Home > Research > Publications & Outputs > Variable-temperature O-17 NMR study of oxygen m...

Research

Links

Text available via DOI:

View graph of relations

Variable-temperature O-17 NMR study of oxygen motion in the anionic conductor Bi26Mo10O69

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Published

Standard

Variable-temperature O-17 NMR study of oxygen motion in the anionic conductor Bi26Mo10O69. / Holmes, Lesley; Peng, Luming; Heinmaa, Ivo et al.
In: Journal of Materials Chemistry, Vol. 20, No. 11, 01.06.2008, p. 3638-3648.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Holmes, L, Peng, L, Heinmaa, I, O'Dell, LA, Smith, ME, Vannier, R-N & Grey, CP 2008, 'Variable-temperature O-17 NMR study of oxygen motion in the anionic conductor Bi26Mo10O69', Journal of Materials Chemistry, vol. 20, no. 11, pp. 3638-3648. https://doi.org/10.1021/cm800351c

APA

Holmes, L., Peng, L., Heinmaa, I., O'Dell, L. A., Smith, M. E., Vannier, R-N., & Grey, C. P. (2008). Variable-temperature O-17 NMR study of oxygen motion in the anionic conductor Bi26Mo10O69. Journal of Materials Chemistry, 20(11), 3638-3648. https://doi.org/10.1021/cm800351c

Vancouver

Holmes L, Peng L, Heinmaa I, O'Dell LA, Smith ME, Vannier R-N et al. Variable-temperature O-17 NMR study of oxygen motion in the anionic conductor Bi26Mo10O69. Journal of Materials Chemistry. 2008 Jun 1;20(11):3638-3648. doi: 10.1021/cm800351c

Author

Holmes, Lesley ; Peng, Luming ; Heinmaa, Ivo et al. / Variable-temperature O-17 NMR study of oxygen motion in the anionic conductor Bi26Mo10O69. In: Journal of Materials Chemistry. 2008 ; Vol. 20, No. 11. pp. 3638-3648.

Bibtex

@article{611c9a682f3041f09a7bde634bbf34e1,
title = "Variable-temperature O-17 NMR study of oxygen motion in the anionic conductor Bi26Mo10O69",
abstract = "Variable-temperature O-17 NMR spectroscopy, spanning a temperature range from -238 to 1000 degrees C, has been used to investigate mechanisms for ionic conduction in Bi26Mo10O69, a material that contains both MoO42- tetrahedra and [Bi12O14](infinity)(8-) columns. Two O-17 NMR resonances are observed that are assigned to oxygen atoms in the MoO42- tetrahedra and in the [Bi12O14](infinity)(8-) columns. On the basis of the nutation curves for the two groups of resonances, extremely rapid, but local, reorientational motion of the MoO42- units occurs at -70 degrees C and above (with a frequency of >50 kHz), whereas the Bi-O oxygen ions are rigid in this temperature regime. This is confirmed by both an analysis of the line broadening of the MoO42- satellite transitions (under MAS) and the spin-lattice relaxation (T-1) times of these sites, the T-1 times indicating that the MoO42- reorientation rates rapidly increase, reaching > 100 MHz at 400 degrees C. Line narrowing of the MoO42- central-transition resonance indicates that exchange between the tetrahedral units, a motion required for long-range anionic conduction, is much slower, involving only jump rates of approximately 1 kHz at 200 degrees C. Both the changes in line width of the MoO42- resonance, and the jump in the T-1 times of the oxygen atoms in the [Bi12O14](infinity)(8-) columns at around the triclinic-monoclinic phase transition temperature (310 degrees C) are consistent with a mechanism for motion involving all the oxygen atoms. The predicted conductivity based on the [Bi-O] T-1 times is now of the order of that extracted from ac impedance measurements reported by Vannier et al. (J. Solid State Chem. 1996, 122, 394). On the basis of this detailed NMR analysis, we propose that motion at ambient temperatures primarily involves the MoO42- tetrahedral rotation: exchange between these sites is very slow. At higher temperatures (above 310 degrees C) the conduction process now appears to involve the oxygen atoms coordinated to Bi3+, in the [Bi12O14](infinity)(8-) columns, and most likely in the partially vacant O[19] site. The involvement of these sites allows for long-range conduction processes that do not involve concerted, multiple Mo-O bond breakages.",
author = "Lesley Holmes and Luming Peng and Ivo Heinmaa and O'Dell, {Luke A.} and Smith, {Mark E.} and Rose-Noelle Vannier and Grey, {Clare P.}",
year = "2008",
month = jun,
day = "1",
doi = "10.1021/cm800351c",
language = "English",
volume = "20",
pages = "3638--3648",
journal = "Journal of Materials Chemistry",
issn = "1364-5501",
publisher = "Royal Society of Chemistry",
number = "11",

}

RIS

TY - JOUR

T1 - Variable-temperature O-17 NMR study of oxygen motion in the anionic conductor Bi26Mo10O69

AU - Holmes, Lesley

AU - Peng, Luming

AU - Heinmaa, Ivo

AU - O'Dell, Luke A.

