturization, commercialization, and spaceborne ability of nuclear optical clock. Here, the potential of LiF crystal as a host for Th ions is predicted by theoretical calculation, and on this basis, the Th:LiF crystal is successfully grown experimentally for the first time. The theoretical results demonstrate that although the challenges of charge nonconservation and ion radius mismatch between Li+ and Th4+ ions exist, effective doping of thorium can still be achieved via energetically favorable charge compensation mechanisms in an F‐rich environment, and the transmittance of Th:LiF crystal in nuclear transition band will only have a slight decrease, smaller than that of pure LiF crystal. The experimental results prove that the doping concentration of Th:LiF crystal can reach about 8.3 × 1018 cm−3 and the transmittances of 1 mm thick Th:LiF and pure LiF crystal samples grown in similar conditions are ≈68% and 72% at 152.7 nm, respectively. The Th:LiF crystal with high doping concentration, high transmittance, and low background luminescence is expected to be a promising candidate for solid‐state nuclear optical clock materials.

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Feasibility and potential of a thorium-doped barium-lithium-fluoride single crystal as a candidate for solid-state nuclear optical clock material

Gong,

Tao,

et al. 2024

Phys. Rev. A

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Band Gap Calculations for Thorium‐Doped LiCAF

Cited by 3 publications

References 37 publications

Structures and Properties of High-Concentration Doped Th:CaF₂ Single Crystals for Solid-State Nuclear Clock Materials

Structures and Properties of High-Concentration Doped Th:CaF₂ Single Crystals for Solid-State Nuclear Clock Materials

Thorium‐Doped Lithium Fluoride Single Crystal: A Potential Promising Candidate for Solid State Nuclear Optical Clock Materials

Feasibility and potential of a thorium-doped barium-lithium-fluoride single crystal as a candidate for solid-state nuclear optical clock material

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Band Gap Calculations for Thorium‐Doped LiCAF

Cited by 3 publications

References 37 publications

Structures and Properties of High-Concentration Doped Th:CaF2 Single Crystals for Solid-State Nuclear Clock Materials

Structures and Properties of High-Concentration Doped Th:CaF2 Single Crystals for Solid-State Nuclear Clock Materials

Thorium‐Doped Lithium Fluoride Single Crystal: A Potential Promising Candidate for Solid State Nuclear Optical Clock Materials

Feasibility and potential of a thorium-doped barium-lithium-fluoride single crystal as a candidate for solid-state nuclear optical clock material

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Structures and Properties of High-Concentration Doped Th:CaF₂ Single Crystals for Solid-State Nuclear Clock Materials

Structures and Properties of High-Concentration Doped Th:CaF₂ Single Crystals for Solid-State Nuclear Clock Materials