Structural Origin of the Optical Properties of Ag-Doped Fluorophosphate and Sulfophosphate Glasses

Zhou, Ru; Calahoo, Courtney; Ding, Yicong; Yang, Xu; Romao, Carl P.; Wondraczek, Lothar

doi:10.1021/acs.jpcb.0c09375

Cited by 7 publications

(35 citation statements)

References 95 publications

(225 reference statements)

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“…For all glasses, the observed chemical shift values of the four lines were approximately −22, −12, −3, and 7 ppm. Though the Al–O–P bond is more ionic in nature, the chemical shift difference between Q P 1 (1 Al ) and Q P 2 (0 Al ) is very small compared to the difference between Q P 1 (0 Al ) and Q P 1 (1 Al ) . This indicates the difficulty in assigning the deconvoluted peaks of 31 P MAS-NMR to more specific structural units.…”

Section: Resultsmentioning

confidence: 98%

“…Though the Al−O−P bond is more ionic in nature, the chemical shift difference between Q P 1 (1Al) and Q P 2 (0Al) is very small compared to the difference between Q P 1 (0Al) and Q P 1 (1Al). 38 This indicates the difficulty in assigning the deconvoluted peaks of 31 P MAS-NMR to more specific structural units. Therefore, we assume that these deconvoluted lines could be a mixture of several Q P n (mAl) units.…”

Section: Mas-nmrmentioning

confidence: 99%

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Ionic Conductivity of Na₃Al₂P₃O₁₂ Glass Electrolytes—Role of Charge Compensators

et al. 2021

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In glasses, a sodium ion (Na+) is a significant mobile cation that takes up a dual role, that is, as a charge compensator and also as a network modifier. As a network modifier, Na+ cations modify the structural distributions and create nonbridging oxygens. As a charge compensator, Na+ cations provide imbalanced charge for oxygen that is linked between two network-forming tetrahedra. However, the factors controlling the mobility of Na+ ions in glasses, which in turn affects the ionic conductivity, remain unclear. In the current work, using high-fidelity experiments and atomistic simulations, we demonstrate that the ionic conductivity of the Na3Al2P3O12 (Si0) glass material is dependent not only on the concentration of Na+ charge carriers but also on the number of charge-compensated oxygens within its first coordination sphere. To investigate, we chose a series of glasses formulated by the substitution of Si for P in Si0 glass based on the hypothesis that Si substitution in the presence of Na+ cations increases the number of Si–O–Al bonds, which enhances the role of Na as a charge compensator. The structural and conductivity properties of bulk glass materials are evaluated by molecular dynamics (MD) simulations, magic angle spinning-nuclear magnetic resonance, Raman spectroscopy, and impedance spectroscopy. We observe that the increasing number of charge-imbalanced bridging oxygens (BOs) with the substitution of Si for P in Si0 glass enhances the ionic conductivity by an order of magnitudefrom 3.7 × 10–8 S.cm–1 to 3.3 × 10–7 S.cm–1 at 100 °C. By rigorously quantifying the channel regions in the glass structure, using MD simulations, we demonstrate that the enhanced ionic conductivity can be attributed to the increased connectivity of Na-rich channels because of the increased charge-compensated BOs around the Na atoms. Overall, this study provides new insights for designing next-generation glass-based electrolytes with superior ionic conductivity for Na-ion batteries.

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Section: Resultsmentioning

confidence: 98%

Section: Mas-nmrmentioning

confidence: 99%

Ionic Conductivity of Na₃Al₂P₃O₁₂ Glass Electrolytes—Role of Charge Compensators

et al. 2021

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“…As discussed previously, confirmation of the fluorine content is further complicated by its low atomic mass, leading to a comparably large error on analyzed fractions. 17,41 The refractive index n d was determined on a Pulfrich refractometer with a precision of ±0.0005. We used a doublebeam spectrophotometer (Cary5000, Agilent) with a spectral resolution of 1 nm to record the optical absorption from 800 to 200 nm.…”

