7Li NMR and Two-Dimensional Exchange Study of Lithium Dynamics in Monoclinic Li3V2(PO4)3

Cahill, Lindsay S.; Chapman, Rebecca P.; Britten, James F.; Goward, Gillian R.

doi:10.1021/jp057015+

Cited by 124 publications

(135 citation statements)

References 35 publications

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“…This Letter emphasizes the direct, i.e., model-independent, measurement of ultraslow Li jumps in TiS 2 with rates from the kHz to the sub-Hz range by 7 Li spin-alignment echo (SAE) NMR. The method was originally developed for deuterons by Spiess [2] and, quite recently, successfully applied also to spin-3=2 nuclei, like 9 Be [3] and 7 Li [4]. Recording two-time 7 Li SAE singleparticle correlation functions enables direct access to Li jump rates.…”

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confidence: 85%

“…To our knowledge, only few Li 2D NMR experiments have been performed until now; see, e.g., Refs. [5][6][7].Here, polycrystalline layer-structured Li x TiS 2 with x 0:7 was chosen as a unique model substance for a comprehensive investigation of 2D Li diffusion. For the first time, jump rates from 7 Li SAE NMR with values down to the sub-Hz range were systematically compared to those obtained from classical 7 Li NMR relaxation probing Li diffusion on a much shorter time scale with jump rates up to the GHz range.…”

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confidence: 99%

“…The method is applicable at relatively low temperatures, so that it is expected to become one of the leading techniques for the study of Li dynamics in numerous, possibly heat-sensitive Li conductors. Compared to two-dimensional (2D) Li exchange NMR [5], which is also capable to measure very slow Li jumps directly in the present sense, 7 Li SAE NMR is much less time consuming and applicable to a much broader class of crystalline and even amorphous materials. Furthermore, a much larger dynamic range can be investigated which is about four decades in the present study.…”

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From Ultraslow to Fast Lithium Diffusion in the 2D Ion ConductorLi0.7TiS2Probed Directly by Stimulated-Echo NMR and Nuclear Magnetic Relaxation

2006

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7 Li stimulated-echo NMR and classical relaxation NMR techniques are jointly used for the first time for a comprehensive investigation of Li diffusion in layer-structured Li 0:7 TiS 2 . One single 2D Li diffusion process was probed over a dynamic range of almost 10 orders of magnitude. So far, this is the largest dynamic range being measured by 7 Li NMR spectroscopy directly, i.e., without the help of a specific theoretical model. The jump rates obey a strict Arrhenius law, determined by an activation energy of 0:411 eV and a preexponential factor of 6:31 10 12 s ÿ1 , and range between 1 10 ÿ1 s ÿ1 and 7:8 10 8 s ÿ1 (148-510 K). Ultraslow Li jumps in the kHz to sub-Hz range were measured directly by recording 7 Li spin-alignment correlation functions. The temperature and, in particular, the frequency dependence of the relaxation rates fully agree with results expected for 2D diffusion. DOI: 10.1103/PhysRevLett.97.065901 PACS numbers: 66.30.ÿh, 76.60.Lz, 82.47.Aa In the last decade the investigation of solid Li ion conductors has developed into a vast research topic with several hundreds of papers per year. The reason is that Li ion conductors serve both for applications in, e.g., batteries with high energy density and for fundamental studies of the lightest ion besides hydrogen concerning mechanisms, influence of dimensionality, or quantum effects in diffusion. Unfortunately, due to the lack of a suitable radioactive Li isotope, the standard tracer diffusion technique is not applicable. Alternatively, Li diffusion can be probed on different time scales by nuclear magnetic resonance (NMR) techniques [1]. This Letter emphasizes the direct, i.e., model-independent, measurement of ultraslow Li jumps in TiS 2 with rates from the kHz to the sub-Hz range by 7 Li spin-alignment echo (SAE) NMR. The method was originally developed for deuterons by Spiess [2] and, quite recently, successfully applied also to spin-3=2 nuclei, like 9 Be [3] and 7 Li [4]. Recording two-time 7 Li SAE singleparticle correlation functions enables direct access to Li jump rates. The method is applicable at relatively low temperatures, so that it is expected to become one of the leading techniques for the study of Li dynamics in numerous, possibly heat-sensitive Li conductors. Compared to two-dimensional (2D) Li exchange NMR [5], which is also capable to measure very slow Li jumps directly in the present sense, 7 Li SAE NMR is much less time consuming and applicable to a much broader class of crystalline and even amorphous materials. Furthermore, a much larger dynamic range can be investigated which is about four decades in the present study. Two-dimensional NMR experiments can be carried out only if a direct Li exchange process becomes visible in the 2D spectra. To our knowledge, only few Li 2D NMR experiments have been performed until now; see, e.g., Refs. [5][6][7].Here, polycrystalline layer-structured Li x TiS 2 with x 0:7 was chosen as a unique model substance for a comprehensive investigation of 2D Li diffusion. For the first time, jump...