AU - Smith, Mark E.

AU - Vannier, Rose-Noelle

AU - Grey, Clare P.

PY - 2008/6/1

Y1 - 2008/6/1

N2 - Variable-temperature O-17 NMR spectroscopy, spanning a temperature range from -238 to 1000 degrees C, has been used to investigate mechanisms for ionic conduction in Bi26Mo10O69, a material that contains both MoO42- tetrahedra and [Bi12O14](infinity)(8-) columns. Two O-17 NMR resonances are observed that are assigned to oxygen atoms in the MoO42- tetrahedra and in the [Bi12O14](infinity)(8-) columns. On the basis of the nutation curves for the two groups of resonances, extremely rapid, but local, reorientational motion of the MoO42- units occurs at -70 degrees C and above (with a frequency of >50 kHz), whereas the Bi-O oxygen ions are rigid in this temperature regime. This is confirmed by both an analysis of the line broadening of the MoO42- satellite transitions (under MAS) and the spin-lattice relaxation (T-1) times of these sites, the T-1 times indicating that the MoO42- reorientation rates rapidly increase, reaching > 100 MHz at 400 degrees C. Line narrowing of the MoO42- central-transition resonance indicates that exchange between the tetrahedral units, a motion required for long-range anionic conduction, is much slower, involving only jump rates of approximately 1 kHz at 200 degrees C. Both the changes in line width of the MoO42- resonance, and the jump in the T-1 times of the oxygen atoms in the [Bi12O14](infinity)(8-) columns at around the triclinic-monoclinic phase transition temperature (310 degrees C) are consistent with a mechanism for motion involving all the oxygen atoms. The predicted conductivity based on the [Bi-O] T-1 times is now of the order of that extracted from ac impedance measurements reported by Vannier et al. (J. Solid State Chem. 1996, 122, 394). On the basis of this detailed NMR analysis, we propose that motion at ambient temperatures primarily involves the MoO42- tetrahedral rotation: exchange between these sites is very slow. At higher temperatures (above 310 degrees C) the conduction process now appears to involve the oxygen atoms coordinated to Bi3+, in the [Bi12O14](infinity)(8-) columns, and most likely in the partially vacant O[19] site. The involvement of these sites allows for long-range conduction processes that do not involve concerted, multiple Mo-O bond breakages.

AB - Variable-temperature O-17 NMR spectroscopy, spanning a temperature range from -238 to 1000 degrees C, has been used to investigate mechanisms for ionic conduction in Bi26Mo10O69, a material that contains both MoO42- tetrahedra and [Bi12O14](infinity)(8-) columns. Two O-17 NMR resonances are observed that are assigned to oxygen atoms in the MoO42- tetrahedra and in the [Bi12O14](infinity)(8-) columns. On the basis of the nutation curves for the two groups of resonances, extremely rapid, but local, reorientational motion of the MoO42- units occurs at -70 degrees C and above (with a frequency of >50 kHz), whereas the Bi-O oxygen ions are rigid in this temperature regime. This is confirmed by both an analysis of the line broadening of the MoO42- satellite transitions (under MAS) and the spin-lattice relaxation (T-1) times of these sites, the T-1 times indicating that the MoO42- reorientation rates rapidly increase, reaching > 100 MHz at 400 degrees C. Line narrowing of the MoO42- central-transition resonance indicates that exchange between the tetrahedral units, a motion required for long-range anionic conduction, is much slower, involving only jump rates of approximately 1 kHz at 200 degrees C. Both the changes in line width of the MoO42- resonance, and the jump in the T-1 times of the oxygen atoms in the [Bi12O14](infinity)(8-) columns at around the triclinic-monoclinic phase transition temperature (310 degrees C) are consistent with a mechanism for motion involving all the oxygen atoms. The predicted conductivity based on the [Bi-O] T-1 times is now of the order of that extracted from ac impedance measurements reported by Vannier et al. (J. Solid State Chem. 1996, 122, 394). On the basis of this detailed NMR analysis, we propose that motion at ambient temperatures primarily involves the MoO42- tetrahedral rotation: exchange between these sites is very slow. At higher temperatures (above 310 degrees C) the conduction process now appears to involve the oxygen atoms coordinated to Bi3+, in the [Bi12O14](infinity)(8-) columns, and most likely in the partially vacant O[19] site. The involvement of these sites allows for long-range conduction processes that do not involve concerted, multiple Mo-O bond breakages.

U2 - 10.1021/cm800351c

DO - 10.1021/cm800351c

M3 - Journal article

VL - 20

SP - 3638

EP - 3648

JO - Journal of Materials Chemistry

JF - Journal of Materials Chemistry

SN - 1364-5501

IS - 11

ER -