Section: Methodsmentioning

confidence: 99%

“…3,16 In a previous report, we discussed Ag doping in fluorophosphate (PF) and sulfophosphate (PS) glass matrices. 17 Ag + −RE interactions without the obfuscation from stronger surface plasmon resonance (SPR) of Ag nanoparticles. Furthermore, these investigations revealed the importance of the glass matrix and nearest-neighbor interactions in determining the optical properties of Ag + .…”

Section: Introductionmentioning

confidence: 99%

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Role of Ag⁺ Ions in Determining Ce³⁺ Optical Properties in Fluorophosphate and Sulfophosphate Glasses

et al. 2021

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Understanding the interactions among dopant species and the role of the host lattice is of fundamental importance for the chemical formulation of optically active glasses. Here, we consider the archetypal dopant pair of Ag–Ce in complex fluorophosphate (PF) and sulfophosphate (PS) matrices, in which variable bonding environments and ligand selectivity exert distinct effects on dopant properties. The addition of Ag+ to PF glasses blue-shifts the ultraviolet (UV) cutoff wavelength of Ce3+ and enhances its photoluminescence (PL) intensity. In PS matrices, the exact opposite effect is observed: red-shifting the UV cutoff and lowering the PL intensity. No Ag–Ag pairs or cluster species were found in either matrix material; however, in PS, such clustering could be triggered by secondary broad-band UV–visible irradiation. The optical properties of Ag–Ce-codoped glasses are a result of the ionocovalent character of the Ag+–O–Ce3+ bond, the cross-relaxation process between Ag+ and Ce3+, and the redox ratio of Ce3+/Ce4+. In the PF glasses, the enhancement of the Ce3+ PL intensity is due to energy transfer from Ag+ to Ce3+ and a redox shift from Ce4+ to Ce3+. The more covalent Ag+–O–Ce3+ interactions in the PS series decrease the Ce3+/Ce4+ ratio. Moreover, photoinduced Ag clustering is facilitated in the more covalent environment, which indicates that glasses commonly used for Ag nanoparticle formation, such as silicate glasses, also possess more covalent Ag+–O bonding.

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Understanding the sodium-ion dynamics in NASICON (Na3Al2P3O12) glass containing NaF: Scaling of electrical conductivity spectra

Mandal

Chakraborty

Annapurna

et al. 2021

Journal of Alloys and Compounds

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Structural Origin of the Optical Properties of Ag-Doped Fluorophosphate and Sulfophosphate Glasses

Cited by 7 publications

References 95 publications

Ionic Conductivity of Na₃Al₂P₃O₁₂ Glass Electrolytes—Role of Charge Compensators

Ionic Conductivity of Na₃Al₂P₃O₁₂ Glass Electrolytes—Role of Charge Compensators

Role of Ag⁺ Ions in Determining Ce³⁺ Optical Properties in Fluorophosphate and Sulfophosphate Glasses

Understanding the sodium-ion dynamics in NASICON (Na3Al2P3O12) glass containing NaF: Scaling of electrical conductivity spectra

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Structural Origin of the Optical Properties of Ag-Doped Fluorophosphate and Sulfophosphate Glasses

Cited by 7 publications

References 95 publications

Ionic Conductivity of Na3Al2P3O12 Glass Electrolytes—Role of Charge Compensators

Ionic Conductivity of Na3Al2P3O12 Glass Electrolytes—Role of Charge Compensators

Role of Ag+ Ions in Determining Ce3+ Optical Properties in Fluorophosphate and Sulfophosphate Glasses

Understanding the sodium-ion dynamics in NASICON (Na3Al2P3O12) glass containing NaF: Scaling of electrical conductivity spectra

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Product

Resources

About

Ionic Conductivity of Na₃Al₂P₃O₁₂ Glass Electrolytes—Role of Charge Compensators

Ionic Conductivity of Na₃Al₂P₃O₁₂ Glass Electrolytes—Role of Charge Compensators

Role of Ag⁺ Ions in Determining Ce³⁺ Optical Properties in Fluorophosphate and Sulfophosphate Glasses