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From Ultraslow to Fast Lithium Diffusion in the 2D Ion ConductorLi0.7TiS2Probed Directly by Stimulated-Echo NMR and Nuclear Magnetic Relaxation

2006

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“…In particular, the investigation of Li dynamics over a wide length scale turns out to be highly important to understand the underlying structure-property relationships governing ion transport in materials being relevant for battery applications [5][6][7][8][9][10][11][12][13][14][15]. For instance, fast ion conductors are needed to develop powerful all-solid-state lithium-ion batteries which are regarded to play a key role in the development of new energy storage systems [16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Studying Li Dynamics in a Gas-Phase Synthesized Amorphous Oxide by NMR and Impedance Spectroscopy

Epp¹,

Brünig

Binnewies

et al. 2012

Zeitschrift Für Physikalische Chemie

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Li Diffusion / Solid State NMR / Impedance Spectroscopy / Non-Stoichiometric CompoundsLi diffusion parameters of a structurally disordered Li-Al-Si-oxide prepared by gas-phase synthesis were complementarily investigated by both time-domain NMR techniques and impedance spectroscopy. The first include 7 Li NMR spin-lattice relaxation (SLR) measurements in the laboratory as well as in the rotating frame of reference. An analysis of variable-temperature NMR line widths point to an activation energy E a of approximately 0.6 eV. The value is confirmed by rotating-frame SLR NMR data recorded at approximately 11 kHz. Above room temperature the low-temperature flank of a diffusion-induced rate peak shows up which can be approximated by an Arrhenius law yielding E a = 0.56(1) eV. This is in very good agreement with the result obtained from 7 Li spin-alignment echo (SAE) NMR being sensitive to even slower Li dynamics. For comparison, dc-conductivity measurements, probing long-range motions, yield E a = 0.8 eV. Interestingly, lowtemperature SAE NMR decay rates point to localized Li motions being characterized with a very small activation energy of only 0.09 eV.

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“…Furthermore, stimulated echo NMR allows the measurement of extremely slow Li jumps with rates in the kHz to sub-Hz range. Recently, also 2D exchange 3 6 Li and 7 Li NMR experiments were used for the study of Li jump rates in the kHz range very successfully [10][11][12]. To our knowledge, so far only these few magic angle spinning (MAS) 2D exchange NMR experiments have been carried out to detect Li jumps between crystallographic distinct sites.…”

Section: Introductionmentioning

confidence: 99%

New prospects in studying Li diffusion—two-time stimulated echo NMR of spin-3/2 nuclei

Wilkening

Heitjans

2006

Solid State Ionics

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The measurement of diffusion parameters like activation energies and translational jump rates of small cations plays a key role in materials science. Especially the in-depth investigation of Li diffusion in ionic conductors is of great interest, because suitable ionic conductors are needed for, e. g., the development of new secondary ion battery systems. As the standard tracer method is not applicable to study Li diffusion due to the lack of a suitable radioactive isotope, Li diffusion is alternatively probed by solid state NMR techniques. With the different NMR methods being available, diffusion processes can be studied on different length-and time-scales. In the present paper we use two-time spin-alignment echo (SAE) NMR for the direct, i. e., model independent, measurement of extremely small translational Li jump rates. To this end, different crystalline and glassy ion conductors like Li x TiS 2 , Li 4 SiO 4 as well as LiNbO 3 served as model substances to reveal the special features of this technique. SAE-NMR, which was originally developed for deuterons, has also been applied in a few cases to spin-3/2 nuclei, like 7 Li, before. The corresponding correlation functions yield not only information about diffusion parameters but also about geometric properties of the diffusion pathways, making SAE NMR a powerful method which complements well-established NMR techniques.

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⁷Li NMR and Two-Dimensional Exchange Study of Lithium Dynamics in Monoclinic Li₃V₂(PO₄)₃

Cited by 124 publications

References 35 publications

From Ultraslow to Fast Lithium Diffusion in the 2D Ion ConductorLi0.7TiS2Probed Directly by Stimulated-Echo NMR and Nuclear Magnetic Relaxation

From Ultraslow to Fast Lithium Diffusion in the 2D Ion ConductorLi0.7TiS2Probed Directly by Stimulated-Echo NMR and Nuclear Magnetic Relaxation

Studying Li Dynamics in a Gas-Phase Synthesized Amorphous Oxide by NMR and Impedance Spectroscopy

New prospects in studying Li diffusion—two-time stimulated echo NMR of spin-3/2 nuclei

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