Structural control of ionic conductivity in LiAlSi2O6 and LiAlSi4O10 glasses and single crystals

Welsch, Anna-Maria; Behrens, Harald; Ross, Sebastian; Murawski, Dawid

doi:10.1524/zpch.2012.0230

Cited by 18 publications

(14 citation statements)

References 44 publications

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“…Although this evaluation is not a quantitative analysis, the emission intensity of LiAlSi 4 O 10 was very low compared with that of LiAlSi 2 O 6 . In neutron detectors, the energy deposited is typically 4.8 MeV in 6 Li-containing materials based on the 6 Li(n,α) 3 H reaction, and a higher emission intensity can be expected. Figure 7 shows scintillation decay time profiles of LiAlSi 2 O 6 and LiAlSi 4 O 10 .…”

Section: Resultsmentioning

confidence: 99%

“…As scintillation detectors, they can be used as thermal neutron detectors since they contain Li in their chemical composition. Owing to the limited 3 He gas supply, (3,4) (6) Sometimes, the former was studied for optically stimulated luminescence (OSL (7) ) or thermally stimulated luminescence (TSL (8) ) dosimeter applications. (9)(10)(11) On the other hand, there have been no reports on the luminescence properties of LiAlSi 4 O 10 .…”

Section: Introductionmentioning

confidence: 99%

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Scintillation and Dosimeter Properties of LiAlSi2O6 and LiAlSi4O10 Crystals

Yanagida

Fujimoto

Koshimizu

et al. 2017

Sensors and Materials

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Optical, scintillation, optically stimulated luminescence, and thermally stimulated luminescence properties of nondoped LiAlSi 2 O 6 and LiAlSi 4 O 10 mineral crystals were investigated. The photoluminescence emission wavelengths of LiAlSi 2 O 6 and LiAlSi 4 O 10 were 300-500 and 350-600 nm, respectively, and the scintillation emission wavelengths were similar. Under vacuum ultraviolet photon excitation at a synchrotron facility (UVSOR), excitation bands of LiAlSi 2 O 6 and LiAlSi 4 O 10 appeared at around 150 and 180 nm, respectively. The decay lifetime of LiAlSi 2 O 6 was on the nanosecond order while that of LiAlSi 4 O 10 was on the millisecond order for both photoluminescence and scintillation. Both samples showed thermally stimulated luminescence, and LiAlSi 4 O 10 had a higher sensitivity. When we investigated optically stimulated luminescence, LiAlSi 4 O 10 exhibited a detectable signal, while we could not observe a signal in LiAlSi 2 O 6 .

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Scintillation and Dosimeter Properties of LiAlSi2O6 and LiAlSi4O10 Crystals

Yanagida

Fujimoto

Koshimizu

et al. 2017

Sensors and Materials

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“…However, the temperature corresponding to the centre of the conductivity plateau was always determined with a precision better than AE1 K. The accuracy of conductivity measurements was verified to be better than AE0.10 log units by comparison of conductivity data of LiAlSi 2 O 6 glasses with literature data. 15 …”

Section: Impedance Spectroscopymentioning

confidence: 99%

“…Compared to crystals of the same composition (LiAlSi 2 O 6 : a-and b-spodumene; LiAlSi 4 O 10 : petalite) the mobility of lithium in the glasses is decreased by several orders of magnitude. 15 Denser packing in the crystalline phases reduces, on one hand, the number of possible sites, which can host lithium ions and may affect, on the other hand, the energy barrier for transition from one site to the other. A vacancycontrolled transport mechanism was proposed for the densely packed a-spodumene structure, while in the open framework the structure of petalite formation and movement of Li interstitials were assumed to be the dominant mechanism for charge transfer.…”

Section: Implications For Lithium Migration Paths and Glass Structuresmentioning

confidence: 99%

“…A vacancycontrolled transport mechanism was proposed for the densely packed a-spodumene structure, while in the open framework the structure of petalite formation and movement of Li interstitials were assumed to be the dominant mechanism for charge transfer. 15 However, for alkali silicate glasses there is strong evidence for an unmixing of structural units on the nanometre scale (see Discussion in Bauer et al). 3 A separation of Li-rich regions within a Si-rich matrix was observed using different experimental methods 1,5,[54][55][56][57]59,60 as well as in theoretical modelling.…”

Section: Implications For Lithium Migration Paths and Glass Structuresmentioning

confidence: 99%

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Lithium conductivity in glasses of the Li₂O–Al₂O₃–SiO₂system

Ross

Welsch

Behrens

2015

Phys. Chem. Chem. Phys.

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To improve the understanding of Li-dynamics in oxide glasses, i.e. the effect of [AlO 4 ] À tetrahedra and non-bridging oxygens on the potential landscape, electrical conductivity of seven fully polymerized and partly depolymerized lithium aluminosilicate glasses was investigated using impedance spectroscopy (IS).Lithium is the only mobile particle in these materials. Data derived from IS, i.e. activation energies, preexponential factors and diffusivities for lithium, are interpreted in light of Raman spectroscopic analyses of local structures in order to identify building units, which are crucial for lithium dynamics and migration. In polymerized glasses (compositional join LiAlSiO 4 -LiAlSi 4 O 10 ) the direct current (DC) electrical conductivity continuously increases with increasing lithium content while lithium diffusivity is not affected by the Al/Si ratio in the glasses. Hence, the increase in electrical conductivity can be solely assigned to lithium concentration in the glasses. An excess of Li with respect to Al, i.e. the introduction of non-bridging oxygen into the network, causes a decrease in lithium mobility in the glasses. Activation energies in polymerized glasses (66 to 70 kJ mol À1 ) are significantly lower than those in depolymerized networks (76 to 78 kJ mol À1 ) while pre-exponential factors are nearly constant across all compositions. Comparison of the data with results for lithium silicates from the literature indicates a minimum in lithium diffusivity for glasses containing both aluminium tetrahedra and non-bridging oxygens. The findings allow a prediction of DC conductivity for a large variety of lithium aluminosilicate glass compositions.

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Ionic conductivity in single-crystal LiAlSi2O6: influence of structure on lithium mobility

Welsch

Murawski

Prekajski³

et al. 2015

Phys Chem Minerals

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Structural control of ionic conductivity in LiAlSi₂O₆ and LiAlSi₄O₁₀ glasses and single crystals

Cited by 18 publications

References 44 publications

Scintillation and Dosimeter Properties of LiAlSi2O6 and LiAlSi4O10 Crystals

Scintillation and Dosimeter Properties of LiAlSi2O6 and LiAlSi4O10 Crystals

Lithium conductivity in glasses of the Li₂O–Al₂O₃–SiO₂system

Ionic conductivity in single-crystal LiAlSi2O6: influence of structure on lithium mobility

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Structural control of ionic conductivity in LiAlSi2O6 and LiAlSi4O10 glasses and single crystals

Cited by 18 publications

References 44 publications

Scintillation and Dosimeter Properties of LiAlSi2O6 and LiAlSi4O10 Crystals

Scintillation and Dosimeter Properties of LiAlSi2O6 and LiAlSi4O10 Crystals

Lithium conductivity in glasses of the Li2O–Al2O3–SiO2system

Ionic conductivity in single-crystal LiAlSi2O6: influence of structure on lithium mobility

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Structural control of ionic conductivity in LiAlSi₂O₆ and LiAlSi₄O₁₀ glasses and single crystals

Lithium conductivity in glasses of the Li₂O–Al₂O₃–SiO₂system